• Top
• Abstract
• Background
• Conclusion
• Abbreviations
• Competing interests
• Authors' contributions
• Acknowledgements
• References

Review

HIV-associated adipose redistribution syndrome (HARS): definition, epidemiology and clinical impact

Kenneth Lichtenstein¹ , Ashok Balasubramanyam² , Rajagopal Sekhar² and Eric Freedland³

¹University of Colorado Infectious Disease Group Practice, Denver, CO, USA

²Translational Metabolism Unit, Division of Diabetes, Endocrinology and Metabolism, Baylor College of Medicine, Houston, TX, USA

³EMD Serono, Inc., Rockland, MA, USA

author email corresponding author email

AIDS Research and Therapy 2007, 4:16doi:10.1186/1742-6405-4-16

The electronic version of this article is the complete one and can be found online at: http://www.aidsrestherapy.com/content/4/1/16

Received:	26 February 2007
Accepted:	16 July 2007
Published:	16 July 2007

© 2007 Lichtenstein et al; licensee BioMed Central Ltd.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

A segment of the HIV infected population develops abnormal and excessive accumulation of adipose tissue in the trunk, including accumulation of visceral (deep abdominal) adipose tissue. This condition, known as HIV-related adipose redistribution syndrome (HARS), may also be accompanied by fat accumulation in the upper back/neck (dorsocervical region) and/or depletion of subcutaneous adipose tissue from the abdomen, face, limbs, or buttocks. HARS is estimated to occur in up to 32% of patients and is associated with health risks similar to those of metabolic syndrome. Techniques to detect and measure HARS include physician and patient assessments and radiologic or anthropometric methods.

Background

Effective antiretroviral therapy has reduced AIDS (acquired immune deficiency syndrome) mortality and dramatically increased longevity to the point that the long-term effects of HIV (human immunodeficiency virus) infection and treatment are manifesting themselves [1,2]. One particularly troublesome condition associated with long-term treatment of HIV/AIDS is an alteration of fat deposits in the body. In the late 1990s, reports of unusual changes in body fat distribution in HIV patients began to appear in the peer-reviewed literature [3-8].

Today, after almost a decade of study, the disturbance of fat metabolism in HIV-infected patients remains inadequately understood and controversial [9-12]. Abnormal accumulations of intra-abdominal fat [4,8,13-15], enlarged dorsocervical fat masses [6,16-18], and fat loss from the arms and legs, face, and buttocks [3,9,19-21] are the most visible signs of metabolic disturbance in HIV-infected patients with this syndrome. The term "lipodystrophy" is broad and is traditionally used to describe the several morphologic changes related to fat distribution, e.g. lipoatrophy (the loss of fat) and lipohypertrophy (fat accumulation). Both lipoatrophy and lipohypertrophy can occur separately or together in an individual.

In some HIV-infected patients, the body habitus changes are characterized by increases in trunk fat, including accumulation of visceral adipose tissue (VAT), which may present as abdominal obesity or (more rarely) dorsocervical fat accumulation ("buffalo hump"). The term HIV-associated adipose redistribution syndrome (HARS) has been used to describe this syndrome [22-27], even though it does not strictly represent "redistribution" of fat from one depot to another. The fat accumulation in HARS patients may be accompanied by other metabolic disturbances including insulin resistance, glucose intolerance, hypertension, and dyslipidemia, as well as by body image distress [24,28-30]. HARS may also be accompanied by lipoatrophy, typically involving loss of subcutaneous fat of the face, arms, legs, and/or buttocks. Although the combination of visceral adiposity and metabolic disturbances is not unique to HIV, the pathogenesis and clinical presentation appear to differ from those of "standard" obesity in the general population.

In this review, we address the following topics regarding central accumulation of fat in HIV-infected patients: HARS characterization and case definition; health risks associated with HARS; prevalence of HARS; signs of HARS and its relationship to highly active antiretroviral therapy (HAART), and HARS clinical presentation.

Lipohypertrophy and lipoatrophy: changing perspectives

Peripheral and central lipoatrophy affecting subcutaneous fat is often associated with HIV infection [9,12,31]. Although central fat accumulation was noted in early reports [5,7,16], appreciation of the clinical significance of HIV-associated fat accumulation has come slowly in studies of HIV-associated lipodystrophy.

There may be a number of reasons why fat accumulation has received less attention than peripheral lipoatrophy in the literature. Firstly, there appears to be a perception that fat loss is more common than fat accumulation [9,32]. Secondly, patients may report fat loss more readily to their physicians because of the undesirable cosmetic effects of fat loss from the face, buttocks and extremities [33]. Thirdly, the presence of obesity may confound the detection of HIV-associated accumulation of fat [34]. Fourthly, accumulation of VAT is not readily amenable to objective measurement in the clinical setting [35,36], and sophisticated imaging equipment is needed to visualize and specifically quantify HIV-associated accumulation of VAT [36].

The 1998 Advisory Committee of the International Association of Physicians in AIDS Care (IAPAC) estimated that approximately 1/3 of all treated HIV-infected patients show evidence of intra-abdominal (visceral) fat accumulation along with, or independent of, generalized obesity [8]. This observation coincided with the introduction of one of the first protease inhibitor (PI) drugs (indinavir) that may have contributed significantly to lipodystrophy with VAT accumulation [8]. In summary, HARS is a subset of HIV-associated lipodystrophy in which there is abnormal accumulation of trunk fat, including VAT, appearing with or without concurrent lipoatrophy of subcutaneous adipose tissue (SAT) in the limbs and face, or both. Between 5% and 10% of HARS patients exhibit dorsocervical fat accumulation [24].

To date, it has not been possible to bring the diverse observations of altered fat distribution and metabolism under the rubric of a single syndrome [32], and case definition remains a work in progress [37]. Without a clear definition of what constitutes a "case" of HIV lipodystrophy, the field will continue to be plagued by a wide variation in prevalence estimates, uncertainty about risk factors and indecision about proper course of treatment [38].

HARS case definition

Methodologic difficulties have plagued investigations of HIV lipodystrophy. Differing case definitions, reliance on detection methods with various levels of sensitivity and specificity, and enrollment of different patient populations have made it difficult to compare results across studies. A low level of agreement between clinical and patient assessments of fat redistribution has also contributed to the problem of clarifying the case definition [39]. Finally, the cross-sectional design of many studies is appropriate for generating hypotheses about the possible association of factors in lipodystrophy, but such studies cannot be used to identify causal relationships.

To resolve these ambiguities, the HIV Lipodystrophy Case Definition Study Group developed a statistical model for the diagnosis of lipodystrophy (including age, sex, duration of HIV infection, HIV disease stage, waist-to-hip ratio [WHR], anion gap, serum high-density lipoprotein-cholesterol [HDL-C] concentration, trunk-to-peripheral fat ratio, percentage leg fat, and intra- and extra-abdominal fat ratio as variables) with a quantitative scale for detecting cases [40,41]. The model efficiently captured cases of HIV lipodystrophy (70% sensitivity, 80% specificity), but this approach failed to develop a model specifically for peripheral fat loss or central fat gain.

