22 - 350 Acute Viral Hepatitis
350 Acute Viral Hepatitis
Esperance A. K. Schaefer,
Raymond T. Chung, Jules L. Dienstag
serotype. Human HAV can infect and cause hepatitis in chimpanzees, tamarins (marmosets), and several monkey species. HAV-like hepa toviruses have also been identified in small mammals, including bats and rodents.
Hepatitis A has an incubation period of ~3–4 weeks. Its replication is limited to the liver, but the virus is present in the liver, bile, stools, and blood during the late incubation period and acute preicteric/ presymptomatic phase of illness. Despite slightly longer persistence of virus in the liver, fecal shedding, viremia, and infectivity diminish rapidly once jaundice becomes apparent. Detection of HAV RNA by sensitive reverse transcription polymerase chain reaction assays has been reported to persist at low levels in stool, the liver, and serum for up to several months after acute illness; however, this does not cor relate with persistent infectivity, probably because of the presence of neutralizing antibody. HAV can be cultivated reproducibly in vitro and in primate models. Antibodies to HAV (anti-HAV) can be detected during acute illness when serum aminotransferase activity is elevated and fecal HAV shed ding is still occurring. This early antibody response is predominantly of the IgM class and persists for several (~3) months, rarely for 6–12 months. During convalescence, however, anti-HAV of the IgG class becomes the predominant antibody (Fig. 350-2). Therefore, the diag nosis of hepatitis A is made during acute illness by demonstrating antiHAV of the IgM class. After acute illness, anti-HAV of the IgG class remains detectable indefinitely, and patients with serum anti-HAV are immune to reinfection. Neutralizing antibody activity parallels the appearance of anti-HAV, and the IgG anti-HAV present in immune globulin accounts for the protection it affords against HAV infection. CHAPTER 350 Hepatitis B HBV is a DNA virus with a remarkably compact genomic structure; despite its small, circular, 3200-bp size, HBV DNA codes for four sets of viral products with a complex, multiparticle structure. HBV achieves its genomic economy by relying on an effi cient strategy of encoding proteins from four overlapping genes: S, C, P, and X (Fig. 350-3), as detailed below. Once thought to be unique among viruses, HBV is now recognized as one of a family of animal viruses, hepadnaviruses (hepatotropic DNA viruses), and is classi fied as hepadnavirus type 1. Similar viruses infect certain species of woodchucks, ground and tree squirrels, and Pekin ducks, to mention the most carefully characterized; genetic evidence of ancient HBV-like virus forbears has been found in fossils of ancient birds, and an HBV-like virus has been identified in contemporary fish. Studies of ancient HBV genomes date an association between HBV and human beings back as long as 21,000 years ago; primate HBV-like viruses date back mil lions of years, suggesting that HBV predated the emergence of modern humans. Like HBV, all have the same distinctive three morphologic forms, have counterparts to the envelope and nucleocapsid virus anti gens of HBV, replicate in the liver but exist in extrahepatic sites, contain their own endogenous DNA polymerase, have partially double-strand and partially single-strand genomes, are associated with acute and Acute Viral Hepatitis chronic hepatitis and hepatocellular car cinoma, and rely on a replicative strategy unique among DNA viruses but typi cal of retroviruses. Entry of HBV into hepatocytes is mediated by binding to the sodium taurocholate cotransporting polypeptide (NTCP) receptor. Instead of DNA replication directly from a DNA template, hepadnaviruses rely on reverse transcription (effected by the DNA poly merase) of minus-strand DNA from a “pregenomic” RNA intermediate. Then, plus-strand DNA is transcribed from the minus-strand DNA template by the DNA-dependent DNA polymerase and converted in the hepatocyte nucleus to a covalently closed circular DNA, which serves as a template for messenger RNA and pregenomic RNA. Viral proteins
Jaundice IgG Anti-HAV IgM Anti-HAV ALT Fecal HAV
Weeks after exposure FIGURE 350-2 Scheme of typical clinical and laboratory features of hepatitis A virus (HAV). ALT, alanine aminotransferase. are translated by the messenger RNA, and the proteins and genome are packaged into virions and secreted from the hepatocyte. Hepatitis B virus has been difficult to cultivate in vitro from clinical materials; therefore, a model that recapitulates the entire HBV life cycle has been particularly elusive. In recent decades, however, advances in molecular virology have permitted the comprehensive study of HBV replication and its viral genes and proteins. VIRAL PROTEINS AND PARTICLES Three particulate forms of HBV appear in the circulation (Table 350-1), the complete virion and two incomplete or subviral particles. Of these, the most numerous are the 22-nm particles, which appear as spherical or long filamentous forms; these are antigenically indistinguishable from the outer surface or envelope protein of HBV and are thought to represent excess viral envelope protein. Outnumbered in serum by a factor of 100 or 1000 to 1 compared with the spheres and tubules are large, 42-nm, doubleshelled spherical particles, which represent the intact hepatitis B virion (Fig. 350-1). The envelope protein expressed on the outer surface of the virion and on the smaller spherical and tubular structures is referred to as hepatitis B surface antigen (HBsAg). The concentration of HBsAg and virus particles in the blood may reach 500 μg/mL and 10 trillion particles per milliliter, respectively; HBsAg assays in common clinical use detect all forms of HBsAg (virion and subviral particles). The enve lope protein, HBsAg, is the product of the S gene of HBV. PART 10 Disorders of the Gastrointestinal System HBV isolates fall into 10 different genotypes (A–J) and multiple sub types, which are determined by unique gene sequences of the envelope Pre-S2 Pre-S1 S P C Pre-C X FIGURE 350-3 Compact genomic structure of hepatitis B virus (HBV). This structure, with overlapping genes, permits HBV to code for multiple proteins. The S gene codes for the “major” envelope protein, HBsAg. Pre-S1 and pre-S2, upstream of S, combine with S to code for two larger proteins, “middle” protein, the product of pre-S2 + S, and “large” protein, the product of pre-S1 + pre-S2 + S. The largest gene, P, codes for DNA polymerase. The C gene codes for two nucleocapsid proteins, HBeAg, a soluble, secreted protein (initiation from the pre-C region of the gene), and HBcAg, the intracellular core protein (initiation after pre-C). The X gene codes for HBxAg, which can transactivate the transcription of cellular and viral genes; its clinical relevance is not known, but it may contribute to carcinogenesis by binding to p53.
HBsAg protein. Envelope HBsAg subdeterminants include a common group-reactive antigen, a, shared by all HBsAg isolates and one of several subtype-specific antigens—d or y, w or r. Geographic distribu tion of genotypes and subtypes varies; genotypes A (corresponding to subtype adw) and D (ayw) predominate in the United States and Europe, whereas genotypes B (adw) and C (adr) predominate in Asia; however, these geographic distinctions have been blunted by recentdecade migration across continents. Clinical course and outcome are independent of subtype, but genotype B appears to be associated with less rapidly progressive liver disease and cirrhosis and a lower likelihood, or delayed appearance, of hepatocellular carcinoma than genotype C, D, or F. In a large Japanese cohort, after acute infection, patients with genotype A were more likely to have persistent infection (23.4% with genotype A vs 8.6% with non-A genotypes). Also, geno type may influence response to treatment with interferon and other antiviral agents; for example, higher rates of HBeAg and HBsAg loss have been observed in patients with genotype A. An additional impor tant consequence of genotype is the propensity for “precore” mutations to emerge (see below). Upstream of the S gene are the pre-S genes (Fig. 350-3), which code for pre-S gene products, including receptors on the HBV surface for polymerized human serum albumin and for hepatocyte membrane proteins. The pre-S region actually consists of both pre-S1 and pre-S2. Depending on where translation is initiated, three potential HBsAg gene products are synthesized. The protein product of the S gene is HBsAg (major protein), the product of the S region plus the adjacent pre-S2 region is the middle protein, and the product of the pre-S1 plus pre-S2 plus S regions is the large protein. Compared with the smaller spherical and tubular particles of HBV, complete 42-nm virions are enriched in the large protein. Both pre-S proteins and their respective antibodies can be detected during HBV infection, and the period of pre-S antigenemia appears to coincide with other markers of virus rep lication, as detailed below; however, pre-S proteins have little clinical relevance and are not included in routine serologic testing repertoires. The intact 42-nm virion contains a 27-nm nucleocapsid core par ticle. Nucleocapsid proteins are coded for by the C gene. The antigen expressed on the surface of the nucleocapsid core is hepatitis B core antigen (HBcAg), and its corresponding antibody is anti-HBc. A third HBV antigen is HBeAg, a soluble, nonparticulate, nucleocapsid protein that is immunologically distinct from intact HBcAg but is a product of the same C gene. The C gene has two initiation codons: a precore and a core region (Fig. 350-3). If translation is initiated at the precore region, the protein product is HBeAg, which has a signal peptide that binds it to the smooth endoplasmic reticulum, the secretory apparatus of the cell, leading to its secretion into the circulation. If translation begins at the core region, HBcAg is the protein product; it has no signal peptide and is not secreted, but it assembles into nucleocapsid particles, which bind to and incorporate RNA and which, ultimately, contain HBV DNA. Also packaged within the nucleocapsid core is a DNA polymerase, which directs replication and repair of HBV DNA. When packaging within viral proteins is complete, synthesis of the incomplete plus strand stops; this accounts for the single-strand gap and for differ ences in the size of the gap. HBcAg particles remain in the hepatocyte, where they are readily detectable by immunohistochemical staining and are exported after encapsidation by an envelope of HBsAg. There fore, naked core particles do not circulate in the serum. The secreted nucleocapsid protein, HBeAg, provides a convenient, readily detect able, qualitative marker of HBV replication and relative infectivity. HBsAg-positive serum containing HBeAg is more likely to be highly infectious and to be associated with the presence of hepatitis B virions (and detectable HBV DNA, see below) than HBeAg-negative or antiHBe-positive serum. For example, HBsAg-positive mothers who are HBeAg positive almost invariably (>90%) transmit hepatitis B infec tion to their offspring, whereas HBsAg-positive mothers with anti-HBe rarely (10–15%) infect their offspring. Early during the course of acute hepatitis B, HBeAg appears tran siently; its disappearance may be a harbinger of clinical improvement and resolution of infection. Persistence of HBeAg in serum beyond the first 3 months of acute infection may be predictive of the development
TABLE 350-1 Nomenclature and Features of Hepatitis Viruses HEPATITIS TYPE VIRUS PARTICLE, nm MORPHOLOGY GENOMEa CLASSIFICATION ANTIGEN(S) ANTIBODIES REMARKS HAV
Icosahedral nonenveloped 7.5-kb RNA, linear, ss, + Hepatovirus HAV Anti-HAV Early fecal shedding Diagnosis: IgM anti-HAV Previous infection: IgG anti-HAV HBV
Double-shelled virion (surface and core) spherical 3.2-kb DNA, circular, ss/ds Hepadnavirus HBsAg HBcAg HBeAg HBcAg HBeAg Nucleocapsid core
Spherical and filamentous; represents excess virus coat material
HCV
Enveloped 9.4-kb RNA, linear, ss, + Hepacivirus HCV core antigen HDV 35–37 Enveloped hybrid particle with HBsAg coat and HDV core 1.7-kb RNA, circular, ss, – Resembles viroids and plant satellite viruses (genus Deltavirus) HEV 32–34 Nonenveloped icosahedral 7.6-kb RNA, linear, ss, + Orthohepevirus HEV antigen Anti-HEV Agent of enterically transmitted hepatitis; rare in the United States; occurs in Asia, Mediterranean countries, Central America Diagnosis: IgM/IgG anti-HEV (assays not routinely available); virus in stool, bile, hepatocyte cytoplasm ass, single-strand; ss/ds, partially single-strand, partially double-strand; −, minus-strand; +, plus-strand. Note: See text for abbreviations. of chronic infection, and the presence of HBeAg during chronic hepa titis B tends to be associated with ongoing viral replication, infectivity, and inflammatory liver injury (except during the early decades after perinatally acquired HBV infection; see below). The third and largest of the HBV genes, the P gene (Fig. 350-3), codes for HBV DNA polymerase; as noted above, this enzyme has both DNA-dependent DNA polymerase and RNA-dependent reverse transcriptase activities. The fourth gene, X, codes for a small, non particulate protein, hepatitis B x antigen (HBxAg), which is capable of transactivating the transcription of both viral and cellular genes (Fig. 350-3). This function underpins its role in promoting both viral rep lication and HBV-related hepatocellular carcinoma. In the cytoplasm, HBxAg effects calcium release (possibly from mitochondria), which activates signal-transduction pathways that lead to stimulation of HBV reverse transcription and HBV DNA replication. Such transactivation may enhance the replication of HBV; the transactivating activity can enhance the transcription and replication of other viruses besides HBV, such as HIV. The clinical relevance of HBxAg is limited, however, and testing for it is not part of routine clinical practice. SEROLOGIC AND VIROLOGIC MARKERS After a person is infected with HBV, the first virologic marker detectable in serum within 1–12 weeks, usually between 8 and 12 weeks, is HBsAg (Fig. 350-4). Circulating HBsAg precedes elevations of serum aminotransferase activity and clinical symptoms by 2–6 weeks and remains detectable during the entire icteric or symptomatic phase of acute hepatitis B and beyond. In typical self-limited cases, HBsAg becomes undetectable 1–2 months after the onset of jaundice and rarely persists beyond 6 months. After HBsAg disappears, antibody to HBsAg (anti-HBs) becomes
Anti-HBs Anti-HBc Anti-HBe Anti-HBc Anti-HBe Bloodborne virus; carrier state Acute diagnosis: HBsAg, IgM anti-HBc Chronic diagnosis: IgG anti-HBc, HBsAg Markers of replication: HBeAg, HBV DNA Liver, lymphocytes, other organs Nucleocapsid contains DNA and DNA polymerase; present in hepatocyte nucleus; HBcAg does not circulate; HBeAg (soluble, nonparticulate) and HBV DNA circulate— correlate with infectivity and complete virions HBsAg detectable in >95% of patients with acute hepatitis B; found in serum, body fluids, hepatocyte cytoplasm; anti-HBs appears following infection—protective antibody HBsAg Anti-HBs Anti-HCV Bloodborne agent, formerly labeled non-A, non-B hepatitis Acute diagnosis: anti-HCV, HCV RNA Chronic diagnosis: anti-HCV, HCV RNA; cytoplasmic location in hepatocytes HBsAg HDAg Anti-HBs Anti-HDV Defective RNA virus, requires helper function of HBV (hepadnaviruses); HDV antigen (HDAg) present in hepatocyte nucleus Diagnosis: anti-HDV, HDV RNA; HBV/HDV co-infection—IgM anti-HBc and anti-HDV; HDV superinfection—IgG anti-HBc and anti-HDV CHAPTER 350 Acute Viral Hepatitis detectable in serum and remains detectable indefinitely thereafter. Because HBcAg is intracellular and, when in the serum, sequestered within an HBsAg coat, naked core particles do not circulate in serum, and therefore, assays for HBcAg are not included in routine clinical testing. By contrast, anti-HBc is readily demonstrable in serum, begin ning within the first 1–2 weeks after the appearance of HBsAg and preceding detectable levels of anti-HBs by weeks to months. Because variability exists in the time of appearance of anti-HBs after HBV Jaundice ALT HBeAg Anti-HBe IgG Anti-HBc HBsAg IgM Anti-HBc Anti-HBs
Weeks after exposure
FIGURE 350-4 Scheme of typical clinical and laboratory features of acute hepatitis B. ALT, alanine aminotransferase.
infection, occasionally a gap of several weeks or longer may separate the disappearance of HBsAg and the appearance of anti-HBs. Dur ing this “gap” or “window” period, IgM anti-HBc may represent the only serologic evidence of current or recent HBV infection, and blood containing anti-HBc in the absence of HBsAg and anti-HBs had been implicated in the past in transfusion-associated hepatitis B. In part because the sensitivity of immunoassays for HBsAg and anti-HBs has increased, however, this window period is rarely encountered. In some persons, years after HBV infection, anti-HBc may persist in the circulation longer than anti-HBs. Therefore, isolated anti-HBc does not necessarily indicate active virus replication; most instances of isolated anti-HBc represent hepatitis B infection in the remote past. Rarely, however, isolated anti-HBc represents low-level hepatitis B viremia, with HBsAg below the detection threshold, and occasionally, isolated anti-HBc represents a cross-reacting or false-positive immunologic specificity.
