Abstract
A major problem in patients with hepatitis C virus (HCV) infections is progression from acute to persistent infection, resulting in development of serious liver diseases including hepatocellular carcinoma. However, HCV infection is a multifaceted disease. Extrahepatic manifestations include cryoglobulinemia, glomerulonephritis, porphyria cutanea tarda, Sjögren’s syndrome, and lymphoma, most of which are evoked by the virus or the interaction thereof with the host immune system. Recently, partly extrahepatic features of HCV infection, including disturbance of lipid metabolism and insulin resistance, have been described. Such metabolic disturbances provoked by HCV are now considered to be essential features of the pathogenesis of liver disease induced by HCV infection. Some of these diseases/syndromes are cured by antiviral treatment. In the present review, the systemic manifestations of HCV infection will be examined and their clinical relevance discussed.
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Keywords
- Hepatitis C virus
- Extrahepatic manifestation
- Metabolic disease
- Sjögren’s syndrome
- All-cause mortality
- Hepatocellular carcinoma
1 Introduction
Worldwide, approximately 170 million people are persistently infected with hepatitis C virus (HCV), which induces a spectrum of chronic liver diseases, ranging from chronic hepatitis, through cirrhosis, and, eventually, to hepatocellular carcinoma (HCC) (Saito et al. 1990). HCV has received increasing attention because of widespread viral dissemination across broad communities, linked to very high incidences of HCC in those with persistent infections. Once liver cirrhosis is diagnosed in patients persistently infected with HCV, the annual risk of HCC is approximately 7 % (Ikeda et al. 1998), resulting in development of HCC in almost 90 % of HCV-associated cirrhotic patients by 15 years later. It was recognized relatively soon after the discovery of HCV that infection with the virus involves not only the liver but also other organs and tissues. Several extrahepatic manifestations, which are complicated disorders of organs other than the liver, occur in association with HCV infection (Gumber et al. 1995). In addition, disease manifestations that are extrahepatic in part, including disturbances in lipid and glucose metabolism, add to the multifaceted nature of HCV infection (Koike and Moriya 2005). Of the latter conditions, most are definitely associated with HCV infection in both clinical and basic terms, but the links between some others await verification via conduct of more case studies and/or pathogenetic analyses (Table 1).
2 Manifestations Associated with HCV Infection
2.1 Cryoglobulinemia
In many patients infected with HCV, cryoglobulinemia is subclinical, thus not symptomatic, but the incidence of the extrahepatic complication, essential mixed cryoglobulinemia (EMC), is highest in HCV-infected patients. The clinical symptoms of EMC include purpura, arthralgia, and renal impairments (Mayo 2002). The latter include membranoproliferative glomerulonephritis (MPGN), which occasionally progresses to renal insufficiency (Johnson et al. 1993). Approximately 80–90 % of EMC patients are infected with HCV (Agnello et al. 1992; Saadoun et al. 2006). Cryoglobulins were detected, using a highly sensitive gel diffusion method, in 70 % of patients chronically infected with HCV (Okuse et al. 2003).
Cryoglobulins are abnormal immunoglobulins that form white deposits at 4 °C but are liquids at 37 °C. Cryoglobulins are classified into three types, namely, monoclonal cryoglobulins (type I), polyclonal cryoglobulins (type III), and mixed cryoglobulins (type II). The cryoglobulinemia associated with HCV infection is mainly of the mixed type. Specifically, such patients produce monoclonal IgM and polyclonal IgG antibodies exhibiting rheumatoid factor activity (Brouet et al. 1974; Wong et al. 1996).
The pathogenesis of cryoglobulinemia in HCV-infected patients remains poorly elucidated. However, persistent stimulation of lymphocytes induces B-cell clonal expansion, leading to the production of antibodies including rheumatoid factor, which become incorporated into cryoglobulins (Saadoun et al. 2007). Intrahepatic growth of CD5- and CD81-positive B lymphocytes has been observed, suggesting that induction of monoclonal IgM synthesis may be the cause of the disease (Curry et al. 2003). Tissue damage in patients with EMC-induced vasculitis would thus be T-cell mediated.
Antiviral agents including interferon (IFN) have been used to treat HCV-associated cryoglobulinemia (Lunel et al. 1994). Cryoglobulinemia symptoms improved in 15 of 25 patients with HCV-associated disease after IFN treatment commenced, but the symptoms recurred when treatment concluded (Misiani et al. 1994). A combination of (PEG)-IFN and ribavirin has also been used to treat HCV-associated cryoglobulinemia. Administration of both drugs to nine EMC patients who had not responded to IFN monotherapy alleviated cryoglobulinemia in all nine, and improved clinical symptoms in seven of the nine (Zuckerman et al. 2000). Recently developed direct-acting antivirals (DAAs) for HCV are also effective, as these agents exhibit strong antiviral activities (Saadoun et al. 2014).
In addition, in patients with severe cryoglobulinemia, in whom antiviral agents may not adequately improve symptoms, combination therapy with IFN and steroids or immunosuppressants has been considered effective (Cacoub et al. 2002). Other treatment strategies, including plasma exchange therapy and splenectomy (Ubara et al. 2000), have also been attempted. Recently, rituximab was reported to improve vasculitis, including skin lesions, arthralgia, neuropathy, and glomerulonephritis (Cacoub et al. 2008).
2.2 Renal Impairments and Glomerulonephritis
Renal impairments associated with HCV infection include membranoproliferative glomerulonephritis (MPGN), membranous nephropathy, mesangial proliferative glomerulonephritis, Henoch-Schönlein purpura nephritis, and tubulointerstitial nephritis (Kasuno et al. 2003).
MPGN, in particular, is considered to be a typical example of the renal impairment associated with hepatic disease caused by HCV, and is also termed HCV-associated nephritis. In 1993, eight patients with HCV infections complicated by MPGN were reported, for the first time (Johnson et al. 1993). The incidence of HCV-associated nephritis has not yet been determined. In an autopsy study on 188 cases of chronic hepatitis C, 11.2 % exhibited MPGN, 2.7 % membranous nephropathy, and 17.6 % mesangial proliferative glomerulonephritis (Arase et al. 1998). The pathogenesis underlying HCV-associated nephritis is considered to be accumulation of an immune complex, formed by monoclonal or polyclonal IgM-κ, exhibiting rheumatoid factor activity. The antibody is produced by HCV-infected peripheral B lymphocytes, and is deposited in the glomerular vascular endothelium and mesangium (D’Amico and Fornasieri 1995).
The histopathological features of HCV-associated nephritis are similar to those of general MPGN of type I, but the former disease is occasionally associated with cryoglobulin deposition (Sinico et al. 2000). If EMC and nephrotic syndrome patients produce rheumatoid factor, HCV-associated nephritis should be suspected, and the presence/absence of HCV infection determined.
Antiviral therapies, including IFN, are effective when used to treat HCV-associated nephritis (Johnson et al. 1994). Administration of IFN to 14 patients with HCV-associated nephritis improved proteinuria, but relapse occurred after the end of therapy, in association with a relapse of HCV infection. IFN/ribavirin combination therapy, which is associated with a low relapse rate, has also been tested (Misiani et al. 1999). A combination of a steroid and cyclophosphamide has been used as immunosuppressive therapy, but use of an immunosuppressant alone has not yet afforded good results (Dammacco et al. 1994). As patients with HCV-associated nephritis have been reported to have poor prognoses, the recent introduction of DAAs, as HCV treatments, may allow development of therapeutic procedures effective to treat the renal impairment associated with HCV infection. Also, addition of rituximab may be valuable in treatment of patients with HCV-related EMC exhibiting renal involvement (Saadoun et al. 2010).