In fact, this case-definition exercise deliberately excluded patients with moderate or severe "abdominal obesity" without lipoatrophy on the assumption that it was "age-related adiposity", and was thus biased against those with central fat accumulation or HARS. Nevertheless, regional fat accumulation was a prominent feature of the model with high scores for fat accumulation on the dorsocervical spine and abdominal region. There was no difference in body mass index between the cases and the comparison subjects (24.1 ± 3.7 vs 23.8 ± 3.8, P = 0.454). However, in cases of lipodystrophy, WHR was greater (0.95 ± 0.09 vs 0.91 ± 0.07, P < 0.001), intra-abdominal fat was greater (138 ± 88 cm² versus 97 ± 71 cm², P < 0.001), and the ratio of intra-to-extra-abdominal fat was dramatically greater (3.21 ± 9.87 vs 0.90 ± 1.16, P < 0.001) compared with controls.

Prevalence of HARS

In the Aquitaine Cohort (1999), in which 61% of the 581 patients were treated with PI, the overall incidence of fat maldistribution was 38% [42]. Some form of peripheral fat loss was observed in 90% of the patients, but 21% had increased abdominal girth and 10% of the patients had both peripheral fat loss and central fat accumulation. At least one metabolic abnormality was seen in 54% of patients; 51% of men and 45% of women had some form of lipid or glucose abnormality. These results led the authors of the Aquitaine study to suggest that there may be 3 separate presentations of lipodystrophy – fat atrophy, fat accumulation, and a mixed syndrome of both fat atrophy and accumulation [42].

A number of studies have consistently reported a significant proportion of patients with central fat accumulation: the Australian Prevalence Survey of Lipodystrophy Syndrome[43]the HIV Outpatient Study (HOPS) [44], the LIPOCO Study [45], the Norwegian patient survey [46], the Swiss cohort study [47], and the Australia cohort survey [43,48,49]. Safrin and Grunfeld (1999) surveyed reports of localized fat accumulation and loss in HIV-infected patients, and offered prevalence estimates of 1% to 56% for fat accumulation, 1% to 24% for regional loss of fat, and 2% to 83% for the pooled lipodystrophy syndromes [10].

Lichtenstein et al. reviewed 15 published surveys with >100 patients with descriptions suggestive of HARS [50]. They determined that prevalence estimates for HARS vary widely, from 9% [51] to 48% [52] (mean 32%), depending on the criteria used for assessment: increased abdominal girth, abdominal lipohypertrophy, abdominal enlargement, central or abdominal fat accumulation, truncal obesity, central fat gain, increased abdominal wall thickness, or pseudo-obesity. From a review of published, large cross-sectional and longitudinal studies, Tien and Grunfeld determined similar estimates [12]; for any lipodystrophy prevalence ranged from 30% to 62%, peripheral lipoatrophy from 22% to 38%, and any central fat accumulation from 18% to 45%. The highest estimates in the ranges reported by Tien and Grunfeld, however, all came from one study, relying on physical examination only and not on anthropometric or other objective measurements [53].

Fat redistribution and metabolic changes in HIV infection study

The Fat Redistribution and Metabolic Changes in HIV Infection Study (FRAM) was a large cross-sectional analysis of 425 HIV-infected and 152 HIV-negative men, age 33 to 45, in which lipoatrophy or lipohypertrophy were defined as concordance between subject report of the direction of fat change and results of the physical examination [9,31]. The objective of this study was to compare regional fat distribution (determined by self-report, physical examination and magnetic resonance imaging [MRI]) in HIV-positive men and population-based comparison subjects. Whereas previous studies evaluated only the presence of suspected changes, FRAM used bidirectional instruments (increase or decrease, as well as scales) to grade the magnitude of reported change as mild, moderate or severe.

The FRAM study found no correlation between changes in central fat and peripheral fat in HIV-infected men, measured either by self-report or physical examination [9,31]. In fact, the amount of central accumulation of fat was equivalent in HIV-infected men and comparison men without HIV, and peripheral fat loss did not necessarily correlate with central fat loss. The study authors concluded that central fat accumulation and peripheral fat loss are not reciprocal processes; there is probably no "relocation" of fat between these two depots.

The FRAM study results were somewhat controversial, however. The researchers did not control for body mass index and the HIV-negative control patients were significantly heavier than the HIV-infected patients. This may have contributed to the observation that increases in VAT were more common in the control patients [54]. Furthermore, FRAM was a cross-sectional study; longitudinal studies, such as ACTG 5005s (a substudy of ACTG 384), have demonstrated an increase in truncal adiposity with prolonged antiretroviral therapy [55]. In ACTG 5005s, the prevalence of a high WHR increased from 35% at baseline to 47% after 64 weeks of treatment with antiretrovirals. This moderate relative change underscores the importance of knowing baseline values. However, unlike FRAM, the ACTG studies did not include an HIV-negative control group, so the extent to which the WHR compares with age-matched HIV-negative controls is not clear.

The cross-sectional design of FRAM also does not shed light on how quickly VAT might have accumulated after a patient became infected with HIV or after initiating treatment with HAART. Follow-up data from FRAM are awaited with interest. With further study, perhaps the rate of VAT accumulation may help distinguish HARS from VAT accumulation related to general obesity.

Health risks associated with HARS

Physical symptoms associated with HARS primarily include bodily discomfort due to local accumulation of a large mass of VAT, with abdominal distension, respiratory difficulty (similar to Pickwickian syndrome), umbilical herniation, gastro-esophageal reflux, difficulty swallowing, abdominal cramping, peptic ulcer, and constipation or diarrhea [33]. It remains unknown if or how much the inflammation associated with HIV adds to or enhances the effects of increased VAT.

VAT: independent predictor of all cause mortality

Visceral fat has been demonstrated as an independent predictor of all causes of mortality in a recent study of 291 non-HIV-infected men [56]. In the evaluation of all three fat measures (subcutaneous, visceral and liver fat), age and length of follow-up, only visceral fat was a significant predictor of mortality in these non-HIV infected men [56]. The derangements of fat metabolism and fat storage seen in HARS may be similar to those seen in metabolic syndrome [57] which, according to U.S. Cholesterol Education Program Adult Treatment Panel III (ATP III), must include three of the following five criteria: increased waist circumference (>102 cm men, >88 cm women); increased triglycerides (>150 ng/dL); reduced HDL-C (<40 mg/dL men, <50 mg/dL women); high blood pressure (>130/>85 mmHg); and elevated fasting glucose (>110 mg/dL) [58].