Recent and remote HBV infections can be distinguished by deter mination of the immunoglobulin class of anti-HBc. Anti-HBc of the IgM class (IgM anti-HBc) predominates during the first 6 months after acute infection, whereas IgG anti-HBc is the predominant class of antiHBc beyond 6 months. Therefore, patients with current or recent acute hepatitis B, including those in the anti-HBc window, have IgM antiHBc in their serum. In patients who have recovered from hepatitis B in the remote past as well as those with chronic HBV infection, anti-HBc is predominantly of the IgG class. Infrequently, in ≤1–5% of patients with acute HBV infection, levels of HBsAg are too low to be detected; in such cases, the presence of IgM anti-HBc establishes the diagnosis of acute hepatitis B. When isolated anti-HBc occurs in the rare patient with chronic hepatitis B whose HBsAg level is below the sensitivity threshold of contemporary immunoassays (a low-level carrier), antiHBc is of the IgG class. Generally, in persons who have recovered from hepatitis B, anti-HBs and anti-HBc persist indefinitely. PART 10 Disorders of the Gastrointestinal System The temporal association between the appearance of anti-HBs and resolution of HBV infection as well as the observation that persons with anti-HBs in serum are protected against reinfection with HBV suggests that anti-HBs is the protective antibody. Therefore, strategies for prevention of HBV infection are based on providing susceptible persons with circulating anti-HBs (see below). Occasionally, in ~5–10% of patients with chronic hepatitis B, low-level, low-affinity anti-HBs can be detected. Although an unusual serologic pattern in chronic hepatitis B, coexisting HBsAg and anti-HBs positivity does not signal imminent clearance of hepatitis B. Recently, the presence of coexisting HBsAg and anti-HBs in 4.2% of 6534 Chinese patients with chronic hepatitis B was reported (in HBeAg-negative but not HBeAg-reactive patients) to be associated with a higher risk of advanced fibrosis and cirrhosis. The fact that the coexistent HBsAg–anti-HBs subset was significantly older suggests that the link with advanced disease was predominantly the result of longer-duration disease. These patients with HBsAg and such nonneutralizing anti-HBs should be categorized as having chronic HBV infection and, because of the reported association with advanced fibrosis, evaluated for a higher risk of advanced disease. The other readily detectable serologic marker of HBV infection, HBeAg, appears concurrently with or shortly after HBsAg. Its appear ance coincides temporally with high levels of virus replication and reflects the presence of circulating intact virions and detectable HBV DNA (with the notable exception of patients with precore mutations who cannot synthesize HBeAg—see “Molecular Variants”). Pre-S1 and pre-S2 proteins are also expressed during periods of peak replication, but assays for these gene products are not routinely available. In selflimited HBV infections, HBeAg becomes undetectable shortly after peak elevations in aminotransferase activity, before the disappearance of HBsAg, and anti-HBe then becomes detectable, coinciding with a period of relatively lower infectivity (Fig. 350-4). Because HBeAg appears transiently (and HBV DNA, see below, is always present) dur ing typical cases of acute infection, testing for HBeAg and HBV DNA is of limited clinical utility; in contrast, testing for the presence of these markers is of substantial importance in patients with chronic infection. Departing from the pattern typical of acute HBV infections, in chronic HBV infection, HBsAg remains detectable beyond 6 months,
ALT HBeAg Anti-HBe HBV DNA HBsAg Anti-HBc IgM anti-HBc
Months after exposure
1 2 3 4 5 FIGURE 350-5 Scheme of typical laboratory features of wild-type chronic hepatitis B. HBeAg and hepatitis B virus (HBV) DNA can be detected in serum during the relatively replicative phase of chronic infection, which is associated with infectivity and liver injury. Seroconversion from the replicative phase to the relatively nonreplicative phase occurs at a rate of ~10% per year and is heralded by an acute hepatitis–like elevation of alanine aminotransferase (ALT) activity; during the nonreplicative phase, infectivity and liver injury are limited. In HBeAg-negative chronic hepatitis B associated with mutations in the precore region of the HBV genome, replicative chronic hepatitis B occurs in the absence of HBeAg. anti-HBc is primarily of the IgG class, and anti-HBs is either undetect able or detectable at low levels (see “Laboratory Features”) (Fig. 350-5). During early chronic HBV infection, HBV DNA can be detected both in serum and in hepatocyte nuclei, where it is present in free or epi somal form. This relatively highly replicative stage of HBV infection is the time of maximal infectivity and liver injury; HBeAg is a qualitative marker and HBV DNA a quantitative marker of this replicative phase, during which all three forms of HBV circulate, including intact virions. Over time, the relatively replicative phase of chronic HBV infection gives way to a relatively nonreplicative phase. This occurs at a rate of ~10% per year and is accompanied by seroconversion from HBeAg to anti-HBe. In many cases, this seroconversion coincides with a tran sient, usually mild, acute hepatitis-like elevation in aminotransferase activity, believed to reflect cell-mediated immune clearance of virusinfected hepatocytes. In this relatively nonreplicative or low-replicative phase of chronic infection, when HBV DNA is demonstrable in hepa tocyte nuclei, it tends to be integrated into the host genome. In this phase, only spherical and tubular forms of HBV, not intact virions, circulate, and liver injury tends to subside. In this phase, clinical mea sures of liver injury (specifically alanine aminotransferase [ALT]) are normal. Most such patients would be characterized as inactive HBV carriers. In reality, the designations replicative and nonreplicative are only relative; even in the so-called nonreplicative phase, circulating HBV DNA can be detected at levels of approximately ≤103 virions/mL with highly sensitive amplification probes such as the polymerase chain reaction (PCR); below this replication threshold, liver injury and infec tivity of HBV are limited to negligible. Still, the distinctions are patho physiologically and clinically meaningful. While true inactive carriers rarely progress to an immune active state, in 5% of cases, relatively nonreplicative HBeAg-negative chronic HBV infection converts back to replicative infection with re-expression of HBeAg. Such spontaneous reactivations may also be accompanied by expression of IgM anti-HBc, as well as by exacerbations of liver injury. Because high-titer IgM antiHBc can reappear during acute exacerbations of chronic hepatitis B, relying on IgM anti-HBc versus IgG anti-HBc to distinguish between acute and chronic hepatitis B infection, respectively, may not always be reliable; in such cases, patient history and additional follow-up monitoring over time are invaluable in helping to distinguish de novo acute hepatitis B infection from acute exacerbation of chronic hepatitis B infection. MOLECULAR VARIANTS Variation occurs throughout the HBV genome, and clinical isolates of HBV that do not express typical viral
proteins have been attributed to mutations in individual or even multi ple gene locations. For example, variants have been described that lack nucleocapsid proteins (commonly), envelope proteins (very rarely), or both. Two categories of naturally occurring HBV variants have attracted the most attention: precore mutations and escape mutations. One precore mutation was identified initially in Mediterranean countries among patients with severe chronic HBV infection and detectable HBV DNA, but with anti-HBe instead of HBeAg. These patients were found to be infected with an HBV mutant that contained an alteration in the precore region, rendering the virus incapable of encoding HBeAg. Although several potential mutation sites exist in the pre-C region, the region of the C gene necessary for the expression of HBeAg (see “Virology and Etiology”), the most commonly encoun tered in such patients is a single base substitution, from G to A in the second to last codon of the pre-C gene at nucleotide 1896. This sub stitution results in the replacement of the TGG tryptophan codon by a stop codon (TAG), which prevents the translation of HBeAg. Another mutation, in the core-promoter region, prevents transcription of the coding region for HBeAg and yields an HBeAg-negative phenotype. Patients with such mutations in the precore region and who are unable to secrete HBeAg may have severe liver disease that progresses more rapidly to cirrhosis, or alternatively, they are identified clinically later in the course of the natural history of chronic hepatitis B, when the disease is more advanced. Both “wild-type” HBV and precore-mutant HBV can coexist in the same patient, or mutant HBV may arise late during wild-type HBV infection. Clusters of fulminant hepatitis B have been observed in Japan and Israel among patients with precore mutant mutations, although, typically, in Europe and North America, most cases of fulminant hepatitis B occur in patients with wild-type virus. HBeAg-negative chronic hepatitis with mutations in the precore region is now the most frequently encountered form of hepatitis B in Mediterranean countries and in Europe. In the United States, where HBV genotype A (less prone to G1896A mutation) is prevalent, pre core-mutant HBV had been much less common; however, as a result of immigration from Asia and Europe, the proportion of HBeAg-negative hepatitis B–infected persons has increased in the United States, now accounting for ~30–40% of patients with chronic hepatitis B. Char acteristic of such HBeAg-negative chronic hepatitis B are lower levels of HBV DNA (usually ≤105 IU/mL) and one of several patterns of aminotransferase activity—persistent elevations, periodic fluctuations above the normal range, and periodic fluctuations between the normal and elevated range. The second important category of HBV mutants consists of escape mutants, in which a single amino acid substitution, from glycine to arginine, occurs at position 145 of the immunodominant a determi nant common to all HBsAg subtypes. This HBsAg alteration leads to a critical conformational change that results in a loss of neutralizing activity by anti-HBs. This specific HBV/a mutant has been observed in two situations, active and passive immunization, in which humoral immunologic pressure may favor evolutionary change (“escape”) in the virus—in a small number of hepatitis B vaccine recipients who acquired HBV infection despite the prior appearance of neutralizing anti-HBs and in HBV-infected liver transplant recipients treated with a high-potency human monoclonal anti-HBs preparation. Although such mutants have not been recognized frequently, their existence raises a concern that may complicate vaccination strategies and sero logic diagnosis. Different types of mutations emerge during antiviral therapy of chronic hepatitis B with nucleoside analogues; such YMDD and similar mutations in the polymerase motif of HBV are described in Chap. 352. EXTRAHEPATIC SITES Hepatitis B antigens and HBV DNA have been identified in extrahepatic sites, including the lymph nodes, bone mar row, circulating lymphocytes, spleen, and pancreas. Although the virus does not appear to be associated with tissue injury in any of these extra hepatic sites, its presence in these “remote” reservoirs has been invoked (but is not necessary) to explain the recurrence of HBV infection after orthotopic liver transplantation. The clinical relevance of such extra hepatic HBV is limited.
Hepatitis D The delta hepatitis agent, or HDV, the only member of the genus Deltavirus, is a defective RNA virus that co-infects with and requires the helper function of HBV (or other hepadnaviruses) for its replication and expression. Slightly smaller than HBV, HDV is a formalin-sensitive, 35- to 37-nm virus with a hybrid structure. Its nucleocapsid expresses HDV antigen (HDAg), which bears no antigenic homology with any of the HBV antigens, and contains the virus genome. The HDV core is “encapsidated” by an outer envelope of HBsAg, indistinguishable from that of HBV except in its relative compositions of major, middle, and large HBsAg component proteins. The genome is a small, 1700-nucleotide, circular, single-strand RNA of negative polarity that is nonhomologous with HBV DNA (except for a small area of the polymerase gene) but that has features and the rolling circle model of replication common to genomes of plant satellite viruses or viroids. HDV RNA contains many areas of internal complementarity; therefore, it can fold on itself by internal base pairing to form an unusual, very stable, rod-like structure that contains a very stable, self-cleaving and self-ligating ribozyme. HDV RNA requires host RNA polymerase II for its replication in the hepatocyte nucleus via RNA-directed RNA synthesis by transcription of genomic RNA to a complementary antigenomic (plus strand) RNA; the antigenomic RNA, in turn, serves as a template for subsequent genomic RNA syn thesis effected by host RNA polymerase I. HDV RNA has only one open reading frame, and HDAg, a product of the antigenomic strand, is the only known HDV protein; HDAg exists in two forms: a small, 195-amino-acid species, which plays a role in facilitating HDV RNA replication, and a large, 214-amino-acid species, which appears to suppress replication but is required for assembly of the antigen into virions. HDV antigens have been shown to bind directly to RNA polymerase II, resulting in stimulation of transcription. Viral assem bly requires farnesylation of the large HDAg for ribonucleoprotein anchoring to HBsAg. Both HBV and HDV enter hepatocytes via the NTCP receptor. Although complete hepatitis D virions and liver injury require the cooperative helper function of HBV, intracellular replica tion of HDV RNA can occur without HBV. Genomic heterogeneity among HDV isolates has been described. Although pathophysiologic and clinical consequences of this genetic diversity have not been estab lished definitively, preliminarily, genotype 2 has been linked to milder disease and genotype 3 to severe acute disease. The clinical spectrum of hepatitis D is common to all eight genotypes identified, the predomi nant of which is genotype 1.
CHAPTER 350 Acute Viral Hepatitis HDV can either infect a person simultaneously with HBV (co-infection) or superinfect a person already infected with HBV (superinfection). In instances of superinfection, when HDV infection is transmitted from a donor with one HBsAg subtype to an HBsAg-positive recipient with a different subtype, HDV assumes the HBsAg subtype of the recipient, rather than the donor. Because HDV relies absolutely on HBV for its replication, the duration of HDV infection is determined by the dura tion of (and cannot outlast) HBV infection. HDV replication tends to suppress HBV replication; therefore, patients with hepatitis D tend to have lower levels of HBV replication. HDV antigen is expressed primarily in hepatocyte nuclei and is occasionally detectable in serum. During acute HDV infection, anti-HDV of the IgM class predominates, and 30–40 days may elapse after symptoms appear before anti-HDV can be detected. In self-limited infection, anti-HDV is low-titer and transient, rarely remaining detectable beyond the clearance of HBsAg and HDV antigen. In chronic HDV infection, anti-HDV circulates in high titer, and both IgM and IgG anti-HDV can be detected. HDV antigen in the liver and HDV RNA in serum and liver can be detected during HDV replication. Hepatitis C Hepatitis C virus, which, before its identification, was labeled “non-A, non-B hepatitis,” is a linear, single-strand, positivesense, 9600-nucleotide RNA virus, the genome of which is similar in organization to that of flaviviruses and pestiviruses; HCV is the only member of the genus Hepacivirus in the family Flaviviridae. The HCV genome contains a single, large open reading frame (ORF) (gene) that codes for a virus polyprotein of ~3000 amino acids, which is cleaved after translation to yield 10 viral proteins. The 5′ end of
the genome consists of an untranslated region (containing an internal ribo somal entry site [IRES]) adjacent to the genes for three structural proteins, the nucleocapsid core protein, C, and two envelope glycoproteins, E1 and E2. The 5′ untranslated region and core gene are highly conserved among genotypes, but the envelope proteins are coded for by the hypervariable region, which varies from isolate to isolate and may allow the virus to evade host immunologic containment directed at accessible virusenvelope proteins. The 3′ end of the genome also includes an untranslated region and contains the genes for seven nonstructural (NS) proteins: p7, NS2, NS3, NS4A, NS4B, NS5A, and NS5B. p7 is a membrane ion channel pro tein necessary for efficient assembly and release of HCV. The NS2 cysteine protease cleaves NS3 from NS2, and the NS3-4A serine protease cleaves all the downstream proteins from the polyprotein. Important NS proteins involved in virus replication include the NS3 helicase; NS3-4A serine protease; the multifunctional membrane-associated phosphoprotein NS5A, an essential component of the viral replication membranous web (along with NS4B); and the NS5B RNA-dependent RNA polymerase (Fig. 350-6). Because HCV does not replicate via a DNA intermediate, it does not integrate into the host genome. Because HCV tends to circulate in relatively low titer, 103−107 virions/mL, visualization of the 50- to 80-nm virus particles remains difficult. Still, the replication rate of HCV is very high, 1012 virions per day; its half-life is 2.7 h. Historically, the study of HCV had been hampered by few adequate in vitro and animal models. In 2005, however, complete replication of HCV and intact 55-nm virions was described in cell culture systems. These and other subsequent models were fundamental toward the development of targeted, effective antivi ral therapies for HCV infection. Still, the continued absence of robust animal models poses a barrier to much-needed vaccine development. Albeit a helpful animal model, the chimpanzee is cumbersome to study, and access to chimpanzees for medical research has been curtailed substantially. In addition, while HCV replication has been documented in a xenograft immunodeficient mouse model containing explants of human liver and in transgenic mouse and rat models, a tractable immunocompetent murine model has remained elusive.
AA Envelope glycoproteins Core 5' 3' C E1 E2 NS2 NS3 NS4B NS5A NS5B Conserved region Hypervariable region FIGURE 350-6 Organization of the hepatitis C virus genome and its associated, 3000-amino-acid (AA) proteins. The three structural genes at the 5′ end are the core region, C, which codes for the nucleocapsid, and the envelope regions, E1 and E2, which code for envelope glycoproteins. The 5′ untranslated region and the C region are highly conserved among isolates, whereas the envelope domain E2 contains the hypervariable region. At the 3′ end are seven nonstructural (NS) regions—p7, a membrane protein adjacent to the structural proteins that appears to function as an ion channel; NS2, which codes for a cysteine protease; NS3, which codes for a serine protease and an RNA helicase; NS4 and NS4B; NS5A, a multifunctional membrane-associated phosphoprotein, an essential component of the viral replication membranous web; and NS5B, which codes for an RNA-dependent RNA polymerase. After translation of the entire polyprotein, individual proteins are cleaved by both host and viral proteases. PART 10 Disorders of the Gastrointestinal System In vitro study has also elucidated important cofactors for the hepatitis C viral life cycle. For example, HCV entry into the hepatocyte occurs via the non-liver-specific CD81 receptor and the liver-specific tight junction protein claudin-1. A growing list of additional host receptors to which HCV binds upon cell entry includes occludin, lowdensity lipoprotein receptors, glycosaminoglycans, scavenger receptor B1, and epidermal growth factor receptor, among others. After viral entry and uncoating, translation is initiated by the IRES on the endo plasmic reticulum membrane, and the HCV polyprotein is cleaved dur ing translation and posttranslationally by host cellular proteases as well as HCV NS2-3 and NS3-4A proteases. Host cofactors involved in HCV replication include cyclophilin A, which binds to NS5A and yields conformational changes required for viral replication, and the liverspecific host microRNA miR-122. Relying on the same assembly and secretion pathway as low-density and very-low-density lipoproteins, HCV is a lipoviroparticle and masquerades as a lipoprotein, which may limit its visibility to the adaptive immune system, explain its ability to evade immune containment and clearance, and account for the lower circulating LDL levels observed in patients with chronic hepatitis C. At least six distinct major genotypes (and a minor genotype 7), as well as >50 subtypes within genotypes, of HCV have been identi fied by nucleotide sequencing. Some HCV genotypes are distributed worldwide, whereas others are more confined geographically (see “Epidemiology and Global Features”). Genotype differences can affect choice of direct-acting antiviral treatment and can affect clinical course
Helicase Serine protease RNA-dependent RNA polymerase p7 NS4A (e.g., hepatic steatosis and clinical progression are more likely in geno type 3). Genotypes differ from one another in sequence homology by ≥30%, and subtypes differ by ~20%. Because divergence of HCV iso lates within a genotype or subtype and within the same host may vary insufficiently to define a distinct genotype, these intragenotypic differ ences are referred to as quasispecies and differ in sequence homology by only a few percent. The genotypic and quasispecies diversity of HCV, resulting from its high mutation rate, interferes with effective humoral immunity. Neutralizing antibodies to HCV have been demonstrated, but they tend to be short-lived, and HCV infection does not induce lasting immunity against reinfection with different virus isolates or even the same virus isolate. Indeed, the presence of detectable antiHCV does not indicate protection against re-infection. Thus, neither heterologous nor homologous immunity appears to develop commonly after acute HCV infection Currently available, third-generation immunoassays, which incor porate proteins from the core, NS3, and NS5 regions, detect anti-HCV antibodies during acute infection. The most sensitive indicator of HCV infection is the presence of HCV RNA, which requires molecular amplification, for example, by PCR (Fig. 350-7). To allow standardiza tion of the quantification of HCV RNA among laboratories and com mercial assays, HCV RNA is reported as international units (IUs) per milliliter; quantitative assays with a broad dynamic range are available that allow detection of HCV RNA with a sensitivity as low as 5 IU/mL. HCV RNA can be detected within a few days of exposure to HCV— well before the appearance of anti-HCV—and tends to persist for the duration of HCV infection. Application of sensitive molecular probes for HCV RNA has revealed the presence of replicative HCV in periph eral blood lymphocytes of infected persons; however, as is the case for HBV in lymphocytes, the clinical relevance of HCV lymphocyte infec tion is not known. Anti-HCV HCV RNA ALT 0 1 2 3 4 5 6
Months after exposure FIGURE 350-7 Scheme of typical laboratory features during acute hepatitis C progressing to chronicity. Hepatitis C virus (HCV) RNA is the first detectable event, preceding alanine aminotransferase (ALT) elevation and the appearance of anti-HCV.