2.3 Porphyria Cutanea Tarda
Porphyria cutanea tarda (PCT) is an acquired condition; patients exhibit photosensitivity to the sun, and hepatic damage caused by reduced activity of liver uroporphyrinogen decarboxylase (Sarkany 2001). The contributions of all of alcohol, excess iron, and medications to hepatic impairment were previously examined in the context of PCT development. However, as HCV infection is present in 60–100 % of patients with PCT, a linkage between such infection and the pathogenesis of PCT is suspected. The mechanism has not yet been clarified. It is assumed, however, that PCT is caused by a reduction in uroporphyrinogen decarboxylase activity associated with excessive deposition of iron in the liver, in turn triggered by HCV infection (Fargion et al. 1992).
IFN has been shown to be effective for treatment of PCT, in combination with avoidance of exposure to the sun, abstention from alcohol, and phlebotomy. IFN therapy normalized serum ALT levels, caused serum HCV-RNA to disappear, normalized porphyrin and ferritin levels, and improved clinical symptoms—including vesicle formation and hypertrichosis—in PCT patients infected with HCV (Okano et al. 1997).
2.4 Sjögren’s Syndrome
Sjögren’s syndrome is an aggregate of symptoms characterized by insufficient tear production by the lacrimal glands and insufficient saliva production by the salivary glands, caused by infiltration of exocrine lymphocytes, which in turn causes dryness of the eyes and mouth (Fox 2005).
An association of Sjögren’s syndrome with certain viral infections has long been known, and reports indicating that 0–45 % of patients were positive for anti-HCV antibodies suggest that Sjögren’s syndrome and HCV infection may be associated (Nagao et al. 2003). Differences in anti-HCV positivity rates may be attributable to regional differences in HCV infection rates. Also, lymphocytic sialadenitis, which resembles Sjögren’s syndrome, was found in 16 of 28 patients (57 %) with HCV infection, but only 1 of 20 controls (5 %) (Haddad et al. 1992). Pawlotsky et al. reported a 14 % prevalence of pathological abnormalities resembling Sjögren’s syndrome in patients with HCV infections, compared to 0 % in controls without HCV infection. Of interest, the cited authors found that almost 50 % of patients with HCV infection had lymphocytic capillaritis of the salivary glands, which is found in all patients with sialadenitis. Lymphocytic capillaritis could therefore represent an early stage in the development of more severe lesions resembling the lymphocytic sialadenitis of Sjögren’s syndrome (Pawlotsky et al. 1995).
Koike et al. found a direct association between HCV infection and sialadenitis in work with transgenic mice carrying genotype 1b HCV envelope genes, in which sialadenitis resembling Sjögren’s syndrome develops spontaneously. In particular, it was noteworthy that lymphocytic capillaritis preceded sialadenitis in such animals (Koike et al. 1997), which may reflect the pathological sequence of development of Sjögren-like syndrome in humans chronically infected with HCV (Pawlotsky et al. 1995). In a clinical study, HCV-RNA was detected in salivary gland tissues from anti-HCV-positive patients with Sjögren’s syndrome, via reverse transcriptase (RT)-PCR analysis (Takamatsu et al. 1992). Upon in situ hybridization of salivary gland tissue samples from 8 anti-HCV-positive and 11 anti-HCV-negative patients with chronic sialadenitis or Sjögren’s syndrome, HCV-RNA was detected in all salivary gland samples from the anti-HCV-positive patients. Moreover, HCV-infected salivary gland epithelium supported viral multiplication (Arrieta et al. 2001). Such lines of evidence indicate that HCV plays some role in the development of the sialadenitis of Sjögren’s syndrome, but it remains unclear whether HCV per se or an immunological response to HCV infection induces the condition.
No reports on the efficacy of IFN therapy for HCV-associated sialadenitis have yet appeared (Lunel and Cacoub 2000). Artificial lacrimal fluid and artificial saliva are used to alleviate dryness, and a non-steroidal anti-inflammatory drug or corticosteroid is administered to treat the fever and articular symptoms (Fox 2005).
2.5 Diabetes and Insulin Resistance
Allison et al. reported an epidemiological link between diabetes and HCV infection, but only in a cirrhotic cohort (Allison et al. 1994). This initial report made little impact, however, in view of the fact that glucose tolerance is well known to be impaired in patients with advanced chronic liver disease. Several other reports followed, both from the same group and others. The trend toward acceptance of a positive association between diabetes and HCV infection seems to have been triggered by a population-based study performed in the United States (Mehta et al. 2000), which found a solid association between the two conditions. In addition, it has been shown that comorbid diabetes is a risk factor for HCC (Hassan et al. 2002) in cirrhotic patients (Bianchi et al. 1994). These reports support the existence of an association between HCV infection and type 2 diabetes.
Petit et al. reported that insulin resistance was increased in chronic hepatitis C patients with even slight hepatic impairment, and that the index of impairment (HOMA-IR) correlated with the severity of liver fibrosis (Petit et al. 2001). Tumor necrosis factor (TNF)-alpha, the levels of which correlate closely with the extents of hepatic inflammation and fibrosis in chronic hepatitis C patients (Zylberberg et al. 1999), is considered to enhance glucose uptake in peripheral tissue and to promote gluconeogenesis in the liver, leading to induction of insulin resistance (Pradhan and Ridker 2002). However, any association between diabetes and HCV infection is difficult to establish, because cirrhosis, obesity, and old age are common in HCV patients. Hence, experimental systems have been employed. Shintani et al. used transgenic mice carrying the genotype 1b HCV core gene (Moriya et al. 1998), and found that (1) the HCV core protein induced insulin resistance in vivo; (2) tyrosine phosphorylation of the insulin receptor substrate (IRS)-1 in the insulin signal transduction pathway was disrupted; and, (3) the insulin resistance that developed was hepatic in nature, as shown by hyperinsulinemic euglycemic clamp analysis. The mice had high TNF-alpha liver levels, and administration of anti-TNF-alpha antibody improved insulin resistance. These results indicate that a direct link exists between HCV infection and type 2diabetes (Shintani et al. 2004).
At the time of publication of the above findings, Aytug et al. reported on insulin signaling in biopsied liver specimens from patients with chronic hepatitis C (Aytug et al. 2003). Specifically, the cited authors measured changes in IRS-1, IRS-2, and phosphatidylinositol (PI)3-kinase levels. Upon insulin stimulation of the biopsy samples, the levels of insulin-receptor proteins and IRS-1 increased, whereas phosphorylation of the tyrosines in IRS-1 decreased the levels thereof to 50 % of baseline values, and also reduced the activity of the P13-kinase associated with IRS-1. These data were in agreement with those of Shintani et al., who explored the mechanism of insulin resistance in mice. Both studies found that impaired tyrosine phosphorylation of IRS-1 induced insulin resistance in animals infected by HCV. It is, however, surprising, in a sense, that the mechanism of insulin resistance induced by HCV infection is identical in both clinical samples and experimental animals, because, earlier, hepatic IRS-2 was thought to be more important than IRS-1 in terms of development of insulin resistance (Suzuki et al. 2004).