This cluster of cardiovascular risk factors associated with metabolic syndrome, and the prothrombotic state associated with them, may predispose HIV-infected patients with HARS to premature cardiovascular disease [59].

Insulin resistance

VAT is an independent risk factor for insulin resistance [60]. When Goodpaster et al. (1999) examined the effects of weight loss on regional fat distribution and insulin sensitivity in the general population with obesity, they found that the reduction in VAT was the only adipose tissue parameter that predicted the improvement in insulin sensitivity [61].

An estimated 30% to 90% of patients receiving PI agents are insulin resistant, although the incidence of diabetes mellitus is less than 10% [62]. Lipodystrophy (peripheral lipoatrophy and/or lipohypertrophy) is associated with hyperinsulinemia and insulin resistance [13,63,64]. The dorsocervical fat pad or "buffalo hump" has also been associated with insulin resistance in an analysis of two separate studies involving 1765 HIV-infected patients [65]. In addition, impaired glucose tolerance is part of the spectrum of metabolic changes seen in patients taking antiretroviral therapy [29]. The direct effects of PI and nucleoside reverse transcriptase inhibitor agents, and the indirect effects of visceral adiposity and peripheral fat loss, with fatty infiltration of muscle and liver, account in part for the insulin resistance seen in the HIV-infected population [66].

Cardiovascular risks

Cohort studies suggest that patients with HIV already face an increased risk of acute myocardial infarction (MI) compared with matched non-HIV-infected controls [59,67,68]. In the subset of patients with HARS, the metabolic consequences of fat deposition may further increase cardiovascular risk [59,68,69], although HIV patients tend also to have high rates of other cardiovascular risk factors relative to age-matched HIV-negative individuals, including diabetes, hypertension and dyslipidemia [67]. In addition, protease inhibitor use is a strong predictor of MI in HIV-infected patients [70].

Waist-hip ratio and cardiovascular disease risk

WHR is an integrated index of body-composition changes that reflects VAT stores. It is significantly related to cardiovascular disease risk in the general population [71] and strongly predicts both fasting hyperinsulinemia and insulin levels in both HIV-infected and -negative individuals [28,72]. However, the extent to which WHR is a predictor of cardiovascular disease in HIV has not yet been established, especially since the WHR in HIV may be increased by a low hip circumference (from lipoatrophy) in addition to an increased waist circumference.

A recent study investigated cardiovascular disease risk indices in 100 consecutively recruited HIV-infected women and 75 healthy female control subjects [28]. HIV-infected women had more VAT and less extremity fat by computerized tomography (CT) and dual-energy x-ray absorptiometry (DXA) scan and demonstrated a higher WHR than the control population. Among all subjects, WHR, but not HIV status, was significantly related to high levels of C-reactive protein and other cardiovascular disease risk indices. This could suggest that VAT (as indicated by WHR) is accounting for most of the cardiovascular disease risk in both the HIV-positive and HIV-negative cohorts. However, an earlier study found the coronary heart disease risk estimate was greatest in HIV-infected patients who had primary lipoatrophy, compared with those who had either lipohypertrophy or mixed fat redistribution [73].

The ACTG 362 study group found higher-than-normal risk of cardiovascular disease among patients with HAART-induced immune reconstitution, many of whom had lipodystrophy [74]. The rate of atherosclerotic cardiovascular disease was 7.2 events per 1000 person-years (18 of 643 patients). These 18 patients experienced 20 atherosclerotic cardiovascular events (10 myocardial infarctions, 3 symptomatic coronary heart disease). Of 433 subjects who agreed to remain in follow-up for evaluating risks of cardiovascular disease and metabolic syndrome, 21% of the men and 38% of the women had signs of metabolic syndrome, 31% had a WHR 0.95 to 1.00, and 21% had WHR >1.00.

In a multicenter study of 788 HIV patients, Samaras et al. found the prevalence of metabolic syndrome was 14% by International Diabetes Federation criteria and 18% by ATP III [75]. Many of these patients (49%) had at least two features of metabolic syndrome (particularly elevated lipids) but did not meet the waist circumference or WHR cutoff criteria for metabolic syndrome [75]. It may be that the waist circumference and WHR criteria for the International Diabetes Federation and the ATP III definitions of metabolic syndrome are set too high and are too insensitive for maximal detection of cardiovascular and diabetic risk in HIV-infected adults [76]. In various general populations and ethnic groups, the optimal criteria for identifying high risk abdominally obese patients (with excess VAT) remains unclear [77].

Systemic steatosis, e.g. hepatic and intramyocellular fat accumulation

Comorbid liver disease is common in patients with HIV, and the presence of fatty liver may be caused and/or exacerbated by concomitant hepatitis virus infection, use of certain antiretroviral drugs, chronic inflammation and metabolic derangements [78].

Fatty liver, as well as VAT, in non-HIV individuals is related to metabolic risk factors such as dyslipidemia, insulin resistance and inflammatory markers [79,80]. Similarly, patients with HIV and dyslipidemia have increased insulin resistance, and greater amounts of intrahepatic fat and VAT compared to HIV patients without dyslipidemia or normal controls even when total body fat mass is comparable [81]. The insulin resistance impairs insulin from suppressing lipolysis of triglycerides in SAT stores leading to increased release of free fatty acids. These could contribute to expanded VAT stores, which in turn, can release free fatty acids into the portal circulation (Table 1). The increase in free fatty acids in the portal circulation could lead to a net retention of lipid in the hepatocytes or steatosis, which in turn could contribute to systemic insulin resistance [81,82]. In addition, free fatty acid oxidation stimulates gluconeogenesis and hepatic glucose output and thus favors insulin resistance [83]. This is consistent with data showing that, in patients with HIV lipodystrophy, the severity of insulin resistance is related to the accumulation of fat in the liver rather than to the accumulation of intra-abdominal fat [84].

Excess systemic free fatty acids can also find their way to other tissues. Luzi et al. found that triglyceride levels within the myocytes of the soleus and tibialis anterior muscles were significantly elevated in HIV-positive patients compared with healthy controls [85]. This increased accumulation of fat in skeletal muscle of patients with HIV and lipodystrophy is associated with insulin resistance; there was an inverse relationship between insulin action and intramyocellular lipid content.

Psychosocial effects of HARS

Patient-reported health-related quality-of-life issues associated with abnormal fat distribution in HIV-positive patients came to the attention of investigators early [86]. Changes in body shape stigmatize patients [87] and may interfere with treatment adherence [88]. In addition, patients' anxieties regarding long-term skeletal and cardiovascular risks can interfere with treatment decisions [89]. Although it is difficult to isolate the effect of body habitus changes alone on quality of life in HIV patients [90], significant body image distress is associated with adipose tissue maldistribution [30].