Hepatitis E Previously labeled epidemic or enterically transmitted non-A, non-B hepatitis, HEV is an enterically transmitted virus that causes clinically apparent hepatitis primarily in India, Asia, Africa, and Central America. In those geographic areas, HEV is the most common cause of acute hepatitis; one-third of the global population appears to have been infected. This agent, with epidemiologic features resembling those of hepatitis A, is a 27- to 34-nm, nonenveloped, heatstable, HAV-like virus with a 7200-nucleotide, single-strand, positivesense RNA genome. Like HAV, HEV also exists in a quasi-enveloped form enclosed within host-cell-derived membranes. HEV has three overlapping ORFs (genes), the largest of which, ORF1, encodes non structural proteins involved in virus replication (the viral replicase, which includes a protease, polymerase, and helicase). A middle-sized gene, ORF2, encodes the nucleocapsid protein, the major structural protein, and the smallest, ORF3, encodes a small structural phospho protein involved in virus particle secretion. All HEV isolates appear to belong to a single serotype, despite genomic heterogeneity of up to 25% and the existence of four species (A–D) and eight genotypes, only four of which, all within species A, have been detected in humans. Genotype associations are important in HEV infection. Genotypes 1 and 2 (common in developing countries) appear to be more virulent anthrotropic variants. In contrast, genotypes 3 (the most common in the United States and Europe) and 4 (seen in China), are endemic in animal species (enzootic variants), represent a zoonotic reservoir for human infections, and are associated with more attenuated or subclinical infection in healthy hosts but with chronic infection in immunocompromised hosts. Contributing to the perpetuation of this virus are the animal reservoirs described above, most notably in swine but also in camels, deer, rats, and rabbits, among others. No genomic or antigenic homology, however, exists between HEV and HAV or other picornaviruses; and HEV, although resembling caliciviruses, is sufficiently distinct from any known agent to merit its own classifica tion as a unique genus, Orthohepevirus, within the family Hepeviridae (which includes similar viruses infecting mammals, birds, and fish). The virus has been detected in stool, bile, and liver and is excreted in the stool during the late incubation period. Both IgM anti-HEV during early acute infection and IgG anti-HEV predominating after the first
3 months can be detected (a serologic pattern similar to that of hepatitis A, see above). The presence of HEV RNA in serum and stool accompa nies acute infection; viremia resolves as clinical-biochemical recovery ensues, while HEV RNA in stool may outlast viremia by several weeks. Currently, serologic/virologic testing for HEV infection—not approved or licensed by the U.S. Food and Drug Administration (FDA)—can be done in specialized laboratories (e.g., the Centers for Disease Control and Prevention [CDC]) and some commercial laboratories. ■ ■PATHOGENESIS Under ordinary circumstances, none of the hepatitis viruses are known to be directly cytopathic to hepatocytes. Evidence suggests that the clinical manifestations and outcomes after acute liver injury associated with viral hepatitis are determined by the immunologic responses of the host. Among the viral hepatitides, the immunopathogenesis of hepatitis B and C has been studied most extensively. Hepatitis B For HBV, the existence of inactive hepatitis B carriers or “immune tolerant” (see below) patients with normal liver histology and function suggests that the virus is not directly cytopathic. The fact that patients with defects in cellular immune competence are more likely to remain chronically infected rather than to clear HBV supports the role of cellular immune responses in the pathogenesis of hepatitis B– related liver injury. The model that has the most experimental support involves cytolytic T cells sensitized specifically to recognize host and hepatitis B viral antigens on the liver cell surface. Nucleocapsid pro teins (HBcAg and possibly HBeAg), present on the cell membrane in minute quantities, are the viral target antigens that, with host antigens, invite cytolytic T cells to destroy HBV-infected hepatocytes. Differ ences in the robustness and broad polyclonality of CD8+ cytolytic T-cell responsiveness; in the level of HBV-specific helper CD4+ T cells; in attenuation, depletion, and exhaustion of virus-specific T cells; in
Although a robust cytolytic T-cell response occurs and eliminates virus-infected liver cells during acute hepatitis B, >90% of HBV DNA has been found in experimentally infected chimpanzees to disappear from the liver and blood before maximal T-cell infiltration of the liver and before most of the biochemical and histologic evidence of liver injury. This observation suggests that components of the innate immune system and inflammatory cytokines, independent of cyto pathic antiviral mechanisms, participate in the early immune response to HBV infection; this effect has been shown to represent elimination of HBV replicative intermediates from the cytoplasm and covalently closed circular viral DNA from the nucleus of infected hepatocytes. In turn, the innate immune response to HBV infection is mediated largely by natural killer (NK) cell cytotoxicity, activated by immunosuppres sive cytokines (e.g., interleukin [IL] 10 and transforming growth factor [TGF] β), reduced signals from inhibitory receptor expression (e.g., major histocompatibility complex), or increased signals from activat ing receptor expression on infected hepatocytes. In addition, NK cells reduce helper CD4+ cells, which results in reduced CD8+ cells and exhaustion of the virus-specific T-cell response to HBV infection. Adding to the evidence supporting the role of these immunologic perturbations in the pathogenesis of HBV-associated liver injury are the observations that many of these departures from normal immune function are restored after successful antiviral therapy. Ultimately, HBV-HLA–specific cytolytic T-cell responses of the adaptive immune system are felt to be responsible for recovery from HBV infection. CHAPTER 350 Debate continues over the relative importance of viral and host factors in the pathogenesis of HBV-associated liver injury and its out come. As noted above, precore genetic mutants of HBV have been asso ciated with the more severe outcomes of HBV infection (severe chronic and fulminant hepatitis), suggesting that, under certain circumstances, relative pathogenicity is a property of the virus, not the host. The facts that concomitant HDV and HBV infections are associated with more severe liver injury than HBV infection alone and that cells transfected in vitro with the gene for HDV antigen express HDV antigen and then become necrotic in the absence of any immunologic influences are also consistent with a viral effect on pathogenicity. Similarly, in patients who undergo liver transplantation for end-stage chronic hepatitis B, occasionally, rapidly progressive liver injury appears in the new liver. This clinical presentation is associated with an unusual histologic pat tern in the new liver, fibrosing cholestatic hepatitis, which, ultrastruc turally, appears to represent a choking of the cell with overwhelming quantities of HBsAg. This observation suggests that, under the influ ence of the potent immunosuppressive agents required to prevent allograft rejection, HBV may have a direct cytopathic effect on liver cells, independent of the immune system. Acute Viral Hepatitis Although the precise mechanism of liver injury in HBV infection remains elusive, studies of nucleocapsid proteins have shed light on the profound immunologic tolerance to HBV of babies born to mothers with highly replicative (HBeAg-positive), chronic HBV infection. In HBeAg-expressing transgenic mice, in utero exposure to HBeAg, which is sufficiently small to traverse the placenta, induces T-cell tol erance to both nucleocapsid proteins. This, in turn, may explain why, when infection occurs so early in life, immunologic clearance does not occur, and protracted, lifelong infection ensues. An alternative expla nation proposed to explain why robust liver injury does not accompany neonatal HBV infection but predisposes to chronic infection is defec tive priming of HBV-specific T cells during in utero exposure to HBV. “IMMUNE TOLERANT” VERSUS “IMMUNE ACTIVE” CHRONIC
HEPATITIS B An important distinction should be drawn between HBV infection acquired at birth, common in endemic areas, such as East Asia, and infection acquired in adulthood, common in the West.
Infection in the neonatal period is associated with the acquisition of what appears to be a high level of immunologic tolerance to HBV and absence of an acute hepatitis illness but the almost invariable establish ment of chronic, often lifelong infection. Neonatally acquired HBV infection can culminate decades later in cirrhosis and hepatocellular carcinoma (see “Complications and Sequelae”). In contrast, when HBV infection is acquired during adolescence or early adulthood, the host immune response to HBV-infected hepatocytes tends to be robust, an acute hepatitis-like illness is the rule, and failure to recover is the exception. After adulthood-acquired infection, chronicity is uncom mon, and the risk of hepatocellular carcinoma is very low. Based on these observations, some authorities categorize chronic HBV infec tion into an “immune tolerant” phase, an “immune active” phase, and an “inactive” phase. This somewhat simplistic formulation, however, does not apply at all to typical adult infection with self-limited acute hepatitis B. Moreover, even in early-life-acquired chronic infection, this duality is limited by nuance and imprecision in its distinctions. For example, even among those with neonatally acquired HBV infection, in whom immunologic tolerance appears to be established, immunologic responses to HBV infection have been demonstrated (albeit typically at reduced levels), and intermittent bursts of hepatic necroinflammatory activity punctuate the early decades of life during which liver injury appears to be quiescent. Thus, while labeled by some as the “immune tolerant” phase, it more accurately is a period of dissociation between high-level HBV replication and a paucity of inflammatory liver injury. In addition, even when clinically apparent liver injury and progressive fibrosis emerge and predominate during later decades (the so-called immune active phase), the level of immunologic tolerance to HBV and the corresponding failure of immunologic containment and clear ance of HBV infection remain substantial. More accurately, in patients with neonatally acquired HBV infection, a dynamic equilibrium exists between tolerance and intolerance, the outcome of which determines the clinical expression of chronic infection. Persons infected as neo nates tend to have a relatively higher level of immunologic tolerance (high replication, low necroinflammatory activity) during the early decades of life and a relatively lower level (but only rarely a loss) of tolerance (and necroinflammatory activity reflecting the level of virus replication) in the later decades of life. Adding to the confusion is an indeterminate category of patients in a gray zone that borders both relative immune activity and relative immune tolerance.
PART 10 Disorders of the Gastrointestinal System Hepatitis C Cell-mediated immune responses and elaboration by T cells of antiviral cytokines contribute to the multicellular innate and adaptive immune responses involved in the containment of infec tion and pathogenesis of liver injury associated with hepatitis C. The fact that HCV is so efficient in evading these immune mechanisms is a testament to its highly evolved ability to disrupt host immune responses at multiple levels. After exposure to HCV, the host cell identifies viral product motifs (pattern recognition receptors) that dis tinguish the virus from “self,” resulting in the elaboration of interferons and other cytokines that result in activation of innate and adaptive immune responses. Intrahepatic human leukocyte antigen (HLA) class 1–restricted cytolytic T cells directed at nucleocapsid, envelope, and nonstructural viral protein antigens have been demonstrated in patients with chronic hepatitis C; however, such virus-specific cytolytic T-cell responses do not correlate adequately with the degree of liver injury or with recovery. Yet a consensus has emerged supporting a role in the pathogenesis of HCV-associated liver injury of virus-activated CD4+ helper T cells that stimulate, via the cytokines they elaborate, HCV-specific CD8+ cytotoxic T cells. These responses appear to be more robust (higher in number, more diverse in viral antigen speci ficity, more functionally effective, and longer lasting) in those who recover from HCV infection than in those who have chronic infection. Contributing to chronic infection are a CD4+ proliferative defect that results in rapid contraction of CD4+ responses, mutations in CD8+ T cell– targeted viral epitopes that allow HCV to escape immune-mediated clearance, and upregulation of inhibitory receptors on functionally impaired, exhausted T cells. Although attention has focused on adap tive immunity, HCV proteins have been shown to interfere with innate
immunity by resulting in blocking of type 1 interferon responses and inhibition of interferon signaling and effector molecules in the inter feron signaling cascade. Several single nucleotide polymorphisms have been linked with self-limited hepatitis C, the most convincing of which is the CC hap lotype of the IL28B gene, which codes for interferon λ3, a component of innate immune antiviral defense. The link between non-CC IL28B polymorphisms and failure to clear HCV infection has been explained by a chromosome 19q13.13 frameshift variant upstream of IL28B, the ΔG polymorphism of which creates an ORF in a novel interferon gene (IFN-λ4) associated with impaired HCV clearance. Also shown to con tribute to limiting HCV infection are NK cells of the innate immune system; in spontaneous clearance, NK cells show enhanced IFN-γ elaboration and expression of activating receptors. Conversely, in per sistent infection, both peripheral cytotoxicity and intrahepatic NK cell cytotoxicity are dysfunctional. In addition, an important intersection between IL28B genotype and NK function can be inferred from the fact that patients with hepatitis C and unfavorable (non-CC, associated with reduced HCV clearance) IL28B alleles have been shown to have depressed NK cell/innate immune function. Adding to the complexity of the immune response, HCV core, NS4B, and NS5B have been shown to suppress the immunoregulatory nuclear factor (NF)-κB pathway, resulting in reduced antiapoptotic proteins and a resultant increased vulnerability to tumor necrosis factor (TNF) α-mediated cell death. Finally, the rapid mutation rate of the virus impairs the host immune response; the emergence of substantial viral quasispecies diversity and HCV sequence variation allows the virus to evade attempts by the host to contain HCV infection by both humoral and cellular immune mechanisms. Hepatitis A and E Viral shedding in these acute hepatitides pre dates clinical evidence of liver injury, consistent with the absence of a relationship between viral replication and target-organ injury. Instead, as shown for hepatitis B and C, in hepatitis A and E, experimental evi dence supports a cytolytic CD8+ T-cell response as the instrument of liver cell injury, in concert with or dwarfed by CD4+ helper T cells or CD4+ interferon γ–secreting cells. Furthermore, in acute HAV infec tion, expansion of CD8+ T cells active against other, non-HAV, viruses has been demonstrated, and this nonspecific CD8+ T-cell activation correlated with liver injury. HEV, similar to the other hepatitides, has also been shown to interfere with host antiviral defenses, such as inter feron signaling and effector function, and to downregulate interferonstimulated genes. The demonstration of an activated innate immune response in patients with these hepatitides argues for a multitude of immunologic mechanisms in the pathogenesis of the acute liver injury resulting from HAV and HEV infection. ■ ■EXTRAHEPATIC MANIFESTATIONS Immune complex–mediated tissue damage appears to play a pathoge netic role in the extrahepatic manifestations of acute hepatitis B. The occasional prodromal serum sickness–like syndrome observed in acute hepatitis B appears to be related to the deposition in tissue blood vessel walls of HBsAg–anti-HBs circulating immune complexes, leading to activation of the complement system and depressed serum comple ment levels. Other extrahepatic manifestations of HBV infection may include immune complex–mediated diseases, such as polyarteritis nodosa (generalized vasculitis affecting small- and medium-sized arte rioles), glomerulonephritis with nephrotic syndrome, and cryoglobu linemia, which are very rare in acute hepatitis B but far more common in chronic disease (Chaps. 326 and 375). Immune complex disorders have been linked, albeit rarely, with both hepatitis A and E. In hepatitis E, rare neurologic (including GuillainBarré syndrome), renal, pancreatic, and hematologic complications have been postulated to result from both immunologic mechanisms and/or direct extrahepatic-site infection with the virus. ■ ■PATHOLOGY Liver biopsy is rarely needed for the diagnosis or management of acute viral hepatitis, for which clinical features and serologic testing remain
the cornerstone of diagnosis. The typical morphologic lesions of all types of viral hepatitis are similar and consist of panlobular infiltration with mononuclear cells, hepatic cell necrosis, hyperplasia of Kupffer cells, and variable degrees of cholestasis. Hepatic cell regeneration is present, as evidenced by numerous mitotic figures, multinucleated cells, and “rosette” or “pseudoacinar” formation. The mononuclear infiltration consists primarily of small lymphocytes, although plasma cells and eosinophils occasionally are present. Liver cell damage con sists of hepatic cell degeneration and necrosis, cell dropout, ballooning of cells, and acidophilic degeneration of hepatocytes (forming so-called Councilman or apoptotic bodies). Large hepatocytes with a groundglass appearance of the cytoplasm may be seen in chronic but not in acute HBV infection; these cells contain HBsAg and can be identified histochemically with orcein or aldehyde fuchsin. In uncomplicated viral hepatitis, the reticulin framework is preserved. In hepatitis C, the histologic lesion is often remarkable for a relative paucity of inflammation, a marked increase in activation of sinusoidal lining cells, lymphoid aggregates, the presence of fat (more frequent in genotype 3 and linked to increased fibrosis), and, occasionally, bile duct lesions in which biliary epithelial cells appear to be piled up without interruption of the basement membrane. Occasionally, microvesicular steatosis occurs in hepatitis D. In hepatitis E, a common histologic feature is marked cholestasis. A cholestatic variant of slowly resolving acute hepatitis A has been described as well. In the setting of severe acute liver injury, less-specific histologic findings, including portal and lobular inflammation and confluent necrosis, may be present. A more severe histologic lesion, bridging hepatic necrosis, also termed subacute or confluent necrosis or inter face hepatitis, is observed occasionally in acute hepatitis. “Bridging” between lobules results from large areas of hepatic cell dropout, with collapse of the reticulin framework. Characteristically, the bridge con sists of condensed reticulum, inflammatory debris, and degenerating liver cells that span adjacent portal areas, portal to central veins, or central vein to central vein. This lesion had been thought to have prog nostic significance; in many of the originally described patients with this lesion, a subacute course terminated in death within several weeks to months, or severe chronic hepatitis and cirrhosis developed; how ever, the association between bridging necrosis and a poor prognosis in patients with acute hepatitis has not been upheld. Therefore, although demonstration of this lesion in patients with chronic hepatitis has prognostic significance (Chap. 352), its demonstration during acute hepatitis is less meaningful, and liver biopsies to identify this lesion are no longer undertaken routinely in patients with acute hepatitis. In mas sive hepatic necrosis (fulminant hepatitis, “acute yellow atrophy”), the striking feature at postmortem examination is the finding of a small, shrunken, soft liver. Histologic examination reveals massive necrosis and dropout of liver cells of most lobules with extensive collapse and condensation of the reticulin framework. When histologic documenta tion is required in the management of fulminant or very severe hepa titis, a biopsy can be done by the angiographically guided transjugular route, which permits the performance of this invasive procedure in the presence of severe coagulopathy. Immunohistochemical and electron-microscopic studies have local ized HBsAg to the cytoplasm and plasma membrane of infected liver cells. In contrast, HBcAg predominates in the nucleus, but, occasion ally, scant amounts are also seen in the cytoplasm and on the cell mem brane. HDV antigen is localized to the hepatocyte nucleus, whereas HAV and HCV antigens are localized to the cytoplasm. Hepatitis E ORF-2 protein staining is distributed in both a cytoplasmic and nuclear pattern. ■ ■EPIDEMIOLOGY AND GLOBAL FEATURES Before the availability of serologic tests for hepatitis viruses, all viral hepatitis cases were labeled either as “infectious” or “serum” hepatitis. Modes of transmission overlap, however, and a clear distinction among the different types of viral hepatitis cannot be made solely based on clini cal or epidemiologic features (Table 350-2). The most accurate means to distinguish the various types of viral hepatitis involves specific serologic testing.
Hepatitis A This agent is transmitted almost exclusively by the fecal-oral route. Person-to-person spread of HAV is enhanced by poor personal hygiene and overcrowding; large outbreaks as well as spo radic cases have been traced to contaminated food, water, milk, frozen raspberries and strawberries, green onions imported from Mexico, and shellfish (e.g., scallops imported from the Philippines used to make sushi, the culprit identified in a 2016 Hawaiian outbreak). Intrafamily and intrainstitutional spreads are also common. Early epidemiologic observations supported a predilection for hepatitis A to occur in late fall and early winter. In temperate zones, epidemic waves have been recorded every 5–20 years as new segments of nonimmune population appeared; however, in developed countries, the incidence of hepatitis A has been declining, presumably as a function of improved sanitation and environmental hygiene, and these cyclic patterns are no longer observed; still, episodic outbreaks among certain high-risk populations continue to be reported (see below). No HAV carrier state has been identified after acute hepatitis A; perpetuation of the virus in nature depends presumably on nonepidemic, inapparent subclinical infection, ingestion of contaminated food or water in, or imported from, endemic areas, and/or contamination linked to environmental reservoirs.