Insulin resistance in patients with HCV infections may have an additional significant clinical implication. In 260 patients with chronic HCV infections, Hui et al. sought to establish a relationship between liver histology, and indicators of glucose metabolism and insulin resistance, using the homeostasis model assessment of such resistance (HOMA-IR). It was found that insulin resistance was already evident in patients with stage 0 or 1 liver fibrosis, indicating that such resistance in HCV-infected patients was not attributable to advanced liver disease (Hui et al. 2003). HOMA-IR was a significant and independent predictor of hepatic fibrosis stage, and the speed of development thereof. Others have reported similar results (Hickman et al. 2003). These data are important because they implicate a role for hyperinsulinemia, and (by inference) insulin resistance in promoting progression of hepatic fibrosis. Insulin has been shown to aggravate not only atherosclerosis, but also systemic inflammation and fibrosis. The liver would not be an exception in this context.
2.6 Lipid Metabolism Disturbances and Steatosis
Hepatic steatosis is frequently observed in chronically HCV-infected patients (Bach et al. 1992; Lefkowitch et al. 1993; Czaja et al. 1998). The liver fatty acid composition in core gene transgenic mice (Moriya et al. 1997, 1998) differs from that in fatty livers caused simply by obesity. The levels of carbon 18 mono-unsaturated fatty acids (C18:1), such as oleic or vaccenic acid, which encourage proliferation of cancer cells (Kudo et al. 2011), were significantly increased in transgenic mice. This was also true when liver tissues from hepatitis C patients, and obese patients with simple “fatty livers”, were compared (Moriya et al. 2001). Patients with HCV infections also exhibit dyslipidemia as part of the phenotype of hypo-beta-lipoproteinemia (Moriya et al. 2003). Chronic hepatitis C patients, in whom the liver fibrosis stages were comparable to those of control patients with chronic hepatitis B, showed reduced serum levels of total cholesterol and apolipoproteins B1, C2, and C3, whereas the levels of apolipoproteins A1, A2, and E were similar to those of controls.
The mechanism of steatogenesis in hepatitis C patients has been investigated using (principally) the mouse model described above. At least three pathways are involved in development of steatosis. One is the insulin resistance pathway that frequently develops in hepatitis C patients, as well as in core gene transgenic mice, as described above (Shintani et al. 2004). Insulin resistance increases the peripheral release and hepatic uptake of fatty acids, resulting in lipid accumulation in the liver. The second pathway involves suppression of the activity of microsomal triglyceride transfer protein (MTP) by HCV core protein (Perlemuter et al. 2002). This, in turn, reduces the secretion of very-low-density-lipoprotein (VLDL) from the liver, increasing liver triglyceride levels. The last pathway involves the sterol regulatory element-binding protein (SREBP)-1c, which regulates the production levels of triglycerides and phospholipids. In HCV core gene transgenic mice, SREBP-1c is upregulated, but this is not true of either SREBP-2 or SREBP-1a (Moriishi et al. 2007). Such results have been obtained in both in vitro studies (Kim et al. 2007; Waris et al. 2007) and work with chimpanzees (Su et al. 2002). Thus, all three pathways result in development of hepatic steatosis in hepatitis C patients (Fig. 1). Steatosis exacerbates the production of reactive oxygen species and accelerates progression of liver disease.
Recently, it has been reported that assembly and budding of HCV occur around lipid droplets accumulated within the endoplasmic reticulum (Miyanari et al. 2007). Furthermore, increases in saturated and monounsaturated fatty acid levels enhanced HCV-RNA replication. Such data suggest that regulation of lipid metabolism by the core protein plays a crucial role in the HCV life cycle. An inflammatory cytokine, TNF-alpha, is known to impair the insulin-signaling pathway via inhibition of tyrosine phosphorylation of IRS. Indeed, overproduction of TNF-alpha (Tsutsumi et al. 2002) has been reported to reduce phosphorylation of both IRS-1 and Akt in core gene-transgenic mice. Moreover, the hyperinsulinemia that developed was cured by depletion of TNF-alpha, suggesting that upregulation of TNF-alpha level contributes to core protein-induced insulin resistance (Shintani et al. 2004).
Hepatic steatosis is significantly associated with accelerated progression of liver fibrosis (Powell et al. 2005). A study on 180 hepatitis C patients for whom the dates of infection were known confirmed that steatosis of grades 3–4 was significantly associated with a higher annual rate of fibrosis progression, and that alcohol and steatosis acted together to increase fibrosis (Adinolfi et al. 2001). In another study on 96 untreated patients with CHC, who underwent serial liver biopsies, fibrosis progression was strongly associated with worsening of the steatosis, which was the only significant factor so associated upon multivariate analysis. (Castera et al. 2003).
2.7 Lichen Planus
Lichen planus is an inflammatory disease associated with chronic abnormal dermal and intraoral keratinization of unknown etiology. The assumed causes include viral or bacterial infection, immunological responses, circulatory disorders, allergy, mental stress, abnormal autonomic function, medication, and disorders of glucose metabolism (Scully et al. 1998).
A number of reports on relationships between lichen planus and HCV infection have appeared, but the anti-HCV antibody positivity rate in lichen planus patients exhibited marked regional differences, ranging from 0 to 65 % (Bellamn et al. 1995; Nagao et al. 1995a). HCV reproduction in the skin and oral mucosal epithelium has been examined by in situ hybridization and RT-PCR (Nagao et al. 2000; Arrieta et al. 2000). HCV-specific T cells have been reported to be linked to the pathogenesis of the condition (Pilli et al. 2002), but none of HCV level, genotype, or pathological severity, was so associated (Nagao et al. 1996). Antiviral therapy (IFN) has been reported to be effective (Doutre et al. 1992). However, other investigators have reported that IFN rather induces or aggravates lichen planus (Baccia et al. 1993; Protzer et al. 1993). Thus, the effectiveness of IFN used to treat lichen planus remains debatable. Nagao et al. found no macroscopic changes in lesions 1 year after the end of IFN administration (to treat intraoral lichen planus lesions) in patients with chronic HCV infection, but macroscopic and histological improvements were evident 3 or more years after IFN administration ceased. It was assumed that not HCV infection, but rather the immunological response to such infection, was associated with development of oral lichen planus, as positive-strand HCVRNA was detected in the oral mucous membrane of some lichen planus patients although they had (histologically) recovered after IFN therapy (Nagao et al. 1999).
2.8 Oral Cancer
A relationship between HCV infection and oral cancer was first reported by Nagao et al., who found that the HCV infection rate was higher in oral cancer patients than in those with esophageal, gastric, or colorectal cancer (Nagao et al. 1995b). When HCV-RNA levels were examined in oral cancer tissues from 17 patients, via RT-PCR, positive-strand HCV RNA was detectable in all anti-HCV-positive patients, and negative-strand HCV-RNA in 71.4 % of such patients (Nagao et al. 2000). These findings indicate that HCV may possibly replicate in oral cancer tissues. No definite consensus has yet emerged on any relationship between oral lichen planus and oral cancer. However, as lichen planus is considered to be precancerous, oral examination may be necessary in patients with chronic HCV infections.