Signs of HARS

Patients with HARS tend to exhibit excess visceral adiposity without increased total body fat, and have more VAT than non-obese HIV-negative people with similar height-adjusted weight [91]. Patients exhibiting signs of HARS also may have a higher WHR, trunk-to-limb fat ratio, and VAT/SAT ratio [36] than would be expected from their body mass index [92]. HIV-infected patients with truncal enlargement had 2.5–4 times more VAT on MRI scan [4] and 4 times more VAT on single-slice CT scan than healthy control subjects of similar age, sex and height. Engelson and colleagues found that VAT volumes could be quite large in HARS patients, and ranged from 2.1–9.8 L in HIV-positive men with truncal obesity compared with 0.3–1.7 L (P < 0.001) in HIV-positive comparison patients without truncal enlargement [4]. Men with truncal enlargement had 6.5 times more VAT than men without truncal enlargement [4].

Extra-abdominal fat accumulation

HARS patients may also exhibit fat accumulation at extra-abdominal sites (e.g. "buffalo hump") [6], and patients exhibiting excess dorsocervical fat are likely to have abnormal truncal fat accumulation as well [18,65]. In an analysis of data from two cross-sectional cohort studies of patients with HIV-associated lipodystrophy, all of the patients with "buffalo hump" also reported central fat accumulation, and 97% to 100% reported facial or buttock lipoatrophy [65]. In multivariate analysis, blood pressure and insulin levels were both significantly associated with the presence of a buffalo hump (P ≤ 0.007), as was duration of ritonavir (P = 0.004) or zidovudine (P = 0.005) use. This particular form of fat accumulation is often very troublesome for patients, who may develop sleep difficulties, snoring or sleep apnea [93], as well as limited range of upper extremity and neck motion, neck and back discomfort [93,94]. In addition to buffalo hump, patients may also develop lipomas, which they often find disfiguring [93].

In a cross-sectional analysis in 582 lipodystrophic patients with HIV, the prevalence of suprapubic lipomas was 9.4%, but these lipomas were more common in patients with dorsocervical fat deposition (18.5%), suggesting a common pathogenesis between these two entities [95]. Other risk factors for pubic lipomas were female gender, obesity (body mass index ≥ 30) and shorter duration of HIV infection.

Detection of HARS

Body measurement of patients with fat redistribution syndrome is fraught with difficulties [96-99]. Studies of HIV lipodystrophy have relied on several different means of detecting and measuring changes in body shape: self-report by means of questionnaires, scales for tabulating clinicians' observations on physical examination, anthropometric formulas, and radiographic techniques. Self-report and questionnaires are open to subjective bias. In general, levels of agreement (tested by kappa statistic) between subjective measures have been poor [39].

Because HARS is marked by depots of VAT rather than SAT, the condition may not always be evident on inspection or physical examination. In patients with mixed lipodystrophy, the decrease in truncal SAT (lipoatrophy) may contribute to a smaller than expected increase in waist circumference or WHR and thus lead to underestimation of the amount of VAT [100]. The 4-year Multicenter AIDS Cohort Study (MACS) suggested that, in at least some HAART recipients, an increase in WHR could be attributed to a relatively lower increase in hip circumference rather than an increased rate of change in waist circumference [101]. Visual inspection on physical exam in some HARS patients may reveal abdominal distension as VAT pushes the abdominal musculature forward [102]. In these, there may be a lack of flabbiness or pinchable subcutaneous fat stretched over a taut abdomen. However, other HARS patients may present with large bellies that are difficult to differentiate from general obesity.

Standard anthropometric tests have the advantage of being readily available to clinicians [103,104]. Anthropometric criteria, based on waist circumference and/or WHR, have been used to estimate the relative mass of visceral fat [24,105,106]. Some studies have applied a composite criterion of waist circumference >88 cm and WHR ≥ 0.95 for men, plus waist circumference >75 and WHR ≥ 0.90 for women to effectively detect HIV-infected patients with high VAT content [24,35,107,108]. These cutoffs for WHR were based on published anthropometric criteria considered to define visceral adiposity and increased cardiovascular risk in adults [106,109]. As mentioned earlier, WHR data may be misleading, especially if a patient has a normal waist but massive loss of fat and muscle from the hips and buttocks. Thus, in order to exclude patients with apparently high WHR due to such dramatically reduced hip circumference, a minimum waist circumference >88.2 cm was set for males and >75.3 cm for females [24]. While these criteria should be subjected to independent validation, it has been suggested that they may be conservative [108].

The most sensitive and specific methods for the detection of VAT are CT scan and MRI because they provide quantifiable data on the location and mass of visceral fat and SAT [110]. DXA is sensitive and produces results within acceptable variability for measuring the subcutaneous fat of the appendages (SAT), but is more difficult for estimation of VAT since changes in SAT and VAT independently affect the mass of truncal fat [111]. Limitations of these methods include: expense and limited availability; radiation exposure associated with CT scan, limit to single-slice and not whole-body studies; few data exist on normal distribution of VAT and SAT, so it is difficult to make comparisons; subcompartments of SAT and VAT are not homogeneous, so whole-body estimates may be simplistic.

Useful as these radiologic techniques are, CT, MRI and DXA instruments are too expensive to be practical for the identification of HARS patients in routine clinical practice. Routine measurement of waist circumference and/or WHR may be helpful and are recommended for all patients as it enhances diagnostic sensitivity for cardiovascular risk factors [112].

Conclusion

Body habitus changes resulting from either lipoatrophy or lipohypertrophy, or both, have been combined under a single syndrome known as lipodystrophy. HARS is a specific form of HIV-associated lipodystrophy characterized by abnormal accumulation of trunk fat, including VAT, and may appear with or without concurrent lipoatrophy of SAT. The best current prevalence estimate for HARS is up to 32% of HIV-infected patients. In addition to disfiguring the patient's appearance (enlarged abdomen, "buffalo hump," perhaps exacerbated by peripheral lipoatrophy), HARS is associated with metabolic disorders and health risk factors similar to those of metabolic syndrome. A more precise definition of HARS will require a consensus statement inclusive of clinical manifestations and symptoms. Further research in this area is necessary to understand this complex condition.

Abbreviations

ACTG AIDS Clinical Trials Group

AIDS Acquired immunodeficiency syndrome

ATP III U.S. Cholesterol Education Program Third Adult Treatment Panel

CT Computerized tomography

DXA Dual-energy x-ray absorptiometry

FRAM Fat Redistribution and Metabolic Changes in HIV Infection

HAART Highly active antiretroviral therapy

HARS HIV-associated adipose redistribution syndrome

HDL-C High density lipoprotein cholesterol

HIV Human immunodeficiency virus

HOPS HIV Outpatient Study

IAPAC International Association of Physicians in AIDS Care

MACS Multicenter AIDS Cohort Study

MI Myocardial infarction

MRI Magnetic resonance imaging

PI Protease inhibitor

SAT Subcutaneous adipose tissue

VAT Visceral adipose tissue

WHR Waist:hip ratio

Competing interests

Dr. Eric Freedland is currently an employee of EMD Serono, Inc. EMD Serono, Inc. holds rights to Serostim^® [somatropin (rDNA origin) for injection], a brand of recombinant human growth hormone, which has been submitted to the FDA for approval for the treatment of HARS. Dr. Balasubramanyam and Dr. Sekhar have received honoraria for consultative meetings with EMD Serono regarding the possible use of growth hormone to treat HIV lipodystrophy. The present manuscript does not discuss growth hormone treatment of HIV lipodystrophy in this condition. Dr. Lichtenstein has nothing to disclose.