In the general population, anti-HAV, a marker for previous HAV infection, increases in prevalence as a function of increasing age and of decreasing socioeconomic status. In the 1970s, serologic evidence of prior hepatitis A infection occurred in ~40% of urban popula tions in the United States, most of whose members never recalled having had a symptomatic case of hepatitis. In subsequent decades, however, the prevalence of anti-HAV declined in the United States. In developing countries, exposure, infection, and subsequent immunity are almost universal in childhood. As the frequency of subclinical childhood infections declines in developed countries, a susceptible cohort of adults emerges. Hepatitis A tends to be more symptomatic in adults; therefore, paradoxically, as the frequency of HAV infection declines, the likelihood of clinically apparent, even severe, HAV ill nesses increases in the susceptible adult population. Travel to endemic areas is a common source of infection for adults from nonendemic areas. Important recognized epidemiologic foci of HAV infection include childcare centers, neonatal intensive care units, promiscuous men who have sex with men, injection drug users, and unvaccinated close contacts of newly arrived international adopted children, most of whom emanate from countries with intermediate-to-high hepatitis A endemicity. Although hepatitis A is rarely bloodborne, several out breaks have been recognized in recipients of clotting-factor concen trates. In the United States, the introduction of hepatitis A vaccination programs among children from high-incidence states has resulted in a >70% reduction in the annual incidence of new HAV infections and has shifted the burden of new infections from children to adults. In the 2007–2012 U.S. Public Health Service National Health and Nutri tion Examination Survey (NHANES), the prevalence of anti-HAV in the U.S. population aged ≥20 years had declined to 24.2% from the 29.5% measured in NHANES 1999–2006. From 2007 to 2016, the overall anti-HAV prevalence rose, from 30% in 2007–2010 to 40% in 2011–2016 in U.S.-born persons over the age of 2; the largest increases were observed in children (2–11 years) and teenagers (12–19 years), with a slight increase among young adults (age 20–29). In all other age cohorts among U.S.-born adults, however, the prevalence of anti-HAV remained unchanged between 2007 and 2017; no more than 25% of any age group had protective antibodies. The lowest age-specific preva lence of anti-HAV (16.1–17.6%) occurred in adults in the fourth and fifth decades (aged 30–49 years). This is a subgroup of the population who remain susceptible to acute hepatitis A acquired during travel to endemic areas and from contaminated foods, especially those imported from endemic countries. Recognized initially in San Diego, California, in 2016, widespread person-to-person outbreaks, attributed to fecally contaminated environments, of acute hepatitis A occurred primarily among homeless persons and persons who were using injection drugs. Ultimately, this outbreak extended to at least 32 states (highest number of cases in Kentucky), and by March 2020, 31,950 cases were reported, resulting in 19,548 hospitalizations (61% of cases) and 322 deaths (1% of reported cases, 1.6% of hospitalized cases). By 2022, 315 hepatitis A CHAPTER 350 Acute Viral Hepatitis
TABLE 350-2 Clinical and Epidemiologic Features of Viral Hepatitis FEATURE HAV HBV HCV HDV HEV Incubation (days) 15–45, mean 30 30–180, mean 60–90 15–160, mean 50 30–180, mean 60–90 14–60, mean 40 Onset Acute Insidious or acute Insidious or acute Insidious or acute Acute Age preference Children, young adults Young adults (sexual and percutaneous), babies, toddlers Transmission Fecal-oral Percutaneous Perinatal Sexual +++ Unusual − ± − +++ +++ ++ Clinical Severity Fulminant Progression to chronicity Carrier Cancer Prognosis Mild 0.1% None None None Excellent Occasionally severe 0.1–1% Occasional (1–10%) (90% of neonates) 0.1–30%f + (neonatal infection) Worse with age, debility Prophylaxis Ig, inactivated vaccine HBIG, recombinant vaccine None HBV vaccine (none for HBV carriers) Therapy None Interferonh Lamivudineh Adefovirh Pegylated interferoni Entecaviri PART 10 Disorders of the Gastrointestinal System Telbivudinei Tenofovir disoproxil fumaratei Tenofovir alafenamidei aPrimarily with HIV co-infection and high-level viremia in index case; more likely in persons with multiple sex partners or sexually transmitted diseases; risk ~5%. bUp to 5% in acute HBV/HDV co-infection; up to 20% in HDV superinfection of chronic HBV infection. e10–20% in pregnant women. dIn acute HBV/HDV co-infection, the frequency of chronicity is the same as that for HBV; in HDV superinfection, chronicity is invariable. eExcept as observed in immunosuppressed liver allograft recipients or other immunosuppressed hosts. fVaries considerably throughout the world and in subpopulations within countries; see text. gCommon in Mediterranean countries; rare in North America and western Europe. hNo longer recommended or not included in first-line therapy. iFirst-line agents. jAnecdotal reports and retrospective studies suggest that pegylated interferon and/or ribavirin are effective in treating chronic hepatitis E, observed in immunocompromised persons; ribavirin monotherapy has been used successfully in acute, severe hepatitis E. Abbreviation: HBIG, hepatitis B immunoglobulin. See text for other abbreviations. outbreak–related deaths were reported across 37 states. The increased clinical severity, rate of hospitalization, and death in these outbreaks can be attributed to their involving an older population (mean age ranging from 36 to 42 years; median age of death was 55), born before the introduction of universal childhood hepatitis A vaccination and in whom clinical severity, as noted above, is higher than in children. Moreover, the affected homeless and drug-using populations suffer from multiple comorbidities (including HBV or HCV co-infection) and disparities in access to health care. Addressing this multistate outbreak has required a vigorous hepatitis A vaccination effort (still falling short of adequate coverage) as well as environmental sanitation/ hygiene and education among these susceptible populations. Hepatitis B Percutaneous inoculation has long been recognized as a major route of hepatitis B transmission, but the outmoded designa tion “serum hepatitis” is an inaccurate label for the epidemiologic spectrum of HBV infection. As detailed below, most of the hepatitis transmitted by blood transfusion is not caused by HBV; moreover, in approximately two-thirds of patients with acute type B hepatitis, no history of an identifiable percutaneous exposure can be elicited. We now recognize that many cases of hepatitis B result from less obvi ous modes of nonpercutaneous or covert percutaneous transmission. HBsAg has been identified in almost every body fluid from infected persons, and at least some of these body fluids—most notably semen and saliva—are infectious, albeit less so than serum, when adminis tered percutaneously or nonpercutaneously to experimental animals. Among the nonpercutaneous modes of HBV transmission, oral
Any age, but more common in adults Any age (similar to HBV) Epidemic cases: young adults (20–40 years); sporadic cases: older adults (>60) − +++ ±a − +++ + ++ +++ − − − ±a Moderate 0.1% Common (85%) 1.5–3.2% + Moderate Occasionally severe 5–20%b Mild 1–2%c Commond Nonee Variableg None None Good ± Acute, good; chronic, poor Vaccine Pegylated interferon ribavirin,h telaprevir,h boceprevir,h simeprevir,h sofosbuvir, ledipasvir, paritaprevir/ritonavir,h ombitasvir,h dasabuvir,h daclatasvir,h velpatasvir, grazoprevir, elbasvir, glecaprevir, pibrentasvir, voxilaprevir Pegylated interferon ± Nonej ingestion has been documented as a potential but inefficient route of exposure. By contrast, the two nonpercutaneous routes considered to have the greatest impact are intimate (especially sexual) contact and perinatal transmission. In sub-Saharan Africa, intimate contact among toddlers is con sidered instrumental in contributing to the maintenance of the high frequency of hepatitis B in the population. Perinatal transmission occurs primarily in infants born to mothers with chronic hepatitis B or (rarely) mothers with acute hepatitis B during the third trimester of pregnancy or during the early postpartum period. Perinatal transmis sion is uncommon in North America and western Europe but occurs with great frequency and is the most important mode of HBV per petuation in East Asia and developing countries. Although the precise mode of perinatal transmission is unknown, and although ~10% of infections may be acquired in utero, epidemiologic evidence suggests that most infections occur approximately at the time of delivery and are not related to breast-feeding (which is not contraindicated in women with hepatitis B). The likelihood of perinatal transmission of HBV correlates with the presence of HBeAg and high-level viral replication; 90% of HBeAg-positive mothers but only 10–15% of anti-HBe-positive mothers transmit HBV infection to their offspring. In most cases, acute infection in the neonate is clinically asymptomatic, but the child is very likely to remain chronically infected. The over 290 million persons with chronic HBV infection in the world constitute the main reservoir of hepatitis B in human beings. Whereas serum HBsAg is infrequent (0.1–0.5%) in normal popula tions in the United States and western Europe, the global prevalence is
estimated at 3.5%, and a prevalence of up to 5–10% has been found in East Asia, sub-Saharan Africa, and tropical countries. The prevalence can be even higher in certain high-risk groups, including persons with Down syndrome, lepromatous leprosy, leukemia, Hodgkin disease, polyarteritis nodosa, and chronic renal disease on hemodialysis, as well as in injection drug users. Other groups with high rates of HBV infection include spouses of acutely infected persons; sexually promiscuous persons (especially promiscuous men who have sex with men); health care workers and first responders exposed to blood; persons who require repeated transfusions especially with pooled blood-product concentrates (e.g., hemophiliacs); residents and staff of custodial institutions for the developmentally handicapped; prisoners; and, to a lesser extent, family members of chronically infected patients. Because of highly sensitive virologic screening (antigen, antibody, and nucleic acid testing) of donor blood, the risk of acquiring HBV infection from a blood transfu sion is estimated to be 1 in 360,000. Prevalence of infection, modes of transmission, and human behav ior conspire to mold geographically different epidemiologic patterns of HBV infection. In East Asia and Africa, hepatitis B, a disease of the newborn and young children, is perpetuated by a cycle of maternalneonatal spread. In North America and western Europe, hepatitis B is primarily a disease of adolescence and early adulthood, the time of life when intimate sexual contact and recreational and occupational percutaneous exposures tend to occur. To some degree, however, this dichotomy between high-prevalence and low-prevalence geographic regions has been minimized by immigration from high-prevalence to low-prevalence areas. For example, in the United States, NHANES data from 2007 to 2012 revealed an overall prevalence of current HBV infection (detectable HBsAg) of 0.3%; however, the prevalence in Asian persons, 93% of whom were foreign-born, was tenfold higher, 3.1%, representing 50% of the U.S. national disease burden. As a result of adoption of safe behaviors in high-risk groups as well as screening and vaccination programs, the incidence of newly reported HBV infections fell by >80% in the United States during the 1990s and has remained low in the 21st century (with a low of 0.6 cases per 100,000 popula tion in 2021). Paralleling that trend, the imbalance between cases in U.S.-born and foreign-born persons widened; currently, imported cases in non-U.S.-born persons outnumber domestic cases by manyfold; in NHANES 2017–2020, the prevalence of HBV infection was 1.0% in foreign-born versus 0.2% in the entire cohort; non-U.S.-born persons accounted for 73.6% of all infections. The introduction of hepatitis B vaccine in the early 1980s and adoption of universal childhood vacci nation policies in many countries resulted in a dramatic, ~90% decline in the incidence of new HBV infections in those countries as well as in the dire consequences of chronic infection, including hepatocel lular carcinoma. In the United States, as demonstrated in NHANES 2007–2012, following the 1991 implementation of universal childhood vaccination, HBsAg seropositivity had declined in children aged 6–19 years to as low as 0.03%, an ~85% reduction. UNIVERSAL SCREENING FOR HEPATITIS B Populations and groups at high risk for hepatitis B are listed in Table 350-3. Screening for HBV infection used to be recommended in these high-risk populations; however, because risk-group screening had not been shown to be effective in reducing the prevalence of HBV infection in the popula tion and the majority of acute hepatitis B cases were found to occur in persons who were not in these high-risk groups, universal screening of all adults (≥18 years) for hepatitis B was recommended in 2023 by the CDC. Because current antiviral therapy has been highly effective in reducing the clinical progression and consequences of HBV infection, such universal screening was found to be cost-effective in reducing the morbidity and mortality associated with chronic hepatitis B. Hepatitis D Infection with HDV has a worldwide distribution, but two epidemiologic patterns exist. In Mediterranean countries (northern Africa, southern Europe, the Middle East), HDV infection is endemic among those with hepatitis B, and the disease is trans mitted predominantly by nonpercutaneous means, especially close personal contact. In nonendemic areas, such as the United States
TABLE 350-3 Populations with a High Risk for HBV Infectiona Persons born in countries/regions with a high (≥8%) and intermediate (≥2%) prevalence of HBV infection including immigrants and adopted children and including persons born in the United States who were not vaccinated as infants and whose parents emigrated from areas of high HBV endemicity Household and sexual contacts of, or needle sharing with, persons who have hepatitis B Babies born to HBsAg-positive mothers Persons who have used injection drugs Persons with multiple sexual contacts or a history of sexually transmitted disease Men who have sex with men Persons incarcerated in a correctional facility or other detention settings Persons with elevated alanine or aspartate aminotransferase levels Persons with HCV or HIV infection Hemodialysis patients Health care and laboratory workers and first responders exposed to blood aScreening for hepatitis B had been recommended in the past for persons in these high-risk groups; however, in 2023, the Centers for Disease Control and Prevention recommended universal screening of all adults (>18 years of age) for hepatitis B. Other groups who should be tested for hepatitis B include pregnant women; persons who are the source of blood or body fluids that would be an indication for postexposure prophylaxis (e.g., needlestick, mucosal exposure sexual assault); and persons who require immunosuppressive or cytotoxic therapy (including anti–tumor necrosis factor α therapy for rheumatologic or inflammatory bowel disorders). (where hepatitis D is rare among persons with chronic hepatitis B) and northern Europe, HDV infection is confined to persons exposed frequently to blood and blood products, primarily injection drug users (especially in HIV-infected injection drug users) and hemo philiacs. In the United States, the prevalence of HDV infection in the national population was 0.02% in NHANES 1999–2012 and 0.11% in NHANES 2011–2016; however, among HBsAg-positive persons, the prevalence of HDV infection is highest in injection drug users (11–36%) and hemophiliacs (19%). In one study of persons who inject drugs (PWID) in San Francisco, the overall prevalence of HDV infection was 1.1% but as high as 34.6% in PWID who had chronic HBV infection. HDV infection can be introduced into a population through drug users or by migration of persons from endemic to non endemic areas. Thus, patterns of population migration and human behavior facilitating percutaneous contact play important roles in the introduction and amplification of HDV infection. Occasionally, the migrating epidemiology of hepatitis D is expressed in explosive out breaks of severe hepatitis, such as those that have occurred in remote South American villages (e.g., “Lábrea fever” in the Amazon basin) as well as in urban centers in the United States. Ultimately, such out breaks of hepatitis D—either of co-infections with acute hepatitis B or of superinfections in those already infected with HBV—may blur the distinctions between endemic and nonendemic areas. On a global scale, HDV infection declined at the end of the 1990s. Even in Italy, an HDV-endemic area, public health measures introduced to control HBV infection (e.g., mass hepatitis B vaccination) resulted during the 1990s in a 1.5%/year reduction in the prevalence of HDV infec tion. Still, the frequency of HDV infection during the first decade of the twenty-first century has not fallen below levels reached during the 1990s; the reservoir has been sustained by survivors infected during 1970–1980 and recent immigrants from still-endemic (e.g., eastern Europe and Central Asia) to less-endemic countries. The current global prevalence of HDV infection has been estimated at
12 million people, albeit with significant regional variation. Of the eight HDV genotypes, genotype 1 is distributed worldwide, while the others are more geographically confined (e.g., genotypes 2 and 4 in the Far East, 3 in South America, and 5–8 in Africa). CHAPTER 350 Acute Viral Hepatitis Hepatitis C Routine screening of blood donors for HBsAg and the elimination of commercial blood sources in the early 1970s reduced the frequency of, but did not eliminate, transfusion-associ ated hepatitis. During the 1970s, the likelihood of acquiring hepatitis after transfusion of voluntarily donated, HBsAg-screened blood was
~10% per patient (up to 0.9% per unit transfused); 90–95% of these cases were classified, based on serologic exclusion of hepatitis A and B, as “non-A, non-B” hepatitis. For patients requiring transfusion of pooled products, such as clotting factor concentrates, the risk was even higher, up to 20–30%.