2.9 Malignant Lymphoma
HCV replicates in lymphocytes, although not robustly (Ito et al. 2010a), and short-term HCV culture systems using lymphocytes have been developed (Ito et al. 2001; Shimizu et al. 1992). Infected lymphocytes may undergo malignant transformation, leading to development of malignant lymphoma, after acquisition of certain genetic mutations (Machida et al. 2004; Mizuochi et al. 2011; Ito et al. 2009, 2010b). HCV infection is considered to be associated with development of malignant lymphoma, particularly the pathogenesis of non-Hodgkin’s B-cell lymphoma (Gisbert et al. 2003; de Sanjose et al. 2008). Some cryoglobulinemia patients have been assumed to develop non-Hodgkin’s B-cell lymphoma in association with myc gene mutation (Perl et al. 1989). The anti-HCV positivity rate in patients with non-Hodgkin’s B-cell lymphoma ranges from 0 to 33 % (Gisbert et al. 2003). Such variation may be associated with regional differences in HCV infection rates. Fourteen of 500 patients with chronic HCV infections had disease complicated with non-Hodgkin’s B-cell lymphoma, and HCV-RNA was found in peripheral blood lymphocytes of all patients (Ferri et al. 1995). Positive- and negative-strand HCV-RNAs were detected in parotid glands of patients with parotid non-Hodgkin’s B-cell lymphoma associated with HCV infection, and the presence of HCV in the parotid gland was confirmed by in situ hybridization (De Vita et al. 1995). Data from the International Lymphoma Epidemiology Consortium confirmed an association between HCV infection, and NHL and specific B-NHL subtypes (diffuse large B-cell lymphoma, marginal zone lymphoma, and lymphoplasmacytic lymphoma) (de Sanjose et al. 2008).
The treatment of HCV-associated malignant lymphoma is similar to that for non-HCV-associated non-Hodgkin B-cell lymphoma. However, recently, IFN monotherapy, or IFN and ribavirin combination therapy, has been reported to be effective. IFN was effective when used to treat certain specific lymphomas, including splenic lymphoma associated with production of villous lymphocytes (Hermine et al. 2002). Administration of pegylated IFN and ribavirin to 13 patients with HCV-associated non-Hodgkin’s B-cell lymphoma afforded complete responses in 7 (Vallisa et al. 2005).
2.10 Autoimmune Thyroid Disease
The relationship between thyroid disease and HCV infection has been analyzed in a number of studies (Montella et al. 2003; Testa et al. 2006), and a causal linkage has been suggested. The incidence of thyroid dysfunction was assessed in 630 chronic HCV patients, without cirrhosis or HCC, who had not been treated with IFN. These patients had higher levels of thyroid-stimulating hormone, and lower levels of free thyroxine and triiodothyronine, than controls. In addition, the patients exhibited hypothyroidism and tended to have anti-thyroglobulin and anti-thyroid peroxidase antibodies. These findings suggest that a relationship exists between HCV infection and thyroid disorder (Antonelli et al. 2004). A possible relationship between such infection and thyroid cancer has attracted recent attention. The mechanism underlying the pathogenesis of thyroid disease associated with HCV infection has not yet been elucidated, but involvement of liver/kidney microsomal antibody type 1 has been suggested (Muratori et al. 2005). In general, patients with thyroid disorders caused by HCV infection are asymptomatic, and require no special treatment. Thyroid disorders are also known to develop as adverse reactions to IFN-alpha therapy for chronic HCV infection (Prummel and Laurburg 2003). Thyroid dysfunction caused by administration of IFN-alpha is generally transient, resolving spontaneously after completion of treatment. Thus, discontinuation of IFN-alpha is not required in most cases.
2.11 Idiopathic Interstitial Pneumonitis
Viral infection has been suggested to be a cause of idiopathic interstitial pneumonitis. In terms of HCV infection, the anti-HCV positivity rate was 28.8 % in 66 patients with idiopathic interstitial pneumonitis (IIP), thus significantly higher than that in 9464 normal controls (Ueda et al. 1992). Any role for HCV infection, however, in the pathogenesis of idiopathic interstitial pneumonitis, remains unclear. Activation of T lymphocytes and eosinophils was suggested to be a feature of IIP pathogenesis associated with HCV infection, because increases in the counts of activated T-lymphocytes and eosinophils were noted in bronchoalveolar fluids from 13 chronic hepatitis C patients, although the total cell counts were identical to those of normal subjects (Kubo et al. 1996). Some studies, however, suggest that no relationship exists between HCV infection and IIP (Irving et al. 1993); further work is necessary. IIP has also been reported as an adverse reaction to IFN therapy in chronic HCV patients, who often exhibit high pretreatment KL-6 levels, suggesting that IIP might potentially develop. Recovery from IFN therapy-induced IIP is achieved by discontinuation of therapy, but steroid administration is required in some cases (Karim et al. 2001).
2.12 Myocardial Impairments
Causal relationships between HCV infection and certain myocardial impairments have been suspected; the impairments include dilated cardiomyopathy, hypertrophic cardiomyopathy, arrhythmogenic right ventricular dysplasia cardiomyopathy, and chronic myocarditis (Matsumori et al. 2000; Matsumori 2006). The rate of serum anti-HCV positivity was 6.3 % (42/663) in patients with hypertrophic cardiomyopathy and 10.6 % (74/697) in those with dilated cardiomyopathy, thus higher than the rate (2.4 %) observed among age-matched Japanese blood donors (Matsumori et al. 2000). Positive- and negative-strand HCV-RNAs were detected in cardiac muscle samples of these patients, indicating potential intramyocardial HCV multiplication (Matsumori 2006). HCV-RNA has also been detected in cardiac muscle samples from patients with arrhythmogenic right ventricular dysplasia cardiomyopathy and chronic myocarditis, suggesting that HCV plays a pivotal role in the genesis of myocardial impairments (Maisch et al. 2003).
In terms of the cause of myocardial impairments associated with HCV, the involvement of host immunological responses to HCV, particularly that of the human major histocompatibility (MHC) class II antigen, has been suggested (Matsumori 2006). The suggested relationships between myocardial disorders and HCV infection require further investigation.
2.13 Mooren’s Ulcer
Mooren’s ulcer is a progressive ulcer associated with congestion and pain around the cornea. HCV infection has been suggested to contribute to development of this disease (Wilson et al. 1994; Moazami et al. 1995). IFN has been reported to be effective for treating HCV-associated Mooren’s ulcers, but ocular pain became exacerbated following IFN discontinuation; hence, caution is required when treating such patients (Wilson et al. 1994). Systemic corticosteroid administration has also been reported to be effective. However, some investigators are of the view that no association exists between HCV infection and Mooren’s ulcer (Zegans et al. 1999; Jain et al. 2004). Further detailed studies would clarify this issue.
2.14 Cognitive and Mental Disorders
Certain mental, psychiatric, and cognitive disorders have been associated with HCV infection in a number of studies. Those include depression, cognitive impairment, and fatigue; all reduce health-related quality of life. For further information, please refer to the comprehensive reviews that have appeared on this issue (Perry et al. 2008; Jacobson et al. 2010).