Authors' contributions

All authors were involved in drafting the manuscript and provided extensive comments and review. All authors performed analysis and interpretation of data. All authors have read and approved the final manuscript.

Acknowledgements

Financial support was provided by EMD Serono, Inc. We thank Adi Reddy, MD for incorporating the authors' comments throughout the development of this manuscript. Dr. Balasubramanyam acknowledges the National Institutes of Health for grant support (R01-HL73696).

References

1. Garcia-Viejo MA, Ruiz M, Martinez E: Strategies for treating HIV-related lipodystrophy.

   Expert Opin Investig Drugs 2001, 10:1443-1456. PubMed Abstract | Publisher Full Text

2. Powderly WG: Long-term exposure to lifelong therapies.

   J Acquir Immune Defic Syndr 2002, 29(Suppl 1):S28-40. PubMed Abstract | Publisher Full Text

3. Carr A, Samaras K, Burton S, Law M, Freund J, Chisholm DJ, Cooper DA: A syndrome of peripheral lipodystrophy, hyperlipidaemia and insulin resistance in patients receiving HIV protease inhibitors.

   AIDS 1998, 12:F51-58. PubMed Abstract | Publisher Full Text

4. Engelson ES, Kotler DP, Tan Y, Agin D, Wang J, Pierson RN Jr, Heymsfield SB: Fat distribution in HIV-infected patients reporting truncal enlargement quantified by whole-body magnetic resonance imaging.

   Am J Clin Nutr 1999, 69:1162-1169. PubMed Abstract | Publisher Full Text

5. Herry I, Bernand L, de Truchis P, Perronn C: Hypertrophy of the breasts in a patient treated with indinavir.

   Clin Infect Dis 1997, 25:937-938. PubMed Abstract

6. Lo JC, Mulligan K, Tai VW, Algren H, Schambelan M: "Buffalo hump" in men with HIV-1 infection.

   Lancet 1998, 351:867-870. PubMed Abstract | Publisher Full Text

7. Massip P, Marchou B, Bonnet E, Cuzin L, Montastruc JL: Lipodystrophia with protease inhibitors in HIV patients.

   Therapie 1997, 52:615. PubMed Abstract

8. Miller KD, Jones E, Yanovski JA, Shankar R, Feuerstein I, Falloon J: Visceral abdominal-fat accumulation associated with use of indinavir.

   Lancet 1998, 351:871-875. PubMed Abstract | Publisher Full Text

9. Bacchetti P, Gripshover B, Grunfeld C, Heymsfield S, McCreath H, Osmond D, Saag M, Scherzer R, Shlipak M, Tien P: Fat distribution in men with HIV infection.

   J Acquir Immune Defic Syndr 2005, 40:121-131. PubMed Abstract | Publisher Full Text

10. Safrin S, Grunfeld C: Fat distribution and metabolic changes in patients with HIV infection.

    AIDS 1999, 13:2493-2505. PubMed Abstract | Publisher Full Text

11. Sattler F: Body habitus changes related to lipodystrophy.

    Clin Infect Dis 2003, 36:S84-90. PubMed Abstract | Publisher Full Text

12. Tien PC, Grunfeld C: What is HIV-associated lipodystrophy? Defining fat distribution changes in HIV infection.

    Curr Opin Infect Dis 2004, 17:27-32. PubMed Abstract | Publisher Full Text

13. Freedland ES: Role of a critical visceral adipose tissue threshold (CVATT) in metabolic syndrome: implications for controlling dietary carbohydrates: a review.

    Nutr Metab (Lond) 2004, 1:12. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text

14. Vigano A, Mora S, Manzoni P, Schneider L, Beretta S, Molinaro M, di Natale B, Brambilla P: Effects of recombinant growth hormone on visceral fat accumulation: pilot study in human immunodeficiency virus-infected adolescents.

    J Clin Endocrinol Metab 2005, 90:4075-4080. PubMed Abstract | Publisher Full Text

15. Yin MT, Glesby MJ: Recombinant human growth hormone therapy in HIV-associated wasting and visceral adiposity.

    Expert Rev Anti Infect Ther 2005, 3:727-738. PubMed Abstract | Publisher Full Text

16. Roth VR, Kravcik S, Angel JB: Development of cervical fat pads following therapy with human immunodeficiency virus type 1 protease inhibitors.

    Clin Infect Dis 1998, 27:65-67. PubMed Abstract | Publisher Full Text

17. Torres RA, Unger KW, Cadman JA, Kassous JY: Recombinant human growth hormone improves truncal adiposity and 'buffalo humps' in HIV-positive patients on HAART.

    AIDS 1999, 13:2479-2481. PubMed Abstract | Publisher Full Text

18. Zolopa A, Benson C, Bacchetti P, Tien PC, Grunfeld C: Buffalo hump in men with HIV Infection: Larger, but not more common.

    10th Conference on Retroviruses and Opportunistic Infections: Incidence, Prevalence, and Impact of Body Composition Abnormalities; Boston, MA 2003.

19. Lichtenstein KA, Delaney KM, Armon C, Ward DJ, Moorman AC, Wood KC, Holmberg SD: Incidence of and risk factors for lipoatrophy (abnormal fat loss) in ambulatory HIV-1-infected patients.

    J Acquir Immune Defic Syndr 2003, 32:48-56. PubMed Abstract | Publisher Full Text

20. Martin A, Mallon PW: Therapeutic approaches to combating lipoatrophy: do they work?

    J Antimicrob Chemother 2005, 55:612-615. PubMed Abstract | Publisher Full Text

21. Parruti G, Toro GM: Persistence of lipoatrophy after a four-year long interruption of antiretroviral therapy for HIV1 infection: case report.

    BMC Infect Dis 2005, 5:80. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text

22. Fliers E, Sauerwein HP, Romijn JA, Reiss P, van der Valk M, Kalsbeek A, Kreier F, Buijs RM: HIV-associated adipose redistribution syndrome as a selective autonomic neuropathy.

    Lancet 2003, 362:1758-1760. PubMed Abstract | Publisher Full Text

23. Grunfeld C, Thompson M, Brown SJ, Richmond G, Lee D, Muurahainen N, Kotler DP: Recombinant Human Growth Hormone to Treat HIV-Associated Adipose Redistribution Syndrome: 12-Week Induction and 24-Week Maintenance Therapy.