During the 1980s, voluntary self-exclusion of blood donors with risk factors for AIDS and then the introduction of donor screening for anti-HIV reduced further the likelihood of transfusion-associated hepatitis to <5%. During the late 1980s and early 1990s, the introduc tion first of “surrogate” screening tests for non-A, non-B hepatitis (ALT and anti-HBc, both shown to identify blood donors with a higher likelihood of transmitting non-A, non-B hepatitis to recipi ents) and, subsequently, after the discovery of HCV, progressively more sensitive immunoassays for anti-HCV and then the application of automated PCR testing of donated blood for HCV RNA reduced the risk of transfusion-associated hepatitis C even further, to almost imperceptible levels ranging between 1 in 2.3 million transfusions to 1 in 4.7 million transfusions. In addition to being transmitted by transfusion, hepatitis C can be transmitted by other percutaneous routes, such as injection drug use. This virus can be transmitted by occupational exposure to blood, and the likelihood of infection is increased in hemodialysis units. Although the frequency of transfusion-associated hepatitis C fell as a result of blood-donor screening, the overall frequency of reported hepatitis C cases did not change until the 1990s, when the overall fre quency of reported cases fell by 80%, in parallel with a reduction in the number of new cases in injection drug users, the source of most of the HCV reservoir. After the exclusion of anti-HCV-positive plasma units from the donor pool, rare, sporadic instances occurred of hepatitis C among recipients of immunoglobulin preparations for intravenous (but not intramuscular) use. PART 10 Disorders of the Gastrointestinal System Serologic evidence for HCV infection occurs in 90% of patients with a history of transfusion-associated hepatitis (almost all occurring before 1992, when second-generation HCV screening tests were intro duced); hemophiliacs and others treated with clotting factors; injection drug users; 60–70% of patients with sporadic “non-A, non-B” hepatitis who lack identifiable risk factors; 0.5% of volunteer blood donors; and, in the NHANES survey conducted in the United States between 1999 and 2002, 1.6% of the general population in the United States, which translated into 4.1 million persons (3.2 million with viremia), the majority of whom were unaware of their infections. Moreover, such population surveys do not include higher-risk groups such as incarcerated persons, homeless persons, and active injection drug users, indicating that the actual prevalence is even higher (estimated to add an additional 1 million with anti-HCV antibody and 0.8 million with HCV RNA in a later cohort assessed in 2003–2010). Comparable frequencies of HCV infection occur in most countries around the world, with 71 million persons infected worldwide, but extraordinarily high prevalences of HCV infection occur in certain countries such as Egypt, where >20% of the population (as high as 50% in persons born prior to 1960) in some cities is infected. The high frequency in Egypt is attributable to contaminated equipment used for medical procedures and unsafe injection practices in the 1950s to 1980s (during a campaign to eradicate schistosomiasis with intravenous tartar emetic). Thanks to a 2018–2019 Egyptian government program to screen its entire adult population (79% participation among >60 million people) for hepatitis C and treat infected persons (2.2 million, 4.6% of those screened; of the 83% with a documented outcome, 99% were cured; the cost to identify and cure a person was $130) with generic versions of direct-acting antiviral (DAA) therapy (Chap. 352), hepatitis C has been nearly eliminated there. In the United States, African Americans and Mexican Americans have higher frequencies of HCV infection than whites. Data from NHANES showed that between 1988 and 1994, 30- to 40-year-old men had the highest prevalence of HCV infection; however, in the NHANES survey conducted between 1999 and 2002, the peak age decile had shifted to those aged 40–49 years; an increase in hepatitis C–related mortality has paralleled this secular trend, increasing since 1995 predominantly in the 45- to 65-year age group. Thus, despite an
80% reduction in new reported HCV infections during the 1990s, the prevalence of HCV infection in the population was sustained by an aging cohort that had acquired their infections three to four decades earlier, during the 1960s and 1970s, as a result predominantly of selfinoculation with recreational drugs. Retrospective phylogenetic map ping of >45,000 HCV genotype 1a isolates revealed that the hepatitis C epidemic emerged in the United States between 1940 and 1965, peaking in 1950 and aligning temporally with the post–World War II expansion of medical procedures (including reuse of glass syringes). Thus, HCV was amplified iatrogenically not only in Egypt but also in the United States; in the United States, the seeds sewn by medical procedures in the 1950s were reaped in the 1960s and 1970s among transfusion recipients and injection drug users, even those whose drug use was confined to brief adolescent experimentation. In NHANES 2003–2010, the prevalence of HCV infection (HCV RNA reactivity) in the United States had actually fallen to 1% (2.7 million persons) from 1.3% (3.2 million) the decade before (NHANES 1999– 2002), attributable to deaths among the HCV-infected population. In NHANES data from 2013–2016, the prevalence of current HCV infec tion (HCV RNA reactivity) had fallen lower, to 0.9%. Worth emphasiz ing, however, is that NHANES datasets account for only the domiciled and noninstitutionalized U.S. civilian population. In the same time frame, the prevalence among incarcerated and homeless persons was estimated to be 10.7%. As deaths resulting from HIV infection fell after 1999, age-adjusted mortality associated with HCV infection surpassed that of HIV infec tion in 2007; >70% of HCV-associated deaths occurred in the “baby boomer” cohort born between 1945 and 1965. By 2012, HCV mortality had surpassed deaths from HIV, tuberculosis, hepatitis B, and 57 other notifiable infectious diseases (i.e., all infectious diseases) reported to the CDC. In NHANES 1999–2002, compared to the 1.6% prevalence of HCV infection in the population at large, the prevalence in the 1945–1965 birth cohort was 3.2%, representing three-quarters of all infected persons. Therefore, in 2012, the CDC and, in 2013, the U.S. Preventive Services Task Force (USPSTF) recommended that all per sons born between 1945 and 1965 be screened for hepatitis C, without ascertainment of risk, a recommendation shown to be cost-effective and predicted to identify 800,000 infected persons. Because of the availability of highly effective antiviral therapy, such screening would have the potential to avert 200,000 cases of cirrhosis and 47,000 cases of hepatocellular carcinoma and to prevent 120,000 hepatitis-related deaths; with the availability of the new generation of DAAs (efficacy
95%, see Chap. 352), screening baby boomers and treating those with hepatitis C have been predicted to reduce the HCV-associated disease burden by 50–70% through 2050. Still, persons with chronic hepatitis C identified by 1945–1965 birthcohort screening are older than 50, and by the time they are identi fied, >20% already have advanced liver disease. In 2020, based on (1) the 95–99% efficacy of all-oral, well-tolerated, highly effective DAAs; (2) the demonstration that the endpoint of DAA therapy (sustained virologic response) was associated with a marked decrease in liver and all-cause mortality, cirrhosis, and hepatocellular carcinoma (Chap. 352); (3) a reduction in the initially high cost of DAA therapy; (4) the demonstration of higher cost-effectiveness of screening all adults rather than birth-cohort screening; and (5) the shifting demographics of HCV infection (see below), especially since 2010, toward a younger popula tion exposed through injection drug use, the American Association for the Study of Liver Diseases and the Infectious Diseases Society of America as well as the USPSTF and CDC expanded recommended hepatitis C screening to all adolescents and adults aged 18–79 (and because of the substantial increase in HCV infections among women of child-bearing age [age 20–39], expanded such screening to pregnant women). Hepatitis C accounts for 40% of chronic liver disease and, before the introduction of high-efficacy DAA therapy, was the most fre quent indication for liver transplantation; hepatitis C is estimated to account for 8000–10,000 deaths per year in the United States. The distribution of HCV genotypes varies in different parts of the world. Worldwide, genotype 1 is the most common. In the United States, genotype 1 accounts for 70% of HCV infections, whereas genotypes 2
and 3 account for the remaining 30%; among African Americans, the frequency of genotype 1 is even higher (i.e., 90%). Genotype 4 pre dominates in Egypt; genotype 5 is localized to South Africa, genotype 6 to Hong Kong, and genotype 7 to Central Africa. As a bloodborne infection, HCV potentially can be transmitted sexually and perinatally; however, both modes of transmission are inefficient for hepatitis C. Although 10–15% of patients with acute hepatitis C report having potential sexual sources of infection, most studies have failed to identify sexual transmission of this agent. The chances of sexual and perinatal transmission have been estimated to be ~5% but have shown in a prospective study to be only 1% between monogamous sexual partners, well below comparable rates for HIV and HBV infections. An important exception to the low rate of peri natal transmission is the high risk—typically in excess of 10%—in babies born to HIV-HCV coinfected mothers. Moreover, sexual transmission appears to be confined to such subgroups as persons with multiple sexual partners and sexually transmitted diseases; for example, isolated clusters of sexually transmitted HCV infection have been reported in HIV-infected men who have sex with men. Breast-feeding does not increase the risk of HCV infection between an infected mother and her infant. Infection of health workers is not dramatically higher than among the general population; however, health workers are more likely to acquire HCV infection through accidental needle punctures, the efficiency of which is ~3%. Infec tion of household contacts is rare as well. Most asymptomatic blood donors found to have anti-HCV and ~20–30% of persons with reported cases of acute hepatitis C do not fall into a recognized risk group; however, many such blood donors do recall long forgotten, risk-associated behaviors when questioned carefully. Besides persons born between 1945 and 1965, other groups with an increased frequency of HCV infection are listed in Table 350-4. In immunosuppressed individuals, levels of anti-HCV may be undetect able, and a diagnosis may require testing for HCV RNA. Although new acute cases of hepatitis C are rare outside of the injection drug–using community, newly diagnosed cases are common among otherwise healthy persons who experimented briefly with injection drugs, as noted above, four or five decades earlier. Such instances usually remain unrecognized for years, until unearthed by laboratory screening for routine medical examinations, insurance applications, and attempted blood donation. Although, overall, the annual inci dence of new HCV infections has continued to fall, the rate of new infections has been increasing since 2002, has accelerated since 2010 (tripling from 0.3/100,000 to 1.2/100,000 between 2009 and 2018), and has been amplified by the recent epidemic of opioid use in a new cohort of young injection drug users aged 20–39 years (accounting for a 3.8-fold increase in cases between 2010 and 2017 and for more than two-thirds of all acute cases), who, unlike older cohorts, had not TABLE 350-4 Populations with a High Risk for HCV Infectiona All adults aged 18–79 should be screened, a recommendation that supplants the earlier focus on persons born between 1945 and 1965a Persons who have ever used injection drugs Persons with HIV infection Hemophiliacs treated with clotting factor concentrates prior to 1987 Persons who have ever undergone long-term hemodialysis Persons with unexplained elevations of aminotransferase levels Transfusion or transplantation recipients prior to July 1992 Recipients of blood or organs from a donor found to be positive for hepatitis C Children born to women with hepatitis C Health care, public safety, and emergency medical personnel following needle injury or mucosal exposure to HCV-contaminated blood Sexual partners of persons with hepatitis C infection Pregnant women aScreening for hepatitis C had been recommended in the past for persons in these high-risk groups; however, in 2020, the Centers for Disease Control and Prevention recommended universal screening of all adults (>18 years of age) for hepatitis C.
learned to take precautions to prevent bloodborne infections. Reflect ing this emerging development, the prevalence of current HCV infec tion (HCV RNA reactivity) in the United States rose from 0.65% (1.7 million persons) in a 2010–2014 NHANES analysis to 0.9% (2.04 million persons) in a 2013–2016 NHANES analysis. Moreover, based on an estimate of populations excluded from this NHANES analysis, the prevalence would be even higher, 0.93% (2.27 million persons). This late temporal trend was attributed to the increase of acute cases in injections drug users, driven by increases in states most affected by the opioid/injection drug use epidemic. Also, in parallel with this trend, the prevalence of HCV infection in women aged 15–44 years (of child-bearing age) doubled between 2016 and 2014; accordingly, screening of pregnant women for HCV infection is now recom mended as well.
Hepatitis E This type of hepatitis, identified in India, Asia, Africa, the Middle East, and Central America (endemic areas), resembles hepatitis A in its primarily enteric mode of spread. The commonly recognized cases occur after contamination of water supplies such as after monsoon flooding, but sporadic, isolated cases occur. An epidemiologic feature that distinguishes HEV from other enteric agents is the rarity of secondary person-to-person spread from infected persons to their close contacts. Large waterborne outbreaks in endemic areas are linked to genotypes 1 and 2, arise in popula tions that are immune to HAV, favor young adults, and account for antibody prevalences of 30–80%. The worldwide annual incidence of acute HEV infections has been estimated conservatively to be at least 20 million (of which 3.3 million are symptomatic), rendering HEV infection as the most common cause of acute viral hepatitis. In nonendemic areas of the world, such as the United States, clinically apparent acute hepatitis E is extremely rare; however, during the 1988–1994 NHANES III survey conducted by the U.S. Public Health Service, the prevalence of anti-HEV was 21%, reflecting subclinical infections, infection with genotypes 3 and 4, predominantly in older males (>60 years). A repeat NHANES study in 2009–2010, however, showed a substantial 70% two-decade reduction in anti-HEV to only 6%, more consistent with the rarity of acute hepatitis E in the United States than the previous NHANES result would suggest and perhaps a reflection of a more specific anti-HEV assay used in the second time period. A subsequent examination of the 2009–2016 NHANES dataset demonstrated a seroprevalence of HEV infection of 6.1%. Moreover, supporting the concern for influence of assay dif ferences on population estimates, a re-interrogation of the NHANES III cohort based on assays of the highest sensitivity identified varying prevalence estimates ranging from 16–21%. Again, in the 2009–2016 cohort, older age was associated with anti-HEV seropositivity, as were non-Hispanic Asian ethnicity and birth outside the United States. CHAPTER 350 Acute Viral Hepatitis In nonendemic areas, HEV accounts for only a small propor tion of cases of sporadic (labeled “autochthonous” or indigenous) hepatitis; however, cases imported from endemic areas have been found in the United States. Evidence supports a zoonotic reservoir for HEV primarily in swine (but also in deer, camels, and rabbits), which may account for the mostly subclinical infections primarily of genotypes 3 and 4 in nonendemic areas. Globally, ~60% of swine have evidence of prior HEV infection, and 13% have active HEV infection. A previously unrecognized high distribution of HEV infec tion, linked to uncooked or undercooked pork-product ingestion, has been discovered in western Europe (e.g., in Germany, an estimated annual incidence of 300,000 cases and a 17% prevalence of anti-HEV among adults; in France, a 22% prevalence of anti-HEV in healthy blood donors). ■ ■CLINICAL AND LABORATORY FEATURES Symptoms and Signs Acute viral hepatitis occurs after an incuba tion period that varies according to the responsible agent. Generally, incubation periods for hepatitis A range from 15 to 45 days (mean,
4 weeks), for hepatitis B and D from 30 to 180 days (mean, 8–12 weeks), for hepatitis C from 15 to 160 days (mean, 7 weeks), and for hepatitis E from 14 to 60 days (mean, 5–6 weeks). The prodromal symptoms of
Many patients will not become jaundiced (anicteric hepatitis), and the likelihood of jaundice varies by virus (e.g., substantially more com mon in acute hepatitis B than in acute hepatitis C). With the onset of clinical jaundice, the constitutional prodromal symptoms usually diminish, but in some patients, mild weight loss (2.5–5 kg) is common and may continue during the entire icteric phase. The liver becomes enlarged and tender and may be associated with right upper quadrant pain and discomfort. Infrequently, patients present with a cholestatic picture, suggesting extrahepatic biliary obstruction. Splenomegaly and cervical adenopathy are present in 10–20% of patients with acute hepatitis. Rarely, a few spider angiomas appear during the icteric phase and disappear during convalescence. During the recovery phase, consti tutional symptoms disappear, but usually some liver enlargement and abnormalities in liver biochemical tests are still evident. The duration of the posticteric phase is variable, ranging from 2 to 12 weeks, and is usually more prolonged in acute hepatitis B and C. Complete clinical and biochemical recovery is to be expected 1–2 months after all cases of hepatitis A and E and 3–4 months after the onset of jaundice in three-quarters of uncomplicated, self-limited cases of hepatitis B and C (among healthy adults, acute hepatitis B is self-limited in 95–99%, whereas hepatitis C is self-limited in only ~15–20%). In the remainder, biochemical recovery may be delayed. PART 10 Disorders of the Gastrointestinal System Infection with HDV can occur in the presence of acute (coinfec tion) or chronic (superinfection) HBV infection; the duration of HBV infection determines the duration of HDV infection. When acute HDV and HBV infections occur simultaneously (coinfection), clini cal and biochemical features may be indistinguishable from those of HBV infection alone, and the clinical severity can range from mild to fulminant disease. When acute HDV infection occurs in a patient with preexisting chronic HBV infection (superinfection), the clinical presentation is more commonly severe, and the HDV superinfection mirrors the chronic HBV infection in becoming persistent. In such cases, the HDV superinfection appears as a clinical exacerbation or an episode resembling acute viral hepatitis in someone already chronically infected with HBV. Superinfection with HDV in a patient with chronic hepatitis B often leads to clinical deterioration (see below). In addition to superinfections with other hepatitis agents, acute hepatitis-like clinical events in persons with chronic hepatitis B may accompany spontaneous HBeAg to anti-HBe seroconversion or spon taneous reactivation (i.e., reversion from relatively nonreplicative to replicative infection). Occasionally, acute clinical exacerbations of chronic hepatitis B may represent the emergence of a precore mutant (see “Virology and Etiology”), and the subsequent course in such patients may be characterized by periodic exacerbations. Reactivations can occur as well in therapeutically immunosuppressed patients with chronic HBV infection when cytotoxic/immunosuppressive drugs are withdrawn; in these cases, restoration of immune competence is thought to allow resumption of previously checked cell-mediated immune cytolysis of HBV-infected hepatocytes. Cancer-directed thera pies can also result in HBV or HCV reactivation, with the greatest risk from the B-cell (CD20)-depleting antibody rituximab in HBV. Immune checkpoint inhibitors (ICIs) have been an important new class of anti tumor therapies, and the impact of ICI therapy on hepatitis caused by chronic HBV or HCV infection is not yet well characterized, but acute exacerbations of chronic viral hepatitis have been reported and may be related to restoring function of “exhausted” T-cell populations. Of interest, however, in pilot studies of ICIs given for chronic hepatitis B,
restoration of T-cell function has also been associated with functional cure in a limited subset. Laboratory Features The serum aminotransferases aspartate aminotransferase (AST) and ALT (previously designated SGOT and SGPT) increase to a variable degree during the prodromal phase of acute viral hepatitis and precede the rise in bilirubin level (Figs. 350-2 and 350-4). The level of these enzymes, however, does not correlate well with the degree of liver cell damage. Peak levels vary from ~400 to ~4000 IU or more; these levels are usually reached at the time the patient is clinically icteric and diminish progressively during the recov ery phase of acute hepatitis. The diagnosis of anicteric hepatitis is based on clinical features and on aminotransferase elevations. Jaundice is usually visible in the sclera or skin when the serum bilirubin value is >43 μmol/L (2.5 mg/dL). When jaundice appears, the serum bilirubin typically rises to levels ranging from 85 to 340 μmol/L (5–20 mg/dL). The serum bilirubin may continue to rise despite falling serum aminotransferase levels. In most instances, the total bilirubin is equally divided between the conjugated and unconjugated fractions. Bilirubin levels >340 μmol/L (20 mg/dL) extending and persisting late into the course of viral hepatitis are more likely to be associated with severe disease. In certain patients with underlying hemolytic anemia, however, such as glucose-6-phosphate dehydrogenase deficiency and sickle cell anemia, a high serum bilirubin level is common, resulting from superimposed hemolysis. In such patients, bilirubin levels >513 μmol/L (30 mg/dL) have been observed and are not necessarily associated with a poor prognosis. Neutropenia and lymphopenia are transient and are followed by a relative lymphocytosis. Atypical lymphocytes (varying between 2 and 20%) are common during the acute phase. Measurement of the pro thrombin time (PT) is important in patients with acute viral hepatitis, because a prolonged value may reflect a severe hepatic synthetic defect, signify extensive hepatocellular necrosis, and indicate a worse progno sis. Occasionally, a prolonged PT may occur with only mild increases in the serum bilirubin and aminotransferase levels. Prolonged nausea and vomiting, inadequate carbohydrate intake, and poor hepatic glycogen reserves may contribute to hypoglycemia noted occasionally in patients with severe viral hepatitis. Serum alkaline phosphatase may be normal or only mildly elevated, whereas a fall in serum albumin is uncom mon in uncomplicated acute viral hepatitis. In some patients, mild and transient steatorrhea has been noted, as well as slight microscopic hematuria and minimal proteinuria. A diffuse but mild elevation of the γ globulin fraction is common during acute viral hepatitis. Serum IgG and IgM levels are elevated in about one-third of patients during the acute phase of viral hepatitis, but the serum IgM level is elevated more characteristically during acute hepatitis A. During the acute phase of viral hepatitis, antibodies to smooth muscle and other cell constituents may be present, and low titers of rheumatoid factor, nuclear antibody, and heterophile antibody can also be found occasionally. In hepatitis C and D, antibodies to LKM may occur; however, the species of LKM antibodies in the two types of hepatitis are different from each other as well as from the LKM anti body species characteristic of autoimmune hepatitis type 2 (Chap. 352). The autoantibodies in viral hepatitis are nonspecific and can also be associated with other viral and systemic diseases. In contrast, virus-specific antibodies, which appear during and after hepatitis virus infection, are serologic markers of diagnostic importance. As described above, serologic tests are available routinely with which to establish a diagnosis of hepatitis A, B, D, and C. Tests for fecal or serum HAV are not routinely available. Therefore, a diagnosis of hepatitis A is based on detection of IgM anti-HAV during acute illness (Fig. 350-2). Worth considering, false-positive IgM anti-HAV results have been observed in rheumatologic diseases (especially those with rheumatoid factor, which can mediate nonspecific binding in solidphase immunoassays) and, very rarely, in other acute viral infections, such as with Epstein-Barr virus (EBV). A diagnosis of HBV infection can usually be made by detection of HBsAg in serum. Infrequently, levels of HBsAg are too low to be detected during acute HBV infection, even with contemporary, highly
sensitive immunoassays. In such cases, the diagnosis can be established by the presence of IgM anti-HBc. The titer of HBsAg bears little relation to the severity of clinical disease. Indeed, an inverse correlation exists between the serum con centration of HBsAg and the degree of liver cell damage. For example, titers are highest in immunosuppressed patients, lower in patients with chronic liver disease (but higher in mild chronic than in severe chronic hepatitis), and very low in patients with acute fulminant hepatitis. These observations suggest that in hepatitis B the degree of liver cell damage and the clinical course are related to variations in the patient’s immune response to HBV rather than to the amount of circulating HBsAg. In immunocompetent persons, however, a correlation exists between markers of HBV replication and liver injury (see below). Another important serologic marker in patients with hepatitis B is HBeAg. Its principal clinical usefulness is as an indicator of relative infectivity. Because HBeAg is invariably present during early acute hepatitis B, HBeAg testing is indicated primarily in chronic infection. In patients with hepatitis B surface antigenemia of unknown dura tion (e.g., blood donors found to be HBsAg positive), testing for IgM anti-HBc may be useful to distinguish between acute or recent infec tion (IgM anti-HBc positive) and chronic HBV infection (IgM antiHBc negative, IgG anti-HBc positive). A false-positive test for IgM anti-HBc may be encountered in patients with high-titer rheumatoid factor. Also, IgM anti-HBc may be reexpressed during acute reactiva tion of chronic hepatitis B. Anti-HBs is rarely detectable in the presence of HBsAg in patients with acute hepatitis B, but up to 10% of persons with chronic HBV infection may harbor anti-HBs. Variability of the a determinant of the S protein is thought to be central to this anti-HBs. The antibody is directed not against the common group determinant, a, but against the relatively closely related heterotypic subtype determinant (e.g., HBsAg of subtype ad with anti-HBs of subtype y). Clinically, patients with both HBsAg and anti-HBs tend to have higher aminotransferase levels, are older, and are more likely to have advanced fibrosis or cirrhosis (pri marily in HBeAg-negative patients). This serologic pattern in patients with chronic hepatitis B is not a harbinger of imminent HBsAg clear ance; however, in patients clearing HBsAg as acute hepatitis B resolves, infrequently, transiently, both HBsAg and anti-HBs may be detected simultaneously. After immunization with hepatitis B vaccine, which consists of HBsAg alone, anti-HBs is the only serologic marker to appear. The commonly encountered serologic patterns of hepatitis B and their interpretations are summarized in Table 350-5. Tests for the detec tion of HBV DNA in liver and serum are now available. Like HBeAg, serum HBV DNA is an indicator of HBV replication, but tests for HBV TABLE 350-5 Commonly Encountered Serologic Patterns of Hepatitis B Infection HBsAg ANTI-HBs ANTI-HBc HBeAg ANTI-HBe INTERPRETATION + − IgM + − Acute hepatitis B, high infectivitya + − IgG + − Chronic hepatitis B, high infectivity + − IgG − + 1. Late acute or chronic hepatitis B, low infectivity 2. HBeAg-negative (“precore-mutant”) hepatitis B (chronic or, rarely, + + + +/− +/− 1. HBsAg of one subtype and heterotypic anti-HBs (common) 2. Process of seroconversion from HBsAg to anti-HBs (rare) − − IgM +/− +/− 1. Acute hepatitis Ba − − IgG − +/− 1. Low-level hepatitis B carrier 2. Hepatitis B in remote past − + IgG − +/− Recovery from hepatitis B − + − − − 1. Immunization with HBsAg (after vaccination) 2. Hepatitis B in the remote past (?) 3. False-positive aIgM anti-HBc may reappear during acute reactivation of chronic hepatitis B. Note: See text for abbreviations.