2.15 All-Cause Mortality in HCV-Seropositives
Recently, several studies on all-cause death levels in HCV patients have been performed. One was a community-based long-term prospective study in Taiwan. In this work, 23,820 adults aged 30–65 years were enrolled during 1991–1992, and vital status was ascertained via computerized linkage to national death certificate profiles in the years 1991–2008. Of all subjects, 1095 were anti-HCV positive and 69.4 % had detectable serum HCV-RNA levels. Compared to anti-HCV seronegative subjects, the seropositive subjects exhibited higher mortalities from both hepatic and extrahepatic diseases. The multivariate-adjusted hazard ratios (with 95 % confidence intervals) were 1.89 (1.66–2.15) for all causes of death; 12.48 for hepatic diseases, 1.35 for extrahepatic diseases; 1.50 for circulatory diseases; 2.77 for nephritis, nephrotic syndrome, and nephrosis; 4.08 for esophageal cancer; 4.19 for prostate cancer; and 8.22 for thyroid cancer. Thus, anti-HCV seropositives with detectable HCV-RNA exhibited significantly higher mortality from not only hepatic, but also extrahepatic diseases, than did anti-HCV seronegatives (Lee et al. 2012).
Similarly, Mahajan et al. evaluated mortality among patients with HCV infection, who were in care, in the Chronic Hepatitis Cohort Study (CHeCS) conducted from 2006 to 2010 in the United States. Mortality was compared with national Multiple Cause of Death (MCOD) data from 12 million US death certificates issued in 2006–2010. It was found that the CHeCS cohort exhibited higher mortalities from both hepatic and extrahepatic diseases: non-alcoholic liver-related death levels were 24.4-fold higher in the CHeCS cohort; deaths from liver cancer 8.7-fold higher; deaths from cancers other than liver cancer 1.28-fold higher; deaths from circulatory disease 1.42-fold higher; deaths from diabetes 1.77-fold higher; and deaths from genitourinary conditions 3.75-fold higher (Mahajan et al. 2014). Thus, HCV-positive patients exhibit higher mortality not only from liver diseases but also from extrahepatic diseases, confirming that extrahepatic manifestations of HCV infection, such as EMC, diabetes, or disorders in lipid metabolism (as described above) increase the mortality rates of such patients.
3 Conclusion
HCV infection is a multifaceted disease exhibiting both hepatic and extrahepatic manifestations caused by viral replication. Although the risk of death from extrahepatic conditions is lower than that associated with hepatic disease, it is important to be aware of the extrahepatic manifestations and diseases associated with HCV infection so that appropriate antiviral or immunomodulating treatments are administered, in a timely manner, to cure patients thus affected.
References
Adinolfi LE, Gambardella M, Andreana A, Tripodi MF, Utili R, Ruggiero G (2001) Steatosis accelerates the progression of liver damage of chronic hepatitis C patients and correlates with specific HCV genotype and visceral obesity. Hepatology 33:1358–1364
Agnello V, Chung RT, Kaplan IM (1992) A roll for hepatitis C virus infection in type II cryoglobulinaemia. N Engl J Med 327:1490–1495
Allison ME, Wreghitt T, Palmer CR, Alexander GJ (1994) Evidence for a link between hepatitis C virus infection and diabetes mellitus in a cirrhotic population. J Hepatol 21:1135–1139
Antonelli A, Ferri C, Pampana A, Fallahi P, Nesti C, Pasquini M et al (2004) Thyroid disorders in chronic hepatitis C. Am J Med 117:10–13
Arase Y, Ikeda K, Murashima N, Chayama K, Tsubota A, Koida I et al (1998) Glomerulonephritis in autopsy cases with hepatitis C virus infection. Intern Med 37:836–840
Arrieta JJ, Rodriguez-Inigo E, Casqueiro M, Bartolom J, Manzarbeitia F, Herrero M et al (2000) Detection of hepatitis C virus replication by in situ hybridization in epithelial cells of anti-hepatitis C virus-positive patients with and without oral lichen planus. Hepatology 32:97–103
Arrieta JJ, Rodriguez-Inigo E, Ortiz-Movilla N, Bartolome J, Pardo M, Manzarbeitia F et al (2001) In situ detection of hepatitis C virus RNA in salivary gland. Am J Pathol 158:259–264
Aytug S, Reich D, Sapiro LE, Bernstein D, Begum N (2003) Impaired IRS-1/PI3-kinase signaling in patients with HCV: a mechanism for increased prevalence of type 2 diabetes. Hepatology 38:1384–1392
Baccia S, Gamberini S, Della Libera M, Strumia R, Ventrurini D (1993) Lichen planus and interferon therapy for hepatitis C. Gastroenterology 105:1921–1922
Bach N, Thung SN, Schaffner F (1992) The histological features of chronic hepatitis C and autoimmune chronic hepatitis: a comparative analysis. Hepatology 15:572–577
Bellamn B, Reddy RK, Falanga V (1995) Lichen planus associated with hepatitis C. Lancet 346:1234
Bianchi G, Marchesini G, Zoli M, Bugianesi E, Fabbri A, Pisi E (1994) Prognostic significance of diabetes in patients with cirrhosis. Hepatology 20:119–125
Brouet JC, Clauvel JP, Danon, Klein M, Seligmann M (1974) Biologic and clinical significance of cryoglobulins. Am J Med 57:775–788
Cacoub P, Lidove O, Maisonobe T, Duhaut P, Thibault V, Ghillani P et al (2002) Interferon-alpha and ribavirin treatment in patients with hepatitis C virus-related systemic vasculitis. Arthritis Rheum 46:3317–3326
Cacoub P, Delluc A, Saadoun D, Landau DA, Sene D (2008) Anti-CD20 monoclonal antibody (rituximab) treatment for cryoglobulinemic vasculitis: where do we stand? Ann Rheum Dis 67:283–287
Castéra L, Hézode C, Roudot-Thoraval F, Bastie A, Zafrani ES, Pawlotsky JM et al (2003) Worsening of steatosis is an independent factor of fibrosis progression in untreated patients with chronic hepatitis C and paired liver biopsies. Gut 52:288–292
Curry MP, Golden-Mason L, Doherty DG, Deignan T, Norris S, Duffy M et al (2003) Expansion of innate CD5pos B cells expressing high levels of CD81 in hepatitis C virus infected liver. J Hepatol 38:642–650
Czaja AJ, Carpenter HA, Santrach PJ, Moore SB (1998) Host- and disease-specific factors affecting steatosis in chronic hepatitis C. J Hepatol 29:198–206
D’Amico G, Fornasieri A (1995) Cryoglobulinemic glomerulonephritis: a membranoproliferative glomerulonephritis induced by hepatitis C virus. Am J Kidney Dis 25:361–369