    J Acquir Immune Defic Syndr 2007, 45:286-297. PubMed Abstract | Publisher Full Text

24. Kotler DP, Muurahainen N, Grunfeld C, Wanke C, Thompson M, Saag M, Bock D, Simons G, Gertner JM: Effects of growth hormone on abnormal visceral adipose tissue accumulation and dyslipidemia in HIV-infected patients.

    J Acquir Immune Defic Syndr 2004, 35:239-252. PubMed Abstract | Publisher Full Text

25. Kotler DP, Muurahainen N, Grunfeld C, Wanke C, Thompson M, Saag M, Bock D, Simons G, Gertner JM: Effects of growth hormone on visceral adipose tissue and dyslipidemia in HIV, an erratum.

    J Acquir Immune Defic Syndr 2006, 43:378-380. PubMed Abstract | Publisher Full Text

26. Pond CM: Long-term changes in adipose tissue in human disease.

    Proc Nutr Soc 2001, 60:365-374. PubMed Abstract | Publisher Full Text

27. van Gurp PJ, Tack CJ, van der Valk M, Reiss P, Lenders JW, Sweep FC, Sauerwein HP: Sympathetic nervous system function in HIV-associated adipose redistribution syndrome.

    AIDS 2006, 20:773-775. PubMed Abstract | Publisher Full Text

28. Dolan SE, Hadigan C, Killilea KM, Sullivan MP, Hemphill L, Lees RS, Schoenfeld D, Grinspoon S: Increased cardiovascular disease risk indices in HIV-infected women.

    J Acquir Immune Defic Syndr 2005, 39:44-54. PubMed Abstract | Publisher Full Text

29. Hadigan C, Meigs JB, Corcoran C, Rietschel P, Piecuch S, Basgoz N, Davis B, Sax P, Stanley T, Wilson PW, et al.: Metabolic abnormalities and cardiovascular disease risk factors in adults with human immunodeficiency virus infection and lipodystrophy.

    Clin Infect Dis 2001, 32:130-139. PubMed Abstract | Publisher Full Text

30. Turner R, Testa MA, Su M, Richmond G, Muurahainen N, Kotler DP, Thompson M: The impact of HIV-associated adipose redistribution syndrome (HARS) on health-related quality of life.

    Antiviral Therapy 2006, 11:L25.

31. Gripshover B, Tien PC, Saag M, Osmond D, Bacchetti P, Grunfeld C: Lipoatrophy is the Dominant Feature of the Lipodystrophy Syndrome in HIV-infected Men.

    Conf Retrovir Oppor Infect 2003.

32. Carr A: HIV lipodystrophy: risk factors, pathogenesis, diagnosis and management.

    AIDS 2003, 17(Suppl 1):S141-148. PubMed Abstract | Publisher Full Text

33. Engelson ES: HIV lipodystrophy diagnosis and management. Body composition and metabolic alterations: diagnosis and management.

    AIDS Read 2003, 13:S10-14. PubMed Abstract

34. Mondy K, Tong S, Kessels L, Powderly W, Overton E: Metabolic Syndrome in HIV within a Representative US patient Population.

    13th Conference on Retroviruses and Opportunistic Infections: Metabolic Syndrome and Other Abnormalities of Fat, Lipid, Glucose and Bone Metabolism. Denver, CO 2006.

35. Kotler D, Engelson E, Heymsfield S, Chang P, Muurahainen N, Gertner J: Anthropometric Criteria define visceral fat excess in patients with HIV-associated adipose redistribution syndrome (HARS), a subset of HIV lipodystrophy (abstract).

    9th Conference on Retroviruses and Opportunistic Infections: Incidence, Prevalence, and Pathogenic Correlates of Insulin Resistance and Lipodystrophy Syndrome, Seattle, WA 2002.

36. Kotler DP, Muurahainen N, Chang P, Engelson ES, Wang J, Heymsfield SB, Gertner JM: Anthropometric equations select HIV+ men and women with distinctly abnormal fat accumulation and distribution.

    Int Conf AIDS; 2002 Jul 7-12;14:(abstract no. WePeB5997) 2002.

37. Wanke C: Editorial comment: a case definition for HIV lipodystrophy – a work in progress.

    AIDS Read 2003, 13:492-493. PubMed Abstract

38. Benavides S, Nahata MC: Pharmacologic therapy for HIV-associated lipodystrophy.

    Ann Pharmacother 2004, 38:448-457. PubMed Abstract | Publisher Full Text

39. Belloso WH, Quiros RE, Ivalo SA, Perman MI, Galich AM, Stern LD, Barcan LA: Agreement analysis of variables involved in lipodystrophy syndrome definition in HIV-infected patients.

    J Acquir Immune Defic Syndr 2003, 32:104-111. PubMed Abstract | Publisher Full Text

40. Carr A, Emery S, Law M, Puls R, Lundgren JD, Powderly WG: An objective case definition of lipodystrophy in HIV-infected adults: a case-control study.

    Lancet 2003, 361:726-735. PubMed Abstract | Publisher Full Text

41. Carr A, Law M, HIV Lipodystrophy Case Definition Study Group : An objective lipodystrophy severity grading scale derived from the lipodystrophy case definition score.

    J Acquir Immune Defic Syndr 2003, 33:571-576. PubMed Abstract | Publisher Full Text

42. Thiebaut R, Daucourt V, Mercie P, Ekouevi DK, Malvy D, Morlat P, Dupon M, Neau D, Farbos S, Marimoutou C, Dabis F: Lipodystrophy, metabolic disorders, and human immunodeficiency virus infection: Aquitaine Cohort, France, 1999. Groupe d'Epidemiologie Clinique du Syndrome d'Immunodeficience Acquise en Aquitaine.

    Clin Infect Dis 2000, 31:1482-1487. PubMed Abstract | Publisher Full Text

43. Miller JE, Emery S, French M, Baker D, Cooper DA: The Australian prevalence survey of lipodystrophy.

    7th Conference on Retroviruses and Opportunistic Infections. San Francisco, CA; 2000 2000.

44. Ward DJ, Delaney KM, Moorman AC, Lichtenstein K, Palella F, Young B, Wood KC, Holmberg SD: Description of lipodystrophy in the HIV outpatient study (HOPS).

    Antiviral Therapy 1999., 4(Suppl 2):PubMed Abstract

45. Saint-Marc T, Partisani M, Poizot-Martin I, Rouviere O, Bruno F, Avellaneda R, Lang JM, Gastaut JA, Touraine JL: Fat distribution evaluated by computed tomography and metabolic abnormalities in patients undergoing antiretroviral therapy: preliminary results of the LIPOCO study.