DNA are more sensitive and quantitative. First-generation hybridiza tion assays for HBV DNA had a sensitivity of 105−106 virions/mL, a relative threshold below which infectivity and liver injury are limited and HBeAg is usually undetectable. Currently, testing for HBV DNA has shifted from insensitive hybridization assays to amplification assays (e.g., the PCR-based assay, which can detect as few as 10 or 100 virions/ mL); among the commercially available PCR assays, the most useful are those with the highest sensitivity (5–10 IU/mL) and the largest dynamic range (100–109 IU/mL). With increased sensitivity, amplification assays remain reactive well below the current 103–104 IU/mL threshold for infectivity and liver injury. These markers are useful in following the course of HBV replication in patients with chronic hepatitis B receiving antiviral chemotherapy (Chap. 352). Except for the early decades of life after perinatally acquired HBV infection (see above), in immuno competent adults with chronic hepatitis B, a general correlation exists between the level of HBV replication, as reflected by the level of serum HBV DNA, and the degree of liver injury. High-serum HBV DNA levels, increased expression of viral antigens, and necroinflammatory activity in the liver go hand in hand unless immunosuppression inter feres with cytolytic T-cell responses to virus-infected cells; reduction of HBV replication with antiviral drugs tends to be accompanied by an improvement in liver histology. Among patients with chronic hepatitis B, high levels of HBV DNA increase the risk of cirrhosis, hepatic decompensation, and hepatocellular carcinoma (see “Compli cations and Sequelae”).
A diagnosis of acute hepatitis C hinges upon the presence of antiHCV and/or HCV RNA with or without the presence of anti-HCV. Compared with the other viral hepatitides, assays specific for IgM anti-HCV, never found to be of clinical value, are lacking; available highly sensitive assays detect IgG anti-HCV. While, in the past, with early-generation immunoassays, up to 12 weeks could elapse before anti-HCV became detectable during acute hepatitis C, with contempo rary, late-generation assays, anti-HCV is readily detectable during early acute hepatitis C. Thus, when contemporary immunoassays are used, anti-HCV can be detected in acute hepatitis C during the initial phase of elevated aminotransferase activity and remains detectable both after recovery from acute infection as well as during chronic infection. As alluded to above, nonspecificity can confound immunoassays for anti-HCV, especially in persons with a low prior probability of infec tion, such as volunteer blood donors, or in persons with circulating rheumatoid factor, which can bind nonspecifically to assay reagents; testing for HCV RNA can be used in such settings to distinguish between true-positive and false-positive anti-HCV determinations. While spontaneous recovery from acute HCV infection occurs no more often than 15–20% of the time, persons who do recover will have CHAPTER 350 Acute Viral Hepatitis acute) 2. Anti-HBc “window”
a persistent anti-HCV but are not protected against reinfection. In high-risk groups, notably PWID, a pattern of positive anti-HCV and HCV RNA may reflect acute reinfection rather than chronic infection. In this setting, prior laboratory tests and clinical history are critical in differentiating between chronic and repeat acute infections.
Assays for HCV RNA are the most sensitive tests for HCV infec tion and represent the “gold standard” in establishing a diagnosis of hepatitis C. HCV RNA can be detected even before acute elevation of aminotransferase activity and before the appearance of anti-HCV in patients with acute hepatitis C. In addition, HCV RNA remains detect able indefinitely, although at varying levels, in patients with chronic hepatitis C. In the very small minority of patients with hepatitis C who lack anti-HCV, a diagnosis can be supported by detection of HCV RNA. In the rare instance when all these tests are negative and the patient has a well-characterized case of hepatitis after percutaneous exposure to blood or blood products, a diagnosis of hepatitis caused by an unidentified agent can be entertained. Amplification techniques are required to detect HCV RNA. Cur rently, such target amplification (i.e., synthesis of multiple copies of the viral genome) is achieved by PCR, in which the viral RNA is reverse transcribed to complementary DNA and then amplified by repeated cycles of DNA synthesis. Quantitative PCR assays provide a measurement of relative “viral load”; current PCR assays have a sensitivity of 10 (lower limit of detection) to 25 (lower limit of quan titation) IU/mL and a wide dynamic range (10–107 IU/mL). Determi nation of HCV RNA level is not a reliable marker of disease severity or prognosis but is helpful in predicting relative responsiveness to antiviral therapy. The same is true for determinations of HCV geno type (Chap. 352). Of course, HCV RNA monitoring during and after antiviral therapy is the sine qua non for determining on-treatment and durable responsiveness. PART 10 Disorders of the Gastrointestinal System A proportion of patients with hepatitis C have isolated anti-HBc in their blood, a reflection of a common risk in certain populations of exposure to multiple bloodborne hepatitis agents. The anti-HBc in such cases is almost invariably of the IgG class and usually represents HBV infection in the remote past (HBV DNA undetectable); it rarely represents current HBV infection with low-level virus carriage. Detect able anti-HCV in the absence of HCV RNA signifies spontaneous or therapeutically induced recovery from (“cured”) hepatitis C. The presence of HDV infection can be identified by demonstrating intrahepatic HDV antigen or, more practically, an anti-HDV (IgM or IgG) seroconversion (a rise in titer of anti-HDV or de novo appearance of anti-HDV). Serum HDV RNA or antigen can be detected early dur ing acute coinfection but is often transient and detectable only briefly, if at all. Because anti-HDV is often undetectable once HBsAg disap pears, retrospective serodiagnosis of acute self-limited, simultaneous HBV and HDV infection is difficult. Early diagnosis of acute infection may be hampered by a delay of up to 30–40 days in the appearance of IgG anti-HDV. When a patient presents with acute hepatitis and has HBsAg and anti-HDV in serum, determination of the class of anti-HBc is helpful in establishing the relationship between infection with HBV and HDV. TABLE 350-6 Simplified Diagnostic Approach in Patients Presenting with Acute Hepatitis SEROLOGIC TESTS OF PATIENT’S SERUM DIAGNOSTIC INTERPRETATION HBsAg IgM ANTI-HAV IgM ANTI-HBc ANTI-HCV HCV RNA + − + − Acute hepatitis B + − − − Chronic hepatitis B + + − − Acute hepatitis A superimposed on chronic hepatitis B + + + − Acute hepatitis A and B − + − − Acute hepatitis A − + + − Acute hepatitis A and B (HBsAg below detection threshold) − − + − Acute hepatitis B (HBsAg below detection threshold) − − − Either + Acute hepatitis C (vs. chronic HCV) Note: See text for abbreviations.
Although IgM anti-HBc does not distinguish absolutely between acute and chronic HBV infection, its presence is a reliable indicator of recent infection and its absence a reliable indicator of infection in the remote past. In simultaneous acute HBV and HDV infections, IgM anti-HBc will be detectable, whereas in acute HDV infection superimposed on chronic HBV infection, anti-HBc will be of the IgG class. Assays for HDV RNA, available in specialized laboratories and yet to be standard ized, can be used to confirm HDV infection and to monitor treatment during chronic infection. The serologic/virologic course of events during acute hepatitis E is entirely analogous to that of acute hepatitis A, with brief fecal shedding of virus and viremia and an early IgM anti-HEV response that predom inates during approximately the first 3 months but is eclipsed thereafter by long-lasting IgG anti-HEV. Diagnostic tests of varying reliability for hepatitis E are commercially available outside the United States; in the United States, although tests for HEV infection are not approved by the FDA, reliable diagnostic serologic/virologic assays can be performed at the CDC or other commercial or academic laboratories. Liver biopsy is rarely necessary or indicated in acute viral hepatitis, except when the diagnosis is questionable or when clinical evidence suggests an alternate diagnosis of chronic hepatitis (e.g., autoimmune hepatitis). A diagnostic algorithm can be applied in the evaluation of cases of acute viral hepatitis. A patient with acute hepatitis should undergo five serologic tests: HBsAg, IgM anti-HAV, IgM anti-HBc, anti-HCV, and HCV RNA (Table 350-6). The presence of HBsAg, with or without IgM anti-HBc, represents HBV infection. If IgM anti-HBc is present, the HBV infection is considered acute (or, less commonly, an acute reac tivation); if IgM anti-HBc is absent, the HBV infection is considered chronic. A diagnosis of acute hepatitis B can be made in the absence of HBsAg when IgM anti-HBc is detectable. A diagnosis of acute hepatitis A is based on the presence of IgM anti-HAV. If IgM anti-HAV coexists with HBsAg, a diagnosis of simultaneous HAV and HBV infections can be made; if IgM anti-HBc (with or without HBsAg) is detectable, the patient has simultaneous acute hepatitis A and B, and if IgM anti-HBc is undetectable, the patient has acute hepatitis A superimposed on chronic HBV infection. In a patient with an acute hepatitis illness, the presence of anti-HCV supports a diagnosis of acute hepatitis C. In the past, sensitivity of anti-HCV assays was limited during acute hepatitis, leading to a delay in the appearance anti-HCV; however, contemporary assays detect anti-HCV reliably during acute hepatitis. If acute hepatitis C is suspected but anti-HCV is undetectable, testing for HCV RNA helps to establish the diagnosis. The serologic diagnosis of acute hepa titis C or B may be challenging, for example, when an acute hepatitislike illness occurs in someone already infected chronically with HBV or HCV. Still, when encountering a person with acute hepatitis, a series of standard serologic assays for hepatitis A, B, and C is a reliable first step. If these assays are all negative, testing for hepatitis E, especially in the presence of risk factors, is available from specialty laboratories or the CDC. Acute hepatitis D belongs in the differential diagnosis of acute hepatitis, but negative serologic testing for hepatitis B excludes hepatitis D infection. In the setting of serologically documented acute
hepatitis B, patients who are at high risk for hepatitis D are candidates to be tested for anti-HDV and/or HDV RNA. Absence of all serologic markers is consistent with a diagnosis of “non-A-E,” hepatitis (no other proven human hepatitis viruses have been identified). As noted above, an outbreak of severe acute liver injury and liver failure in children was found to be associated with adenovirus infection, and elevations in aminotransferase levels are observed as well in a variety of other acute viral illnesses. In patients with chronic hepatitis, initial testing should consist of HBsAg and anti-HCV. Anti-HCV supports and HCV RNA testing establishes the diagnosis of chronic hepatitis C. If a serologic diagno sis of chronic hepatitis B is made, testing for HBeAg and anti-HBe is indicated to evaluate relative infectivity. Testing for HBV DNA in such patients provides a more quantitative and sensitive measure of the level of virus replication and therefore is very helpful during antiviral therapy (Chap. 352). In patients with established chronic hepatitis B and normal aminotransferase activity in the absence of HBeAg, serial testing over time is often required to distinguish between the inactive carrier state and HBeAg-negative chronic hepatitis B with fluctuating virologic and necroinflammatory activity. In persons with hepatitis B, testing for anti-HDV is useful in those with severe and fulminant disease, with severe chronic disease, with chronic hepatitis B and acute hepatitis-like exacerbations, with frequent percutaneous exposures (or known HBV acquisition from percutaneous exposure), and from areas where HDV infection is endemic. ■ ■PROGNOSIS Virtually all previously healthy patients with hepatitis A recover completely with no clinical sequelae. Similarly, in acute hepatitis B, 95–99% of previously healthy adults have a favorable course and recover completely. Certain clinical and laboratory features, how ever, suggest a more complicated and protracted course. Patients of advanced age and with serious underlying medical disorders may have a prolonged course and are more likely to experience severe hepatitis. Initial presenting features such as ascites, peripheral edema, and symptoms of hepatic encephalopathy suggest a poorer prognosis. In addition, a prolonged PT, low serum albumin level, hypoglycemia, and very high serum bilirubin values suggest severe hepatocellular disease. Patients with these clinical and laboratory features deserve prompt hospital admission. The case-fatality rate in hepatitis A and B is very low (~0.1%) but is increased by advanced age and underlying debilitating disorders. Among patients ill enough to be hospitalized for acute hepatitis B, the fatality rate is 1%. Hepatitis C is less severe during the acute phase than hepatitis B and is more likely to be anic teric; fatalities are rare, but the precise case-fatality rate is not known. Interestingly, while spontaneous resolution of HCV is the exception rather than the rule, symptomatic infection (and icteric hepatitis in particular) is associated with a higher likelihood of viral contain ment. In outbreaks of waterborne hepatitis E (genotypes 1 and 2) in India and Asia, the case-fatality rate is 1–2% and up to 10–20% in pregnant women. Contributing to fulminant hepatitis E in endemic countries (but only very rarely or not at all in nonendemic coun tries) are instances of acute hepatitis E superimposed on underlying chronic liver disease (“acute-on-chronic” liver disease). Patients with simultaneous acute hepatitis B and D coinfection do not necessarily experience a higher mortality rate than do patients with acute hepati tis B alone; however, in several outbreaks of acute simultaneous HBV and HDV infection among injection drug users, the case-fatality rate was ~5%. When HDV superinfection occurs in a person with chronic hepatitis B, the likelihood of fulminant hepatitis and death is increased substantially. Although the case-fatality rate for hepatitis D is not known definitively, in outbreaks of severe HDV superinfection in isolated populations with a high hepatitis B carrier rate (“Lábrea fever”), a mortality rate >20% has been recorded. ■ ■COMPLICATIONS AND SEQUELAE A small proportion of patients with hepatitis A experience relaps ing hepatitis weeks to months after apparent recovery from acute hepatitis. Relapses are characterized by recurrence of symptoms,
aminotransferase elevations, occasional jaundice, and fecal excretion of HAV. Another unusual variant of acute hepatitis A is cholestatic hepatitis, characterized by protracted cholestatic jaundice and pruritus. Rarely, liver test abnormalities persist for many months, even up to 1 year. Even when these complications occur, hepatitis A remains selflimited and does not progress to chronic liver disease.