Dammacco F, Sansonno D, Han JH, Shyamala V, Cornacchiulo V, Iacobelli AR et al (1994) Natural interferon-alpha versus its combination with 6-methyl-prednisolone in the therapy of type II mixed cryoglobulinemia: a long-term, randomized, controlled study. Blood 84:3336–3343
de Sanjose S, Benavente Y, Vajdic CM, Engels EA, Morton LM, Bracci PM et al (2008) Hepatitis C and non-Hodgkin lymphoma among 4784 cases and 6269 controls from the International Lymphoma Epidemiology Consortium. Clin Gastroenterol Hepatol 6:451–458
De Vita S, Sansonno D, Dolcetti R, Ferraccioli G, Carbone A, Cornacchiulo V et al (1995) Hepatitis C virus within a malignant lymphoma lesion in the course of type II mixed cryoglobulinemia. Blood 86:1887–1892
Doutre MS, Beylot C, Couzigou P, Long P, Royer P, Beylot J (1992) Lichen planus and virus C hepatitis: disappearance of the lichen under interferon alpha herapy. Dermatology 184:229
Fargion S, Piperno A, Cappellini MD, Sampietro M, Fracanzani AL, Romano R et al (1992) Hepatitis C virus and porphyria cutanea tarda: evidence of a strong association. Hepatology 16:1322–1326
Ferri C, La Civita L, Monti M, Longombardo G, Greco F, Pasero G et al (1995) Can type C hepatitis infection be complicated by malignant lymphoma? Lancet 346:1426–1427
Fox RI (2005) Sjögren’s syndrome. Lancet 366:321–331
Gisbert JP, García-Buey L, Pajares JM, Moreno-Otero R (2003) Prevalence of hepatitis C virus infection in B-cell non-Hodgkin’s lymphoma: systematic review and meta-analysis. Gastroenterology 125:1723–1732
Gumber SC, Chopra S (1995) Hepatitis C: a multifaceted disease. Ann Intern Med 123:615–620
Haddad J, Deny P, Munz-Gotheil C, Ambrosini JC, Trinchet JC, Pateron D et al (1992) Lymphocytic sialadenitis of Sjögren’s syndrome associated with chronic hepatitis C virus liver disease. Lancet 339:321–323
Hassan MM, Hwang LY, Hatten CJ, Swaim M, Li D, Abbruzzese JL et al (2002) Risk factors for hepatocellular carcinoma: synergism of alcohol with viral hepatitis and diabetes mellitus. Hepatology 36:1206–1213
Hermine O, Lefrere F, Bronowicki JP, Mariette X, Jondeau K, Eclache-Saudreau V et al (2002) Regression of splenic lymphoma with villous lymphocytes after treatment of hepatitis C virus infection. N Engl J Med 347:89–94
Hickman IJ, Powell EE, Prins JB, Clouston AD, Ash S, Purdie DM, Jonsson JR (2003) In overweight patients with chronic hepatitis C, circulating insulin is associated with hepatic fibrosis: implications for therapy. J Hepatol 39:1042–1048
Hui JM, Sud A, Farrell GC, Bandara P, Byth K, Kench JG et al (2003) Insulin resistance is associated with chronic hepatitis C virus infection and fibrosis progression. Gastroenterology 125:1695–1704
Ikeda K, Saitoh S, Suzuki Y, Kobayashi M, Tsubota A, Koida I et al (1998) Disease progression and hepatocellular carcinogenesis in patients with chronic viral hepatitis: a prospective observation of 2215 patients. J Hepatol 28:930–938
Irving WL, Day S, Johnston ID (1993) Idiopathic pulmonary fibrosis and hepatitis C virus infection. Am Rev Respir Dis 148:1683–1684
Ito T, Yasui K, Mukaigawa J, Katsume A, Kohara M, Mitamura K (2001) Acquisition of susceptibility to hepatitis C virus replication in HepG2 cells by fusion with primary human hepatocytes: establishment of a quantitative assay for hepatitis C virus infectivity in a cell culture system. Hepatology 34:566–572
Ito M, Mizoroki F, Takai K, Yamaguchi K, Mizuochi T (2009) Functional phenotypes and gene expression profiles of peripheral blood mononuclear cells in chronic hepatitis C patients who developed non-Hodgkin’s B-cell lymphoma. Biochem Biophys Res Commun 390:269–272
Ito M, Masumi A, Mochida K, Kukihara H, Moriishi K, Matsuura Y, Yamaguchi K, Mizuochi T (2010a) Peripheral B cells may serve as a reservoir for persistent hepatitis C virus infection. J Innate Immun 2:607–617
Ito M, Murakami K, Suzuki T, Mochida K, Suzuki M, Ikebuchi K, Yamaguchi K, Mizuochi T (2010b) Enhanced expression of lymphomagenesis-related genes in peripheral blood B cells of chronic hepatitis C patients. Clin Immunol 135:459–465
Jacobson IM, Cacoub P, Dal Maso L, Harrison SA, Younossi ZM (2010) Manifestations of chronic hepatitis C virus infection beyond the liver. Clin Gastroenterol Hepatol 8:1017–1029
Jain AK, Sukhija J, Saini JS, Chawla Y, Dhiman RK (2004) Hepatitis C virus-associated keratitis. Eye 18:131–134
Johnson RJ, Gretch DR, Yamabe H, Hart J, Bacchi CE, Hartwell P et al (1993) Membranoproliferative glomerulonephritis associated with hepatitis C virus infection. N Engl J Med 328:465–470
Johnson RJ, Gretch DR, Couser WG, Alpers CE, Willson J, Chung M et al (1994) Hepatitis C virus-associated glomerulonephritis. Effect of alpha-interferon therapy. Kidney Int 46:1700–1704
Karim A, Ahmed S, Khan A, Steinberg H, Mattana J (2001) Interstitial pneumonitis in a patient treated with alpha-interferon and ribavirin for hepatitis C infection. Am J Med Sci 322:233–235
Kasuno K, Ono T, Matsumori A, Nogaki F, Kusano H, Watanabe H et al (2003) Hepatitis C virus-associated tubulointerstitial injury. Am J Kidney Dis 41:767–775
Kim KH, Hong SP, Kim K, Park MJ, Kim KJ, Cheong J (2007) HCV core protein induces hepatic lipid accumulation by activating SREBP1 and PPARgamma. Biochem Biophys Res Commun 55:883–888
Koike K, Moriya K (2005) Metabolic aspects of hepatitis C viral infection: steatohepatitis resembling but distinct from NASH. J Gastroenterol 40:329–336
Koike K, Moriya K, Ishibashi K, Yotsuyanagi H, Shintani Y, Fujie H et al (1997) Sialadenitis histologically resembling Sjögren syndrome in mice transgenic for hepatitis C virus envelope genes. Proc Natl Acad Sci U S A 94:233–236
Kubo K, Yamaguchi S, Fujimoto K, Hanaoka M, Hayasaka M, Honda T et al (1996) Bronchoalveolar lavage fluid findings in patients with chronic hepatitis C virus infection. Thorax 51:312–314
Kudo Y, Tanaka Y, Tateishi K, Yamamoto K, Yamamoto S, Mohri D et al (2011) Altered composition of fatty acids exacerbates hepatotumorigenesis during activation of the phosphatidylinositol 3-kinase pathway. J Hepatol 55:1400–1408
Lee MH, Yang HI, Lu SN, Jen CL, You SL, Wang LY, Wang CH, Chen WJ, Chen CJ, R.E.V.E.A.L.-HCV Study Group (2012) Chronic hepatitis C virus infection increases mortality from hepatic and extrahepatic diseases: a community-based long-term prospective study. J Infect Dis 206:469–477