    AIDS 2000, 14:37-49. PubMed Abstract | Publisher Full Text

46. Bergersen BM, Sandvik L, Bruun JN: Body composition changes in 308 Norwegian HIV-positive patients.

    Scand J Infect Dis 2004, 36:186-191. PubMed Abstract | Publisher Full Text

47. Bernasconi E, Boubaker K, Junghans C, Flepp M, Furrer HJ, Haensel A, Hirschel B, Boggian K, Chave JP, Opravil M, et al.: Abnormalities of body fat distribution in HIV-infected persons treated with antiretroviral drugs: The Swiss HIV Cohort Study.

    J Acquir Immune Defic Syndr 2002, 31:50-55. PubMed Abstract | Publisher Full Text

48. Miller J, Brown D, Amin J, Kent-Hughes J, Law M, Kaldor J, Cooper DA, Carr A: A randomized, double-blind study of gemfibrozil for the treatment of protease inhibitor-associated hypertriglyceridaemia.

    AIDS 2002, 16:2195-2200. PubMed Abstract | Publisher Full Text

49. Miller J, Carr A, Emery S, Law M, Mallal S, Baker D, Smith D, Kaldor J, Cooper DA: HIV lipodystrophy: prevalence, severity and correlates of risk in Australia.

    HIV Med 2003, 4:293-301. PubMed Abstract | Publisher Full Text

50. Lichtenstein K, Wanke C, Henry K, Thompson M, Muurahainen N, Kotler DP: Estimated Prevalence of HIV-associated adipose redistribution syndrome (HARS) – abnormal abdominal fat accumulation – in HIV-infected patients.

    Antiviral Therapy 2004, 9:L33.

51. Paparizos VA, Kyriakis KP, Polydorou-Pfandl D, Hadjivassiliou M, Stavrianeas NG: Epidemiologic characteristics of Koebner's phenomenon in AIDS-related Kaposi's sarcoma.

    J Acquir Immune Defic Syndr 2000, 25:283-284. PubMed Abstract | Publisher Full Text

52. Rozenbaum W, Gharakhanian S, Salhi Y, Adda N, Nguyen T, Vigouroux C, Capeau J:

    Antivir Ther. 1999, 4(Suppl 2):L34.

53. Saves M, Raffi F, Capeau J, Rozenbaum W, Ragnaud JM, Perronne C, Basdevant A, Leport C, Chene G: Factors related to lipodystrophy and metabolic alterations in patients with human immunodeficiency virus infection receiving highly active antiretroviral therapy.

    Clin Infect Dis 2002, 34:1396-1405. PubMed Abstract | Publisher Full Text

54. Kotler D: Update from the 7th international workshop on adverse drug reactions and lipodystrophy in HIV.

    The PRN Notebook 2006, 11:16-21.

55. Mulligan K, Parker R, Komarow L, Tebas P, Grinspoon S, Robbins G, Dube M, ACTG 5005S and 384 Study Teams: Mixed patterns of changes in central and peripheral fat following initiation of ART.

    12th Conference on Retroviruses and Opportunistic Infections, Boston, MA; 2005. 2005.

56. Kuk JL, Katzmarzyk PT, Nichaman MZ, Church TS, Blair SN, Ross R: Visceral Fat Is an Independent Predictor of All-cause Mortality in Men.

    Obesity (Silver Spring) Research 2006, 14:336-341.

57. Grunfeld C, Tien P: Difficulties in understanding the metabolic complications of acquired immune deficiency syndrome.

    Clin Infect Dis 2003, 37(Suppl 2):S43-46. PubMed Abstract | Publisher Full Text

58. NCEP: Executive Summary of The Third Report of The National Cholesterol Education Program (NCEP) Expert Panel on Detection, Evaluation, And Treatment of High Blood Cholesterol In Adults (Adult Treatment Panel III).

    JAMA 2001, 285:2486-2497. PubMed Abstract | Publisher Full Text

59. Wohl DA: Body shape, lipid, and cardiovascular complications of HIV therapy.

    Curr HIV/AIDS Rep 2005, 2:74-82. PubMed Abstract | Publisher Full Text

60. Lebovitz HE, Banerji MA: Point: visceral adiposity is causally related to insulin resistance.

    Diabetes Care 2005, 28:2322-2325. PubMed Abstract | Publisher Full Text

61. Goodpaster BH, Kelley DE, Wing RR, Meier A, Thaete FL: Effects of weight loss on regional fat distribution and insulin sensitivity in obesity.

    Diabetes 1999, 48:839-847. PubMed Abstract | Publisher Full Text

62. Calza L, R M, F C: Insulin resistance and diabetes mellitus in HIV infected patients receiving antiretroviral therapy.

    Metabolic Syndrome and Related Disorders 2004, 2:241-250. Publisher Full Text

63. Balasubramanyam A, Sekhar RV, Jahoor F, Jones PH, Pownall HJ: Pathophysiology of dyslipidemia and increased cardiovascular risk in HIV lipodystrophy: a model of 'systemic steatosis'.

    Curr Opin Lipidol 2004, 15:59-67. PubMed Abstract | Publisher Full Text

64. Hadigan C, Kamin D, Liebau J, Mazza S, Barrow S, Torriani M, Rubin R, Weise S, Fischman A, Grinspoon S: Depot-specific regulation of glucose uptake and insulin sensitivity in HIV-lipodystrophy.

    Am J Physiol Endocrinol Metab 2006, 290:E289-298. PubMed Abstract | Publisher Full Text

65. Mallon PW, Wand H, Law M, Miller J, Cooper DA, Carr A, HIV Lipodystrophy Case Definition Study; Australian Lipodystrophy Prevalence Survey Investigators: Buffalo hump seen in HIV-associated lipodystrophy is associated with hyperinsulinemia but not dyslipidemia.

    J Acquir Immune Defic Syndr 2005, 38:156-162. PubMed Abstract | Publisher Full Text

66. Shikuma CM, Day LJ, Gerschenson M: Insulin resistance in the HIV-infected population: the potential role of mitochondrial dysfunction.

    Curr Drug Targets Infect Disord 2005, 5:255-262. PubMed Abstract | Publisher Full Text

67. Triant VA, Lee H, Hadigan C, Grinspoon SK: Increased Acute Myocardial Infarction Rates and Cardiovascular Risk Factors Among Patients with HIV Disease.

    J Clin Endocrinol Metab 2007, 92:2506-2512. PubMed Abstract | Publisher Full Text

68. Tanwani LK, Mokshagundam SL: Lipodystrophy, insulin resistance, diabetes mellitus, dyslipidemia, and cardiovascular disease in human immunodeficiency virus infection.

    South Med J 2003, 96:180-188. PubMed Abstract | Publisher Full Text

    quiz 189.

69. Henry K, Melroe H, Huebsch J, Hermundson J, Levine C, Swensen L, Daley J: Severe premature coronary artery disease with protease inhibitors.