During the prodromal phase of acute hepatitis B, a serum sick ness–like syndrome characterized by arthralgia or arthritis, rash, angioedema, and, rarely, hematuria and proteinuria may develop in 5–10% of patients. This syndrome occurs before the onset of clini cal jaundice, and these patients are often diagnosed erroneously as having rheumatologic diseases. The diagnosis can be established by measuring serum aminotransferase levels, which are almost invariably elevated, and serum HBsAg. In patients with chronic hepatitis B or C, immune complex and other extrahepatic manifestations may occur, including metabolic disorders (including insulin resistance and other manifestations of the metabolic syndrome), dermatologic disorders (e.g., porphyria cutanea tarda and lichen planus in chronic hepatitis C), lymphoproliferative and rheumatologic disorders, and, in addition to hepatocellular carcinoma, nonliver malignancies (Chap. 352). In addition, population studies of patients with chronic hepatitis C have shown a convincing increase in cardiovascular and cerebrovascular disease, renal disease, and mental health and cognitive disorders. The most feared complication of acute viral hepatitis is fulminant hepatitis (massive hepatic necrosis); fortunately, this is a rare event. Fulminant hepatitis is seen primarily in hepatitis B, D, and E, but rare fulminant cases of hepatitis A occur primarily in older adults and in persons with underlying chronic liver disease, including, according to some reports, chronic hepatitis B and C. Hepatitis B accounts for
50% of fulminant cases of viral hepatitis, a sizable proportion of which are associated with HDV infection and another proportion with underlying chronic hepatitis C. Fulminant hepatitis is hardly ever seen in hepatitis C, but hepatitis E, as noted above, can be complicated by fatal fulminant hepatitis in 1–2% of all cases and in up to 20% of cases in pregnant women. Patients usually present with signs and symptoms of encephalopathy that may evolve to deep coma. The liver is usually small and the PT excessively prolonged. The combination of rapidly shrinking liver size, rapidly rising bilirubin level, and marked prolon gation of the PT, even as aminotransferase levels fall, together with clinical signs of confusion, disorientation, somnolence, ascites, and edema, indicates that the patient has hepatic failure with encephalopa thy. Cerebral edema is common; brainstem compression, gastrointes tinal bleeding, sepsis, respiratory failure, cardiovascular collapse, and renal failure are terminal events. The mortality rate can be exceedingly high (>80% in patients with deep coma) without liver transplantation, but patients who survive may have a complete biochemical and histo logic recovery (Chap. 356). Documenting the disappearance of HBsAg after apparent clinical recovery from acute hepatitis B is particularly important. Before laboratory methods were available to distinguish between acute hepatitis and acute hepatitis–like exacerbations (spon taneous reactivations) of chronic hepatitis B, observations suggested that ~10% of previously healthy patients remained HBsAg positive for 6 months after the onset of clinically apparent acute hepatitis B. Onehalf of these persons cleared the antigen from their circulations during the next several years, but the other 5% remained chronically HBsAg positive. More recent observations suggest that the true rate of chronic infection after clinically apparent acute hepatitis B is as low as 1% in normal, immunocompetent, young adults. Earlier, higher estimates may have been confounded by inadvertent inclusion of acute exacerba tions in chronically infected patients; these patients, chronically HBsAg positive before exacerbation, were unlikely to seroconvert to HBsAg negative thereafter. Whether the rate of chronicity is 10% or 1%, such patients have IgG anti-HBc in serum; anti-HBs is either undetected or detected at low titer against the opposite subtype specificity of the antigen (see “Laboratory Features”). These patients may (1) be inactive carriers; (2) have low-grade, mild chronic hepatitis; or (3) have moder ate to severe chronic hepatitis with or without cirrhosis. The likelihood of remaining chronically infected after acute HBV infection is espe cially high among neonates, persons with Down syndrome, chronically CHAPTER 350 Acute Viral Hepatitis
hemodialyzed patients, and immunosuppressed patients, including persons with HIV infection.
Chronic hepatitis is an important late complication of acute hepatitis B
occurring in a small proportion of patients with acute disease but more common in those who present with chronic infection without having experienced an acute illness, as occurs typically after neonatal infec tion or after infection in an immunosuppressed host (Chap. 352). The following clinical and laboratory features suggest progression of acute hepatitis to chronic hepatitis: (1) lack of complete resolution of clini cal symptoms of anorexia, weight loss, fatigue, and the persistence of hepatomegaly; (2) the presence of bridging/interface or multilobular hepatic necrosis on liver biopsy during protracted, severe acute viral hepatitis; (3) failure of the serum aminotransferase, bilirubin, and globulin levels to return to normal within 6–12 months after the acute illness; and (4) the persistence of HBeAg for >3 months or HBsAg for
6 months after acute hepatitis. Although acute hepatitis D infection does not increase the likeli hood of chronicity of simultaneous acute hepatitis B, hepatitis D has the potential for contributing to the severity of chronic hepatitis B. Hepatitis D superinfection can transform inactive or mild chronic hepatitis B into severe, progressive chronic hepatitis and cirrhosis; it also can accelerate the course of chronic hepatitis B and acceler ate the risk of hepatocellular carcinoma. Some HDV superinfections in patients with chronic hepatitis B lead to fulminant hepatitis. As defined in longitudinal studies over three decades, the annual rate of cirrhosis in patients with chronic hepatitis D is 4%. Although HDV and HBV infections are associated with severe liver disease, mild hepatitis and even inactive carriage have been identified in some patients, and the disease may become indolent beyond the early years of infection. PART 10 Disorders of the Gastrointestinal System After acute HCV infection, the likelihood of remaining chronically infected approaches 85–90%. Although many patients with chronic hepatitis C have no symptoms, cirrhosis may develop in as many as 20% within 10–20 years of acute illness; in prior series of cases reported by referral centers, cirrhosis has been reported in as many as 50% of patients with chronic hepatitis C. Among cirrhotic patients with chronic hepatitis C, the annual risk of hepatic decompensation is ~4%; the annual risk of hepatocellular carcinoma in cirrhotic patients with chronic hepatitis C has been reported in a range between 1 and 4% and, in a recent definitive report, was 3.36%. With the advent of highly effective DAA therapy during the second decade of the 21st century, a decline in HCV-related cirrhosis and hepatocellular carcinoma has been observed. Progression of chronic hepatitis C may be influenced by advanced age of acquisition, long duration of infection, immuno suppression, coexisting excessive alcohol use, concomitant hepatic steatosis, other hepatitis virus infection, or HIV co-infection. In fact, instances of severe and rapidly progressive chronic hepatitis B and C are recognized with increasing frequency in patients with HIV infec tion (Chap. 208). In contrast, neither HAV nor HEV causes chronic liver disease in immunocompetent hosts; however, cases of chronic hepatitis E (including cirrhosis and end-stage liver disease and even hepatocellular carcinoma) have been observed in immunosuppressed organ-transplant recipients, persons receiving cytotoxic chemotherapy, and persons with HIV infection. Among patients with chronic hepatitis (e.g., caused by hepatitis B or C, alcohol, etc.) in endemic countries, hepatitis E has been reported as the cause of acute-on-chronic liver fail ure; however, in most experiences among patients from nonendemic countries, HEV has not been found to contribute commonly to hepatic decompensation in patients with chronic hepatitis. Persons with chronic hepatitis B, particularly those infected in infancy or early childhood and especially those with HBeAg and/or high-level HBV DNA, have an enhanced risk of hepatocellular car cinoma. The risks of cirrhosis and hepatocellular carcinoma increase with the level of HBV replication. The annual rate of hepatocellular carcinoma in patients with chronic hepatitis D and cirrhosis is ~3%. Rare complications of acute viral hepatitis include pancreati tis, myocarditis, atypical pneumonia, aplastic anemia, transverse myelitis, peripheral neuropathy, and Guillain-Barré syndrome. In children, hepatitis B may present rarely with anicteric hepatitis,
a nonpruritic papular rash of the face, buttocks, and limbs, and lymphadenopathy (papular acrodermatitis of childhood or GianottiCrosti syndrome). Rarely, autoimmune hepatitis (Chap. 352) can be triggered by a bout of otherwise self-limited acute hepatitis, as reported after acute hepatitis A, B, and C. ■ ■DIFFERENTIAL DIAGNOSIS Viral diseases such as infectious mononucleosis (EBV); those due to cytomegalovirus, herpes simplex virus, adenovirus, and cox sackieviruses; and toxoplasmosis may share certain clinical features with viral hepatitis and cause elevations in serum aminotransferase and, less commonly, in serum bilirubin levels. Tests such as the differential heterophile and serologic tests for these agents may be helpful in the differential diagnosis if HBsAg, anti-HBc, IgM antiHAV, and anti-HCV (and anti-HEV) determinations are negative. Aminotransferase elevations can accompany almost any systemic viral infection, including the coronavirus SARS-CoV-2 (~10% of all cases and up to half of severe cases); other rare causes of liver injury confused with viral hepatitis are infections with Leptospira, Candida, Brucella, Mycobacteria, and Pneumocystis. A complete drug history is particularly important, because many drugs and certain anesthetic agents can produce a picture of either acute hepatitis or cholestasis (Chap. 351). Equally important is a history of unexplained “repeated episodes” of acute hepatitis. This history should alert the physician to the possibility that the underlying disorder is chronic hepatitis, for example, autoimmune hepatitis (Chap. 352). Alcohol-associated hepatitis (AH), which can cause an acute icteric hepatitis, must also be considered, but usually the serum aminotransferase levels are not as markedly elevated (generally not much above 200 IU/ mL, almost always below 400 IU/mL) in AH, and a heavy drink ing history must be present (at least 40 g/d in women and 60 g/d in men for at least 6 months). The finding on liver biopsy of fatty infiltration, a neutrophilic inflammatory reaction, and “alcoholic hyaline” would be consistent with alcohol-induced rather than viral liver injury. Because acute hepatitis may present with right upper quadrant abdominal pain, nausea and vomiting, fever, and icterus, it is often confused with acute cholecystitis, common duct stone, or ascending cholangitis. Patients with acute viral hepatitis may tolerate surgery poorly, and surgical risk is particularly high in the elderly and those with underlying chronic liver disease; therefore, excluding biliary disease clinically and with imaging is important. In confusing cases, a percutaneous liver biopsy may be helpful. Viral hepatitis in the elderly is often misdiagnosed as obstructive jaundice resulting from a common duct stone or carcinoma of the pancreas. Another clinical constellation that may mimic acute hepatitis is right ventricular failure with passive hepatic congestion or hypoperfusion syndromes, such as those associated with shock, severe hypoten sion, and severe left ventricular failure. Also included in this general category is any disorder that interferes with venous return to the heart, such as right atrial myxoma, constrictive pericarditis, hepatic vein occlusion (Budd-Chiari syndrome), or venoocclusive disease. Clinical features are usually sufficient to distinguish among these vascular disorders and viral hepatitis. Acute fatty liver of pregnancy, cholestasis of pregnancy, eclampsia, and the HELLP (hemolysis, elevated liver tests, and low platelets) syndrome can be confused with viral hepatitis during pregnancy. Very rarely, malignancies meta static to the liver can mimic acute or even fulminant viral hepatitis.
Occasionally, genetic or metabolic liver disorders (e.g., Wilson’s dis ease, α1 antitrypsin deficiency) and nonalcoholic fatty liver disease (NAFLD; now labeled metabolic dysfunction–associated steatotic liver disease [MASLD]; what used to be called nonalcoholic steato hepatitis [NASH] is now labeled metabolic dysfunction–associated steatohepatitis [MASH]) are confused with acute viral hepatitis (Chap. 354). Among patients with biochemical evidence for severe liver injury, i.e., aminotransferase levels of ≥1000 IU/L, the most common causes are ischemic liver injury, drug-induced liver injury (especially caused by acetaminophen), acute viral hepatitis, and pan creaticobiliary disorders.
TREATMENT Acute Viral Hepatitis Most persons with acute hepatitis (especially hepatitis A, B, and E) recover spontaneously and do not require specific antiviral therapy. In hepatitis B, among previously healthy adults who present with clinically apparent acute hepatitis, recovery occurs in ~99%; there fore, antiviral therapy is not likely to improve the rate of recovery and is not required. In rare instances of severe acute hepatitis B, treatment with a nucleoside analogue at oral doses used to treat chronic hepatitis B (Chap. 352) is included in treatment guide lines by the American Association for the Study of Liver Diseases (AASLD) and the European Association for the Study of the Liver (EASL). Indications include fulminant liver failure (along with such therapy, referral to a liver transplantation center is advised) and a prolonged course (>4 weeks) of acute hepatitis B. Although clinical trials have not been done to establish the efficacy or duration of this approach, most authorities would recommend institution of antivi ral therapy with a nucleoside analogue (entecavir or tenofovir, the most potent and least resistance-prone agents) for severe, but not mild-moderate, acute hepatitis B. Treatment should continue until 3 months after HBsAg seroconversion or 6 months after HBeAg seroconversion. In typical cases of acute hepatitis C, recovery is rare (~15–20% in most experiences), and progression to chronic hepatitis is the rule. Patients with jaundice, those with HCV genotype 1, women, and those with earlier age of infection, lower level of HCV RNA, and HBV co-infection, are more likely to recover from acute hepatitis C, as are persons who have genetic markers associated with spontane ous recovery (favorable IL28B CC haplotype). Because spontaneous recovery can occur and because most cases of acute hepatitis C are not clinically severe or rapidly progres sive, during the era of interferon-based therapy, delaying antiviral therapy of acute hepatitis C for 3–6 months was recommended; however, in the current era of highly effective (95–100%) oral DAA therapy, waiting for potential spontaneous recovery is no longer advised. Instead, early treatment with a standard, full 8- to 12-week course of one of the first-line drug combinations approved for treatment of chronic hepatitis C (Chap. 352) is recommended for treatment of patients with acute hepatitis C. Because of the vast reservoir of acute HCV infections acquired four to five decades ago in the 1945–1965 birth cohort, most newly recognized HCV infections are chronic. Opportunities to identify and treat patients with acute hepatitis C occur in two population subsets: (1) in health care workers who sustain hepatitis C–contam inated needle sticks (occupational accidents), monitoring for ALT elevations and the presence of HCV RNA identify acute hepatitis C in ~3%, and this group should be treated; (2) in persons who use injection drugs, the risk of acute hepatitis C has been on the rise during the previous two decades, and the epidemic of opioid use has contributed to an amplification of HCV infection among drug users. Such persons are candidates for antiviral therapy, and efforts to combine antiviral therapy with drug rehabilitation therapy have been very successful. Notwithstanding these specific therapeutic considerations, in most cases of typical acute viral hepatitis, specific treatment gen erally is not necessary. Although hospitalization may be required for clinically severe illness, most patients do not require hospi tal care. Forced and prolonged bed rest is not essential for full recovery, but many patients will feel better with restricted physi cal activity. A high-calorie diet is desirable, and because many patients may experience nausea late in the day, the major caloric intake is best tolerated in the morning. Intravenous feeding is nec essary in the acute stage if the patient has persistent vomiting and cannot maintain oral intake. Drugs capable of producing adverse reactions such as cholestasis and drugs metabolized by the liver should be avoided. If severe pruritus is present, the use of the bile salt–sequestering resin cholestyramine is helpful. Glucocorticoid
therapy has no value in acute viral hepatitis, even in severe cases, and may be deleterious, even increasing the risk of chronicity (e.g., of acute hepatitis B).
Physical isolation of patients with hepatitis to a single room and bathroom is rarely necessary except in the case of fecal inconti nence for hepatitis A and E or uncontrolled, voluminous bleeding for hepatitis B (with or without concomitant hepatitis D) and C. Because most patients hospitalized with hepatitis A excrete little, if any, HAV, the likelihood of HAV transmission from these patients during their hospitalization is low. Therefore, burdensome enteric precautions are no longer recommended. Although gloves should be worn when the bed pans or fecal material of patients with hepati tis A are handled, these precautions do not represent a departure from sensible procedure and contemporary universal precautions for all hospitalized patients. For patients with hepatitis B and C, emphasis should be placed on blood precautions (i.e., avoiding direct, ungloved hand contact with blood and other body fluids). Enteric precautions are unnecessary. The importance of simple hygienic precautions such as hand washing cannot be overempha sized. Universal precautions that have been adopted for all patients apply to patients with viral hepatitis. Hospitalized patients may be discharged following substantial symptomatic improvement, a significant downward trend in the serum aminotransferase and bilirubin values, and a return to normal of the PT. Mild aminotrans ferase elevations should not be considered contraindications to the gradual resumption of normal activity. CHAPTER 350 In fulminant hepatitis, the goal of therapy is to support the patient by maintenance of fluid balance, nutrition, support of circulation and respiration, control of bleeding, correction of hypoglycemia, early identification and treatment of infection, and treatment of other com plications of the comatose state in anticipation of liver regeneration and repair. Glucocorticoid therapy has been shown in controlled trials to be ineffective. Likewise, exchange transfusion, plasmapheresis, human cross-circulation, porcine liver cross-perfusion, hemoperfusion, and extracorporeal liver-assist devices have not been proven to enhance survival. The cornerstone of management is meticulous intensive care with vigilant monitoring for infection (and low threshold for initiation of antibiotics and antifungals), careful mental status/cerebral edema monitoring, and management of bleeding complications. Liver transplantation is resorted to with increasing frequency, with excellent results, in patients with fulminant hepatitis (Chap. 356). Fulminant hepatitis C is very rare; however, in fulminant hepatitis B, oral antiviral therapy has been used successfully, although the benefit may be limited once late-stage acute liver failure is present. In clinically severe acute hepatitis E or acute-on-chronic liver failure, successful therapy with ribavirin (600 mg twice daily, 15 mg/kg) has been reported; however, the precise dose and duration of therapy have not been established, and conflicting reports have appeared documenting the futility of ribavirin in this setting. Unfortunately, when fulminant hepatitis E occurs in pregnant women (as it does in up to 20% of pregnant women with acute hepatitis E), ribavirin, which is teratogenic, is contraindicated. In cases of hepatitis E in organ-transplant recipients, reduction in overall immunosuppressive drug doses and switching from tacrolimus to cyclosporine A have been shown to be effective, often without antiviral therapy, in achieving eradication of HEV. If a change in immunosup pression is inadequate, ribavirin treatment for 3 months has been observed to achieve a sustained virologic response in 78% of treated patients; again however, the optimal dose, duration, and efficacy of ribavirin therapy remain to be determined. Acute Viral Hepatitis ■ ■PROPHYLAXIS Because application of therapy for acute viral hepatitis is limited and because chronic viral hepatitis requires prolonged and costly courses of antiviral therapy (Chap. 352), emphasis is placed on preven tion through immunization. The prophylactic approach differs for each of the types of viral hepatitis. In the past, immunoprophylaxis
relied exclusively on passive immunization with antibody-containing globulin preparations purified by cold ethanol fractionation from the plasma of hundreds of normal donors. Currently, for hepatitis A, B, and E, active immunization with vaccines is the preferable approach to prevention.