Lefkowitch JH, Schiff ER, Davis GL, Perrillo RP, Lindsay K, Bodenheimer HC Jr et al (1993) Pathological diagnosis of chronic hepatitis C: a multicenter comparative study with chronic hepatitis B. Gastroenterology 104:595–603
Lunel F, Cacoub P (2000) Treatment of autoimmune and extra-hepatic manifestations of HCV infection. Ann Med Interne (Paris) 151:58–64
Lunel F, Musset L, Cacoub P, Frangeul L, Cresta P, Perrin M et al (1994) Cryoglobulinemia in chronic liver disease: role of hepatitis C virus and liver damage. Gastroenterology 106:1291–1300
Machida K, Cheng KT, Sung VM, Shimodaira S, Lindsay KL, Levine AM, Lai MY, Lai MM (2004) Hepatitis C virus induces a mutator phenotype: enhanced mutations of immunoglobulin and protooncogenes. Proc Natl Acad Sci U S A 101:4262–4267
Mahajan R, Xing J, Liu SJ, Ly KN, Moorman AC, Rupp L, Xu F, Holmberg SD, Chronic Hepatitis Cohort Study (CHeCS) Investigators (2014) Mortality among persons in care with hepatitis C virus infection: the Chronic Hepatitis Cohort Study (CHeCS), 2006–2010. Clin Infect Dis 58:1055–1061
Maisch B, Ristic AD, Portig I, Pankuweit S (2003) Human viral cardiomyopathy. Front Biosci 8:39–67
Matsumori A (2006) Role of hepatitis C virus in cardiomyopathies. Ernst Schering Res Found Work 55:99–120
Matsumori A, Yutani C, Ikeda Y, Kawai S, Sasayama S (2000) Hepatitis C virus from the hearts of patients with myocarditis and cardiomyopathy. Lab Invest 80(7):1137–1142
Mayo MJ (2002) Extrahepatic manifestation of hepatitis C infection. Am J Med Sci 325:135–148
Mehta SH, Brancati FL, Sulkowski MS, Strathdee SA, Szklo M, Thomas DL (2000) Prevalence of type 2 diabetes mellitus among persons with hepatitis C virus infection in the United States. Ann Intern Med 133:592–599
Misiani R, Bellavita P, Fenili D, Vicari O, Marchesi D, Sironi PL et al (1994) Interferon alpha-2a therapy in cryoglobulinemia associated with hepatitis C virus. N Engl J Med 330:751–756
Misiani R, Bellavita P, Baio P, Caldara R, Ferruzzi S, Rossi P et al (1999) Successful treatment of HCV-associated cryoglobulinaemic glomerulonephritis with a combination of interferon-alpha and ribavirin. Nephrol Dial Transplant 14:1558–1560
Miyanari Y, Atsuzawa K, Usuda N, Watashi K, Hishiki T, Zayas M et al (2007) The lipid droplet is an important organelle for hepatitis C virus production. Nat Cell Biol 9:1089–1097
Mizuochi T, Ito M, Takai K, Yamaguchi K (2011) Peripheral blood memory B cells are resistant to apoptosis in chronic hepatitis C patients. Virus Res 155:349–351
Moazami G, Auran JD, Florakis GJ, Wilson SE, Srinivasan DB (1995) Interferon treatment of Mooren’s ulcers associated with hepatitis C. Am J Ophthalmol 119:365–366
Montella M, Pezzillo L, Crispo A, Izzo F, Amore A, Marone U et al (2003) Risk of thyroid cancer and high prevalence of hepatitis C virus. Oncol Rep 10:113–116
Moriishi K, Mochizuki R, Moriya K, Miyamoto H, Mori Y, Abe T et al (2007) Critical role of PA28gamma in hepatitis C virus-associated steatogenesis and hepatocarcinogenesis. Proc Natl Acad Sci U S A 104:1661–1666
Moriya K, Yotsuyanagi H, Shintani Y, Fujie H, Ishibashi K, Matsuura Y, Miyamura T, Koike K (1997) Hepatitis C virus core protein induces hepatic steatosis in transgenic mice. J Gen Virol 78:1527–1531
Moriya K, Fujie H, Shintani Y, Yotsuyanagi H, Tsutsumi T, Matsuura Y, Kimura S, Miyamura T, Koike K (1998) Hepatitis C virus core protein induces hepatocellular carcinoma in transgenic mice. Nat Med 4:1065–1068
Moriya K, Todoroki T, Tsutsumi T, Fujie H, Shintani Y, Miyoshi H et al (2001) Increase in the concentration of carbon 18 monounsaturated fatty acids in the liver with hepatitis C: analysis in transgenic mice and humans. Biophys Biochem Res Commun 281:1207–1212
Moriya K, Shintani Y, Fujie H, Miyoshi H, Tsutsumi T, Yotsuyanagi H et al (2003) Serum lipid profile of patients with genotype 1b hepatitis C viral infection in Japan. Hepatol Res 25:369–374
Muratori L, Bogdanos DP, Muratori P, Lenzi M, Granito A, Ma Y et al (2005) Susceptibility to thyroid disorders in hepatitis C. Clin Gastroenterol Hepatol 3:595–603
Nagao Y, Sata M, Tanikawa K, Itoh K, Kameyama T (1995a) Lichen planus and hepatitis C virus in the northern Kyushu region of Japan. Eur J Clin Invest 25:910–914
Nagao Y, Sata M, Tanikawa K, Itoh K, Kameyama T (1995b) High prevalence of hepatitis C virus antibody and RNA in patients with oral cancer. J Oral Pathol Med 24:354–360
Nagao Y, Sata M, Itoh K, Tanikawa K, Kameyama T (1996) Quantitative analysis of HCV RNA and genotype in patients with chronic hepatitis C accompanied by oral lichen planus. Eur J Clin Invest 26:495–498
Nagao Y, Sata M, Suzuki H, Kameyama T, Ueno T (1999) Histological improvement of oral lichen planus in patients with chronic hepatitis C treated with interferon. Gastroenterology 117:283–284
Nagao Y, Sata M, Noguchi S, Seno’o T, Kinoshita M, Kameyama T et al (2000) Detection of hepatitis C virus RNA in oral lichen planus and oral cancer tissues. J Oral Pathol Med 29:259–266
Nagao Y, Hanada S, Shishido S, Ide T, Kumashiro R, Ueno T et al (2003) Incidence of Sjögren’s syndrome in Japanese patients with HCV infection. J Gastroenterol Hepatol 18:258–266
Okano J, Horie Y, Kawasaki H, Kondo M (1997) Interferon treatment of porphyria cutanea tarda associated with chronic hepatitis type C. Hepatogastroenterology 44:525–528
Okuse C, Yotsuyanagi Y, Okazaki T, Yasuda K, Fujioka T, Tomoe M et al (2003) Detection, using a novel method, of a high prevalence of cryoglobulinemia in persistent hepatitis C virus infection. Hepatol Res 27:18–22
Pawlotsky JM, Dhumeaux D, Bagot M (1995) Hepatitis C virus in dermatology. A review. Arch Dermatol 131:1185–1193
Perl A, Gorevic PD, Ryan DH, Condemi JJ, Ruszkowski RJ, Abraham GN (1989) Clonal B cell expression in patients with essential mixed cryoglobulinemia. Clin Exp Immunol 76:54–60
Perlemuter G, Sabile A, Letteron P, Vona G, Topilco A, Koike K et al (2002) Hepatitis C virus core protein inhibits microsomal triglyceride transfer protein activity and very low density lipoprotein secretion: a model of viral-related steatosis. FASEB J 16:185–194
Perry W, Hilsabeck RC, Hassanein TI (2008) Cognitive dysfunction in chronic hepatitis C: a review. Dig Dis Sci 53:307–321
