There is a complex and bidirectional interaction between hepatitis C virus infection and insulin sensitivity.1 Hepatitis C core protein promotes degradation of insulin receptor substrate-1 and induces insulin resistance. Increased insulin resistance index was associated with reduced rapid virological response2,3 and sustained virological response rates in patients treated with pegylated interferon and ribavirin.3-5 Moreover, hepatitis C clearance was related to improved insulin sensitivity, decreased diabetes mellitus and glucose abnormalities development during follow-up and improved insulin receptor subs- trate-1 and 2 expression in hepatocytes, providing strong evidence for a causal relationship between hepatitis C and glucose abnormalities.4,6-8 This association is also potentially imperative as it may influence decision-making about which hepatitis C patients have to be treated based on considerations other than the severity of liver disease alone. Indeed, accumulating evidences are warning from the hepatic expression of the metabolic syndrome and insulin resistance, recently called “diabetic hepatopathy”.9

The study by Conjeevaram, et al.,10 addressed the effect of hepatitis C virus eradication on insulin resistance index. In a large cohort of 341 patients infected with genotype 1, peginterferon plus ribavirin therapy was associated with falling body weight and HOMA-IR, and these changes were more evident in patients with pre-existing insulin resistance before treatment. Resolution of hepatitis C infection resulted in sustained improvement in the HOMA-IR. Our group,4 in a cohort of 50 patients with chronic hepatitis C treated with pegylated interferon/ribavirin combination, HOMA1-IR was measured at the start, at 24 weeks of therapy and at 24 week follow-up after stopping therapy. We showed no improvement in HOMA values among non-responders and although HOMA index decreased in the responder group at 24 weeks, at 24 week follow-up the values returned to baseline among the relapser group, whereas in patients who achieved SVR, mean HOMA value was significantly lower compared to baseline. In 89 Japanese patients eradication of hepatitis C led to improvement of HOMA scores and intrahepatic expression of IRS-1 and IRS-2.6 Similar results in HOMA score changes were reported in a separate cohort including 181 genotype 4 patients.7 Thus, this study including the largest cohort confirmed previous results. Moreover, the study confirmed that baseline insulin resistance was associated with body mass index, triglycerides, fibrosis and steatosis and the sole factor associated with HOMA decline during and after therapy was baseline HOMA index demonstrating the higher HOMA the better decline, supporting the idea that the impact of HOMA on hepatitis C clearance was more evident in difficult to treat cohorts.11 Interestingly, 55% of patients reached normal insulin sensitivity between sustained responders at the end-of-follow-up, quite similar to the percentage of patients receiving peginterferon plus ribavirin and metformin12 at week 24 of therapy suggesting that in more than a half of patients insulin resistance was strongly related to hepatitis C.

A interesting point was the author’s choice to use HOMA2-IR model for assessment of IR, instead of the widely used model HOMA1-IR. In the light of these complex interplay relationship between insulin resistance and hepatitis C, the methods of measurement of insulin sensitivity gained more focus. Insulin resistance can be evaluated either by direct measurement of insulin-mediated glucose uptake (IMGU) or, alternatively, by surrogate estimation of IR. In the view of that, direct method is technically challenging.13 Focus has been directed on the simple and accessible measurement method for the evaluation of insulin sensitivity. To date, HOMA-IR has been the widely used model. HOMA is one of a family of “paradigm models”. This model is a structural computer model of the glucose insulin feedback system in the homeostatic state. The model consists of a number of nonlinear empirical equations describing the functions of organs and tissues involved in glucose regulation. HOMA1-IR was the first developed in 1985 by Matthews, et al.,14 HOMA1-IR = (glucose × insulin)/22.5. While; HOMA2IR is the correctly solved computer model,15 has a nonlinear solution. This updated version of the HOMA model accounts for variations in hepatic and peripheral glucose resistance, the insulin secretion curve has been modified to allow for an increase in insulin secretion in response to a plasma glucose concentration of > 10 mmol/l (180 mg/dL).16 This version incorporates an estimate of proinsulin secretion into the model and thus allows the use of either total (radioimmunoassay [RIA]) or specific insulin assays. Renal glucose losses have also been included in the model, thus allowing its use in hyperglycemic subjects.18 However, HOMA2IR still has the inconvenience that only a specific range of values are acceptable for calculation. In clinical practice, this limitation makes difficult the management of insulin results outside the limits and the need for a computer to run the program.17 HOMA2-IR was calculated using the computer-based solution of the model provided by the Diabetes Trials Unit, Oxford Center for Diabetes, Endocrinology and Metabolism found at the website: (http://www.dtu.ox.ac.uk/index.php7maindocWhoma/history.php). Up to date, there are no current clinical guidelines can answer many of the important concerns: the accurate method for assessment of insulin resistance, the optimal cut-off and the method of interpretation of HOMA, in the view of its complex interplay with many factors. Although theoretically the performance of HOMA2-IR seems to be better than the original one HOMA1-IR, the available data from the clinical studies failed to find that. In a Brazilian study, the HOMA1-IR showed an area under the receiver operating curve (AUC) higher than the area verified for the HOMA2-IR computer model, as discriminators of metabolic syndrome, but this difference did yielded statistical significance.18 In another study, HOMA1 and HOMA-2 measures identified similar patterns of increasing IR in the both older and younger people.19 Two recent studies confirmed HOMA1 and HOMA-2 were significantly associated with metabolic syndrome (odds ratio 5.7 and 4.2, respectively),20 and ROC curve for diagnosis of the metabolic syndrome showed that AUC for the HOMA1 and 2 methods were 0.741 and 0.680, respectively.21 Lastly, Conjeevaram et al used a cutoff value (> 2) for identifying insulin resistance, which is the same cutoff value used with HOMA1-IR. Although, there are no established reference values for assessing IR, using HOMA2-IR, the limited available data in the literature referee to that the cut-off value to detect impaired insulin sensitivity using HOMA2-IR is lower than that of HOMA1-IR and cutoff value has ranged from 1.4 to 1.8.20-22

This study opens future challenges. It is still unknown whether insulin resistance in hepatitis C setting invariably induces its deleterious effect metabolic syndrome-mediated only or it may be induced due to purely virus-induced insulin resistance, without the remaining constellation of cytokine changes that accompany the metabolic syndrome. This distinction may be especially crucial when antiviral therapy has to be undertaken; because here therapy should be aimed at correcting insulin resistance may need to be tolerated according to the underlying molecular mechanisms, which may differ according to the viral genotype and the presence or absence of metabolic syndrome.

In summary, this study adds evidence to the role of hepatitis C on insulin resistance and how curing hepatitis C insulin sensitivity improves. This bidirectional correlation between hepatitis C and insulin resistance, metabolic syndrome and type 2 diabetes remain a major concern and attract our attention to this evolving challenge.22

None Financial support: None Potential competing interests: None