    Lancet 1998, 351:1328. PubMed Abstract | Publisher Full Text

70. Friis-Moller N, Reiss P, Sabin CA, Weber R, Monforte A, El-Sadr W, Thiebaut R, De Wit S, Kirk O, Fontas E, et al.: Class of antiretroviral drugs and the risk of myocardial infarction.

    N Engl J Med 2007, 356:1723-1735. PubMed Abstract | Publisher Full Text

71. Yusuf S, Hawken S, Ounpuu S, Bautista L, Franzosi MG, Commerford P, Lang CC, Rumboldt Z, Onen CL, Lisheng L, et al.: Obesity and the risk of myocardial infarction in 27,000 participants from 52 countries: a case-control study.

    Lancet 2005, 366:1640-1649. PubMed Abstract | Publisher Full Text

72. Meininger G, Hadigan C, Rietschel P, Grinspoon S: Body-composition measurements as predictors of glucose and insulin abnormalities in HIV-positive men.

    Am J Clin Nutr 2002, 76:460-465. PubMed Abstract | Publisher Full Text

73. Hadigan C, Meigs JB, Wilson PW, D'Agostino RB, Davis B, Basgoz N, Sax PE, Grinspoon S: Prediction of coronary heart disease risk in HIV-infected patients with fat redistribution.

    Clin Infect Dis 2003, 36:909-916. PubMed Abstract | Publisher Full Text

74. Williams P, Wu J, Cohn S, Koletar S, McCutchan J, Murphy R, Currier J: Risk of Cardiovascular Disease in HIV-infected adults with immune reconstitution.

    12th Conference on Retroviruses and Opportunistic Infections. Boston, MA; 2005. 2005., 12:

75. Samaras K, Wand H, Law M, Emery S, Cooper D, Carr A: Prevalence of Metabolic Syndrome in HIV-Infected Patients Receiving Highly Active Antiretroviral Therapy Using International Diabetes Foundation and Adult Treatment Panel III Criteria: Associations with insulin resistance, disturbed body fat compartmentalization, elevated C-reactive peptide, and hypoadiponectinemia.

    Diabetes Care 2007, 30:113-119. PubMed Abstract | Publisher Full Text

76. Samaras K, Wand H, Law M, et al.: Metabolic syndrome in HIV-infected patients using IDF and ATP-3 criteria, prevalence, discordance, and clinical utility.

    8th International Workshop on Adverse Drug Reactions and Lipodystrophy in HIV. San Francisco, CA; 2006. 2006.

77. Despres JP, Lemieux I: Abdominal obesity and metabolic syndrome.

    Nature 2006, 444:881-887. PubMed Abstract | Publisher Full Text

78. Ristig M, Drechsler H, Powderly WG: Hepatic steatosis and HIV infection.

    AIDS Patient Care STDS 2005, 19:356-365. PubMed Abstract | Publisher Full Text

79. Kelley DE, McKolanis TM, Hegazi RA, Kuller LH, Kalhan SC: Fatty liver in type 2 diabetes mellitus: relation to regional adiposity, fatty acids, and insulin resistance.

    Am J Physiol Endocrinol Metab 2003, 285:E906-916. PubMed Abstract | Publisher Full Text

80. Nguyen-Duy TB, Nichaman MZ, Church TS, Blair SN, Ross R: Visceral fat and liver fat are independent predictors of metabolic risk factors in men.

    Am J Physiol Endocrinol Metab 2003, 284:E1065-1071. PubMed Abstract | Publisher Full Text

81. Reeds DN, Yarasheski KE, Fontana L, Cade WT, Laciny E, DeMoss A, Patterson BW, Powderly WG, Klein S: Alterations in liver, muscle, and adipose tissue insulin sensitivity in men with HIV infection and dyslipidemia.

    Am J Physiol Endocrinol Metab 2006, 290:E47-E53. PubMed Abstract | Publisher Full Text

82. Meininger G, Hadigan C, Laposata M, Brown J, Rabe J, Louca J, Aliabadi N, Grinspoon S: Elevated concentrations of free fatty acids are associated with increased insulin response to standard glucose challenge in human immunodeficiency virus-infected subjects with fat redistribution.

    Metabolism 2002, 51:260-266. PubMed Abstract | Publisher Full Text

83. Feve B: Adipogenesis: cellular and molecular aspects.

    Best Pract Res Clin Endocrinol Metab 2005, 19:483-499. PubMed Abstract | Publisher Full Text

84. Sutinen J, Hakkinen AM, Westerbacka J, Seppala-Lindroos A, Vehkavaara S, Halavaara J, Jarvinen A, Ristola M, Yki-Jarvinen H: Increased fat accumulation in the liver in HIV-infected patients with antiretroviral therapy-associated lipodystrophy.

    AIDS 2002, 16:2183-2193. PubMed Abstract | Publisher Full Text

85. Luzi L, Perseghin G, Tambussi G, Meneghini E, Scifo P, Pagliato E, Del Maschio A, Testolin G, Lazzarin A: Intramyocellular lipid accumulation and reduced whole body lipid oxidation in HIV lipodystrophy.

    Am J Physiol Endocrinol Metab 2003, 284:E274-280. PubMed Abstract | Publisher Full Text

86. Martinez E, Garcia-Viejo MA, Blanch L, Gatell JM: Lipodystrophy syndrome in patients with HIV infection: quality of life issues.

    Drug Saf 2001, 24:157-166. PubMed Abstract | Publisher Full Text

87. Persson A: Facing HIV: body shape change and the (in)visibility of illness.

    Med Anthropol 2005, 24:237-264. PubMed Abstract | Publisher Full Text

88. Duran S, Saves M, Spire B, Cailleton V, Sobel A, Carrieri P, Salmon D, Moatti JP, Leport C: Failure to maintain long-term adherence to highly active antiretroviral therapy: the role of lipodystrophy.

    AIDS 2001, 15:2441-2444. PubMed Abstract | Publisher Full Text

89. Hawkins T: Appearance-related side effects of HIV-1 treatment.

    AIDS Patient Care STDS 2006, 20:6-18. PubMed Abstract | Publisher Full Text

90. Burgoyne R, Collins E, Wagner C, Abbey S, Halman M, Nur M, Walmsley S: The relationship between lipodystrophy-associated body changes and measures of quality of life and mental health for HIV-positive adults.

    Qual Life Res 2005, 14:981-990. PubMed Abstract | Publisher Full Text

91. Engelson ES: Interventions for visceral adiposity associated with human immunodeficiency virus: application of a method for assessing efficacy.

    Clin Infect Dis 2003, 37(Suppl 2):S96-100. PubMed Abstract | Publisher Full Text

92. Grinspoon S, Gelato M: Editorial: The rational use of growth hormone in HIV-infected patients.

    J Clin Endocrinol Metab 2001, 86:3478-3479. PubMed Abstract |