Petit JM, Bour JB, Galland-Jos C, Minello A, Verges B, Guiguet M et al (2001) Risk factors for diabetes mellitus and early insulin resistance in chronic hepatitis C. J Hepatol 35:279–283
Pilli M, Penna A, Zerbini A, Vescovi P, Manfredi M, Negro F et al (2002) Oral lichen planus pathogenesis: a role for the HCV-specific cellular immune response. Hepatology 36:1446–1452
Powell EE, Jonsson JR, Clouston AD (2005) Steatosis: co-factor in other liver diseases. Hepatology 42:5–13
Pradhan AD, Ridker PM (2002) Do atherosclerosis and type2 diabetes share a common inflammatory basis? Eur Heart J 23:831–834
Protzer U, Ochsendorf FR, Leopolder-Ochsendorf A, Holtermuller KH (1993) Exacerbation of lichen planus during interferon alpha-2a therapy for chronic active hepatitis C. Gastroenterology 104:903–905
Prummel MF, Laurberg P (2003) Interferon-alpha and autoimmune thyroid disease. Thyroid 13:547–551
Saadoun D, Sellam J, Ghillani-Dalbin P, Crecel R, Piette JC, Cacoub P (2006) Increased risks of lymphoma and death among patients with non-hepatitis C virus-related mixed cryoglobulinemia. Arch Intern Med 166:2101–2108
Saadoun D, Landau DA, Calabrese LH, Cacoub PP (2007) Hepatitis C-associated mixed cryoglobulinaemia: a crossroad between autoimmunity and lymphoproliferation. Rheumatology (Oxford) 46(8):1234–1242
Saadoun D, Resche Rigon M, Sene D, Terrier B, Karras A, Perard L, Schoindre Y, Coppéré B, Blanc F, Musset L, Piette JC, Rosenzwajg M, Cacoub P (2010) Rituximab plus Peg-interferon-alpha/ribavirin compared with Peg-interferon-alpha/ribavirin in hepatitis C-related mixed cryoglobulinemia. Blood 116:326–334
Saadoun D, Resche Rigon M, Pol S, Thibault V, Blanc F, Pialoux G et al (2014) Peg-IFNαRibavirin/protease inhibitor combination in severe hepatitis C virus associated mixed cryoglobulinemia vasculitis. J Hepatol. doi:10.1016/j.jhep.2014.08.015, S0168-8278(14)00555-8, [Epub ahead of print]
Saito I, Miyamura T, Ohbayashi A, Harada H, Katayama T, Kikuchi S et al (1990) Hepatitis C virus infection is associated with the development of hepatocellular carcinoma. Proc Natl Acad Sci U S A 87:6547–6549
Sarkany RP (2001) The management of porphyria cutanea tarda. Clin Exp Dermatol 26:225–232
Scully C, Beyli M, Ferreiro MC, Ficarra G, Gill Y, Griffiths M et al (1998) Update on oral lichen planus: etiopathogenesis and management. Crit Rev Oral Biol Med 9:86–122
Shimizu YK, Iwamoto A, Hijikata M, Purcell RH, Yoshikura H (1992) Evidence for in vitro replication of hepatitis C virus genome in a human T-cell line. Proc Natl Acad Sci U S A 89:5477–5481
Shintani Y, Fujie H, Miyoshi H, Tsutsumi T, Tsukamoto K, Kimura S et al (2004) Hepatitis C virus and diabetes: direct involvement of the virus in the development of insulin resistance. Gastroenterology 126:840–848
Sinico RA, Fornasieri A, D’Amico G (2000) Renal manifestations associated with hepatitis C infection. Ann Med Interne (Paris) 151:41–45
Su AI, Pezacki JP, Wodicka L, Brideau AD, Supekova L, Thimme R et al (2002) Genomic analysis of the host response to hepatitis C virus infection. Proc Natl Acad Sci U S A 99:15669–15674
Suzuki R, Tobe K, Aoyama M, Inoue A, Sakamoto K, Yamauchi T et al (2004) Both insulin signaling defects in the liver and obesity contribute to insulin resistance and cause diabetes in Irs2(-/-) mice. J Biol Chem 279:25039–25049
Takamatsu K, Okayasu I, Koyanagi Y, Yamamoto N (1992) Hepatitis C virus propagates in salivary glands. J Infect Dis 165:973–974
Testa A, Castaldi P, Fant V, Fiore GF, Grieco V, DeRosa A et al (2006) Prevalence of HCV antibodies in autoimmune thyroid disease. Eur Rev Med Pharmacol Sci 10:183–186
Tsutsumi T, Suzuki T, Moriya K, Yotsuyanagi H, Shintani Y, Fujie H et al (2002) Intrahepatic cytokine expression and AP-1 activation in mice transgenic for hepatitis C virus core protein. Virology 304:415–424
Ubara Y, Hara S, Katori H, Tagami T, Kitamura A, Yokota M et al (2000) Splenectomy may improve the glomerulopathy of type II mixed cryoglobulinemia. Am J Kidney Dis 35:1186–1192
Ueda T, Ohta K, Suzuki N, Yamaguchi M, Hirai K, Horiuchi T et al (1992) Idiopathic pulmonary fibrosis and high prevalence of serum antibodies to hepatitis C virus. Am Rev Respir Dis 146:266–268
Vallisa D, Bernuzzi P, Arcaini L, Sacchi S, Callea V, Marasca R et al (2005) Role of anti-hepatitis C virus (HCV) treatment in HCV-related, low-grade, B-cell, non-Hodgkin’s lymphoma: a multi-center Italian experience. J Clin Oncol 23:468–473
Waris G, Felmlee DJ, Negro F, Siddiqui A (2007) Hepatitis C virus induces proteolytic cleavage of sterol regulatory element binding proteins and stimulates their phosphorylation via oxidative stress. J Virol 81:8122–8130
Wilson SE, Lee WM, Murakami C, Weng J, Moninger GA (1994) Mooren-type hepatitis C virus-associated corneal ulceration. Ophthalmology 101:736–745
Wong VS, Egner W, Elsey T, Brown D, Alexander GJ (1996) Incidence, character and clinical relevance of mixed cryoglobulinemia in patients with chronic hepatitis C infection. Clin Exp Immunol 104:25–31
Zegans ME, Srinivasan M, McHugh T, Whitcher JP, Margolis TP, Lietman T et al (1999) Mooren ulcer in South India: serology and clinical risk factors. Am J Ophthalmol 128:205–210
Zuckerman E, Keren D, Slobodin G, Rosner I, Rozenbaum M, Toubi E, Sabo E et al (2000) Treatment of refractory, symptomatic, hepatitis C virus related mixed cryoglobulinemia with ribavirin and interferon-alpha. J Rheumatol 27:2172–2178
Zylberberg H, Rimaniol AC, Pol S, Masson A, De Groote D, Berthelot P et al (1999) Soluble tumor necrosis actor receptors in chronic hepatitis C: a correlation with histological fibrosis and activity. J Hepatol 30:185–191
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This work was supported in part by Health Sciences Research Grants of The Ministry of Health, Labour and Welfare of Japan (Research on Hepatitis).
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Koike, K. (2016). The Multifaceted Features of HCV Infection Beyond the Liver. In: Miyamura, T., Lemon, S., Walker, C., Wakita, T. (eds) Hepatitis C Virus II. Springer, Tokyo. https://doi.org/10.1007/978-4-431-56101-9_2
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