Hepatitis A Both passive immunization with immunoglobulin (IG) and active immunization with killed vaccines are available. Pas sive immunization, which can be considered in the setting of recent exposure, is 80–90% effective at preventing infection and provides 12–20 weeks of protection; however, its utility is limited by availability and cost (and the competing appeal of active immunization with vac cine). For postexposure prophylaxis of intimate contacts (household, sexual, institutional) of persons with hepatitis A, the administration of 0.1 mL/kg is recommended as early after exposure as possible but must be within 14 days. Prophylaxis is not necessary for those who have already received hepatitis A vaccine, for casual contacts (office, factory, school, or hospital), for most elderly persons, who are very likely to be immune, or for those known to have anti-HAV in their serum. By the time most common-source outbreaks of hepatitis A are recognized, it is usually too late in the incubation period for IG to be effective; how ever, prophylaxis may have limited the frequency of secondary cases. For travelers to tropical countries, developing countries, and other areas outside standard tourist routes, IG prophylaxis had been recom mended before a vaccine became available. Recommendations for postexposure prophylaxis and for preexpo sure prophylaxis for international travel were updated in 2020. Cur rently, hepatitis A vaccine, not IG, is recommended for all persons aged ≥12 months for postexposure prophylaxis and for preexposure prophylaxis prior to international travel to HAV-endemic areas. Even though hepatitis A vaccine is indicated for children ≥12 months of age, when infants aged 6–11 months travel internationally to areas with a risk of HAV infection, they should receive the vaccine for preexposure prophylaxis; however, this travel-related dose should not be counted toward the universal childhood two-dose hepatitis A vaccine recommendation, which begins at age 12 months. For post exposure prophylaxis of persons with contraindications to hepatitis A vaccination and infants aged <12 months, the use of IG (0.1 mL/ kg) should be retained. In addition, for postexposure prophylaxis in immunocompromised adults and persons with chronic liver disease, both hepatitis A vaccination and IG administration (0.1 mL/kg), at different IM sites, are recommended. Finally, for infants aged <6 months and for persons with contraindications to hepatitis A vac cination, preexposure prophylaxis for travel consists of IG at doses of 0.1 mg/kg for travel durations up to 1 month, 0.2 mg/kg for travel up to 2 months, and repeat 0.2 mg/kg every 2 months thereafter for the remainder of travel. Thus, except for these limited considerations, hepatitis A vaccine has supplanted IG in almost all cases for both postexposure prophylaxis and preexposure prophylaxis for travel. In general, practical use of IG at this point tends to be confined to outbreaks, in which early containment is critical. Unlike IG prophy laxis, the protection afforded by active immunization with vaccine is durable and simpler to administer. PART 10 Disorders of the Gastrointestinal System Formalin-inactivated vaccines made from strains of HAV attenu ated in tissue culture have been shown to be safe, immunogenic, and effective in preventing hepatitis A. Hepatitis A vaccines are approved for use in persons who are at least 1 year old and appear to provide adequate protection beginning 4 weeks after a primary inoculation. As noted above, for travel to an endemic area, hepatitis A vaccine is the preferred approach to preexposure immunoprophylaxis and provides long-lasting protection (protective levels of anti-HAV should last at least 20 years after vaccination). Shortly after its introduction, hepatitis A vaccine was recommended for children living in communities with a high incidence of HAV infection; in 1999, this recommendation was extended to include all children living in states, counties, and com munities with high rates of HAV infection. As of 2006, the Advisory Committee on Immunization Practices of the U.S. Public Health Ser vice recommended routine hepatitis A vaccination of all children. Other groups considered being at increased risk for HAV infection and who
are candidates for hepatitis A vaccination include military personnel, populations with cyclic outbreaks of hepatitis A (e.g., Alaskan natives), employees of day-care centers and persons working in facilities for the developmentally delayed, primate handlers, laboratory workers exposed to hepatitis A or fecal specimens, and patients with chronic liver disease (including persons with aminotransferase elevations ≥2 times the upper limit of normal). Because of an increased risk of fulminant hepatitis A—observed in some experiences but not con firmed in others—among patients with chronic hepatitis C, patients with chronic hepatitis C are candidates for hepatitis A vaccination, as are persons with chronic hepatitis B, persons with HIV infection, and the expanding population of persons with nonalcoholic liver disease (MASLD). Other populations whose recognized risk of hepatitis A is increased should be vaccinated, including men who have sex with men, persons who use injection or noninjection drugs, persons experienc ing homelessness, persons traveling from the United States to coun tries with high or intermediate hepatitis A endemicity, postexposure prophylaxis for contacts of persons with hepatitis A, and household members and other close contacts of (or anyone who anticipates close personal contact with) adopted children arriving from countries with high and moderate hepatitis A endemicity. Hepatitis A vaccine is now recommended as well for pregnant women at risk of infection or severe outcomes from infection during pregnancy. Recommendations for dose and frequency differ for the two approved vaccine preparations in the United States and the combination vaccines that include hepatitis A (Table 350-7); all injections are IM. Hepatitis A vaccine has been reported to be effective in preventing secondary household and daycare center–associated cases of acute hepatitis A. In the United States, reported mortality resulting from hepatitis A declined in parallel with hepatitis A vaccine–associated reductions in the annual incidence of new infections. Hepatitis B Until 1982, prevention of hepatitis B was based on passive immunoprophylaxis either with standard IG, containing modest levels of anti-HBs, or hepatitis B immunoglobulin (HBIG), containing high-titer anti-HBs. The efficacy of standard IG has never been established and remains questionable; even the efficacy of HBIG, demonstrated in several clinical trials, has been challenged, and its contribution appears to be in reducing the frequency of clinical illness, not in preventing infection. The first vaccine for active immunization, introduced in 1982, was prepared from purified, noninfectious, 22-nm spherical HBsAg particles derived from the plasma of healthy HBsAg carriers. In 1987, the plasma-derived vac cine was supplanted by a genetically engineered vaccine derived from recombinant yeast. The latter vaccine consists of HBsAg particles that are nonglycosylated but are otherwise indistinguishable from natural HBsAg; two recombinant vaccines were licensed for use in the United States in the 1980s (Recombivax-HB 1986; Engerix-B 1989), a third (Heplisav-B) was licensed in 2017, and a fourth recombinant vaccine (PreHevbrio, VBI Vaccines) was licensed in 2022. In the United States, TABLE 350-7 Hepatitis A Vaccination Schedules AGE, YEARS NO. OF DOSES DOSE SCHEDULE, MONTHS HAVRIX (GlaxoSmithKline)a 1–18 ≥19
720 ELUb (0.5 mL) 1440 ELU (1 mL) 0, 6–12 0, 6–12 VAQTA (Merck) 1–18 ≥19
25 units (0.5 mL) 50 units (1 mL) 0, 6–18 0, 6–18 aA combination of this hepatitis A vaccine and hepatitis B vaccine, TWINRIX, is licensed for simultaneous protection against both of these viruses among adults (age ≥18 years). Each 1-mL dose contains 720 ELU of hepatitis A vaccine and 20 μg of hepatitis B vaccine. These doses are recommended at months 0, 1, and 6. bEnzyme-linked immunoassay units. cCombination hepatitis A and typhoid vaccines, Hepatyrix (GlaxoSmithKline) and Viatim (Sanofi Pasteur), are available, targeted primarily for travelers to endemic areas. Please consult product insert for doses and schedules
TABLE 350-8 Preexposure Hepatitis B Vaccinations NAME VACCINE TYPE AGE GROUP NO. OF DOSES SCHEDULE, MONTH NOTES Engerix-B (GlaxoSmithKline) Single antigen recombinant From birth, not on dialysis
0, 1, 6 0.5-mL dose for 0–19 years 1-mL dose for ≥20 years Contraindicated with severe yeast allergy Adults on dialysis
0, 1, 2, 6 2-mL dose for adults Recombivax HB (Merck) Single antigen recombinant From birth, not on dialysis
0, 1, 6 0.5-mL dose for 0–19 years 1-mL dose for ≥20 years Contraindicated with severe yeast allergy Recombivax HBV dialysis formulation (Merck) Single antigen recombinant Adults on dialysis
0, 1, 6 1-mL dose for adults Heplisav-B (Dynavax) Single antigen adjuvanted recombinant ≥18 years
0, 1 0.5-mL dose Higher levels of protective antibodies, particularly in adults ≥40 years Not for use in severe yeast allergy PreHevbrio (VBI)* Three antigen recombinant ≥18 years
0, 1, 6 1-mL dose Higher rates of seroprotection in adults ≥45 years Not for use in pregnant women Twinrix (GlaxoSmithKline) Combined single antigen recombinant hepatitis A and hepatitis B ≥18 years
0, 1, 6 Note: accelerated 4-dose regimen, days 0, 7, and 21–30, 12 months *In November 2024, distribution of this vaccine in the United States was discontinued by the manufacturer, because of bankruptcy and termination of operations. universal birth vaccination against HBV infection has been the standard of care since 2002, with more recent recommendations suggesting fur ther that the birth dose be administered within 12 hours of delivery. For unvaccinated persons, current recommendations can be divided into those for preexposure and postexposure prophylaxis. For preexposure prophylaxis against hepatitis B in persons with a high risk of exposure, three IM (deltoid, not gluteal) injections of hepa titis B vaccine are recommended at 0, 1, and 6 months (other, optional schedules are summarized in Table 350-8). In 2022, the Advisory Com mittee on Immunization Practices (ACIP) recommended universal vaccination for all unvaccinated persons aged 19–59 years. Among persons 60 years and older, vaccination is recommended for those at high risk as well as any interested person. Groups considered at high risk include (1) those with sexual exposure (sex workers, those with HBsAg partners, patients at sexually transmitted disease clinics), (2) those with frequent blood exposure (health care workers, first respond ers, persons who use injection drugs, hemophiliacs, dialysis patients, persons with end-stage renal disease), (3) those who frequently travel to, or first-generation immigrants from, moderate- to high-endemicity areas (>2% prevalence of HBV infection), (4) those with chronic liver disease (HCV infection, steatotic liver disease, autoimmune hepatitis, alcohol-associated liver disease, or aminotransferases >2 times the upper limit of normal), and (5) several other groups (e.g., incarcerated persons and those with HIV infection and diabetes mellitus). Pregnancy is not a contraindication to vaccination details of the use of Heplisav-B, a two-injection course a month apart, appear in Table 350-8. In areas of low HBV endemicity such as the United States, despite the availability of safe and effective hepatitis B vaccines, a strategy of vaccinating persons in high-risk groups was not effective. The incidence of new hepatitis B cases continued to increase in the United States after the introduction of vaccines; <10% of all targeted persons in high-risk groups were actually vaccinated, and ~30% of persons with sporadic acute hepatitis B did not fall into any high-risk group category. Therefore, to have an impact on the frequency of HBV infection in an area of low endemicity such as the United States, universal hepatitis B vaccination is now recommended. In HBV-hyperendemic areas (e.g., Asia), universal vaccination of children has resulted in a marked (~70–90%) 40-year decline in complications of hepatitis B, including liver-related mortality and hepatocellular carcinoma.
1-mL dose Severe allergy to yeast or any hepatitis A vaccine CHAPTER 350 The original two available aluminum-adjuvanted recombinant hepatitis B vaccines are comparable, one containing 10 μg of HBsAg (Recombivax-HB) and the other containing 20 μg of HBsAg (Engerix-B), and recommended doses for each injection vary for the two prepara tions (Table 350-8). Combinations of hepatitis B vaccine with other childhood vaccines are available as well (Table 350-8). Acute Viral Hepatitis More recently, two new recombinant hepatitis B vaccines have been approved for use. One is a recombinant vaccine with a novel adjuvant that activates toll-like 9 receptors (Heplisav-B) and is approved for adults aged 18 or older (although it should be avoided in pregnancy). In a series of prospective trials, compared to three Engerix-B injec tions, two IM doses a month apart yielded higher proportions with protective levels of anti-HBs (≥10 mIU/mL): 95% of adults aged 18–55 or 18–70 (vs 81% for Engerix-B), 90% of older adults aged 40–70 (vs 71% for Engerix-B), and 90% of adults aged 18–70 with type 2 diabetes (vs 65% for Engerix-B). This two-injection regimen may be useful for revaccination of persons who failed to respond to the original vaccines. The second novel recombinant vaccine (PreHevbrio, VBI Vaccines), which contains all three hepatitis B surface antigen proteins, S, pre-S1, and pre-S2, has been shown in clinical trials (three IM doses at 0, 1, and 6 months) to achieve higher proportions with protective anti-HBs and higher antibody levels than Engerix-B (which contains S antigen only). In addition, PreHevbrio was shown in clinical trials to be associated with higher rates of seroprotection, e.g., in persons ≥45 years (89% compared to 73.1% with an old standard vaccine). This vaccine was approved by the FDA on December 1, 2021, for adults age ≥18 years and recommended for use by the ACIP of the CDC in March 2022. It is the only vaccine not contraindicated in the presence of a yeast allergy.* For unvaccinated persons sustaining an exposure to HBV, postex posure prophylaxis with a combination of HBIG (for rapid achieve ment of high-titer circulating anti-HBs) and hepatitis B vaccine (for achievement of long-lasting immunity as well as its apparent efficacy in attenuating clinical illness after exposure) is recom mended. For perinatal exposure of infants born to HBsAg-positive *In November 2024, distribution of this vaccine in the United States was discontinued by the manufacturer, because of bankruptcy and termination of operations.
mothers, a single dose of HBIG, 0.5 mL, should be administered IM in the thigh immediately after birth, followed by a complete course of three injections of recombinant hepatitis B vaccines approved for children (see doses above) to be started within the first 12 h of life. For those experiencing a direct percutaneous inoculation or transmucosal exposure to HBsAg-positive blood or body fluids (e.g., accidental needle stick, other mucosal penetration, or ingestion), a single IM dose of HBIG, 0.06 mL/kg, administered as soon after exposure as possible, is followed by a complete course of hepatitis B vaccine to begin within the first week. For pregnant mothers with high-level HBV DNA (>2 × 105 IU/mL), adding antiviral nucleoside analogues (e.g., pregnancy class B tenofovir, see Chap. 352) during the third trimester of pregnancy reduces perinatal transmission even further. For persons exposed by sexual contact to a patient with acute hepatitis B, a single IM dose of HBIG, 0.06 mL/kg,
should be given within 14 days of exposure, to be followed by a com plete course of hepatitis B vaccine. When both HBIG and hepatitis B vaccine are recommended, they may be given at the same time but at separate sites. Testing adults for anti-HBs after a course of vaccine is advisable to document the acquisition of immunity (and can guide management in nonresponders, e.g., whether HBIG and/or repeat vaccination with a more immunogenic vaccine preparation is war ranted), but because hepatitis B vaccine immunogenicity is nearly universal in infants, postvaccination anti-HBs testing of children is not recommended. Similarly, testing for the presence of anti-HBs in exposed adults can help guide management (e.g., HBIG, repeat vaccination).
The precise duration of protection afforded by hepatitis B vaccine is unknown; however, ~80–90% of immunocompetent adult vaccinees retain protective levels of anti-HBs for at least 5 years, and 60–80% for 10 years, and protective antibody has been documented to last for at least two decades after vaccination in infancy. Thereafter and even after anti-HBs becomes undetectable, long-term protection (via an anam nestic immune response) persists against clinical hepatitis B, hepatitis B surface antigenemia, and chronic HBV infection. Currently, booster immunizations are not recommended routinely, except in immunosup pressed persons who have lost detectable anti-HBs or immunocompe tent persons who sustain percutaneous HBsAg-positive inoculations after losing detectable antibody. Specifically, for hemodialysis patients, annual anti-HBs testing is recommended after vaccination; booster doses are recommended when anti-HBs levels fall to <10 mIU/mL. As noted above, for persons at risk of both hepatitis A and B, a combined vaccine is available containing 720 enzyme-linked immunoassay units (ELUs) of inactivated HAV and 20 μg of recombinant HBsAg (at 0, 1, and 6 months). PART 10 Disorders of the Gastrointestinal System Hepatitis D Infection with hepatitis D can be prevented by vac cinating susceptible persons with hepatitis B vaccine. No product is available for immunoprophylaxis to prevent HDV superinfection in persons with chronic HBV infection; for these patients, avoidance of percutaneous exposures and limitation of intimate contact with per sons who have HDV infection are recommended. Hepatitis E For prevention of hepatitis E, IG derived from HEVendemic populations does not appear to be effective. Two safe and effective three-dose (0, 1, and 6 months), recombinant genotype 1 capsid protein vaccines have been shown in randomized, placebocontrolled trials to be highly protective (including against other genotypes) against symptomatic acute hepatitis E. A Chinese vaccine, Hecolin, achieved 100% 12-month efficacy and was licensed in China in 2011; its long-lasting protection (87% efficacy) was documented for up to 4.5 years. A second vaccine developed by GlaxoSmithKline and the U.S. Army achieved a 12-month 96% efficacy. The second vaccine was never developed commercially. The Chinese vaccine is available in China but is not FDA approved or available in the United States. Hepatitis C IG is ineffective in preventing hepatitis C and is no longer recommended for postexposure prophylaxis in cases of perinatal, needle stick, or sexual exposure. Although prototype
vaccines that induce antibodies to HCV envelope proteins have been developed, currently, hepatitis C vaccination is not feasible practi cally. Genotype and quasispecies viral heterogeneity, as well as rapid evasion of neutralizing antibodies by this rapidly mutating virus, conspire to render HCV a difficult target for immunoprophylaxis with a vaccine. Prevention of transfusion-associated hepatitis C has been accomplished successfully by implementation of highly sensitive virologic screening tests, and the current estimated risk is less than 1 in 10 million. In the absence of active or passive immunization, prevention of hepatitis C includes behavior changes and precautions to limit expo sures to infected persons. Recommendations designed to identify patients with clinically inapparent hepatitis as candidates for medical management have as a secondary benefit the identification of persons whose contacts could be at risk of becoming infected. A so-called look-back program has been recommended to identify persons who were transfused before 1992 with blood from a donor found sub sequently to have hepatitis C. In addition, anti-HCV testing, once recommended for persons born between 1945 and 1965, has now been expanded to include all persons 18 years or older, indepen dent of risk factors. For stable, monogamous sexual partners, sexual transmission of hepatitis C is unlikely, and sexual barrier precautions are not recommended. For persons with multiple sexual partners or with sexually transmitted diseases, the risk of sexual transmission of hepatitis C is increased, and barrier precautions (latex condoms) are recommended. A person with hepatitis C should avoid sharing such items as razors, toothbrushes, and nail clippers with sexual partners and family members. No special precautions are recommended for babies born to mothers with hepatitis C, and breast-feeding does not have to be restricted. A more recent, ambitious goal toward HCV prevention steers focus toward its global eradication by 2030, which would require higher rates of and investment in global surveillance, immediate reflex treat ment in persons who test positive for HCV infection, and undelayed, streamlined initiation of treatment (including, and perhaps most importantly, in people who inject drugs to prevent secondary spread) (Table 350-4). ■ ■FURTHER READING Asselah T, Rizzetto M: Hepatitis D virus infection. N Engl J Med 389:58, 2023. Conners EE, et al: Screening and testing for hepatitis B virus infection: CDC recommendations—United States, 2023. MMWR Morb Mortal Wkly Rep 72:1, 2023. Doshani M et al: Recommendations of the Advisory Committee on Immunization Practices for use of hepatitis A vaccine for persons experiencing homelessness. MMWR Morb Mortal Wkly Rep 68:153, 2019. European Association for the Study of the Liver: EASL clinical practice guidelines on hepatitis E virus infection. J Hepatol 68:1256, 2018. Freedman M et al: Advisory Committee on Immunization Practices. Recommended adult immunization schedule, United States, 2020. Ann Intern Med 172:337, 2020. Goldberg D et al: Changes in the prevalence of hepatitis C virus infection, nonalcoholic steatohepatitis, and alcoholic liver disease among patients with cirrhosis and liver failure on the waitlist for liver transplantation. Gastroenterology 152:1090, 2017. Hofmeister MG et al: Estimating prevalence of hepatitis C virus infection in the United States, 2013-2016. Hepatology 69:1020,
Jeng W-J et al: Hepatitis B. Lancet 401:1039, 2023. Kelgeri C et al: Clinical spectrum of children with acute hepatitis of unknown cause. N Engl J Med 387:611, 2022. Koh C et al: Pathogenesis of and new therapies for hepatitis D. Gastro enterology 156:461, 2019. Le MH et al: Chronic hepatitis B prevalence among foreign-born and U.S.-born adults in the United States, 1999-2016. Hepatology 71:431, 2020.
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