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Open Access

Peer-reviewed

Research Article

HIV Infection Is Associated with Increased Fatty Infiltration of the Thigh Muscle with Aging Independent of Fat Distribution

Abstract

Background

Lower muscle density on computed tomography (CT) provides a measure of fatty infiltration of muscle, an aspect of muscle quality that has been associated with metabolic abnormalities, weakness, decreased mobility, and increased fracture risk in older adults. We assessed the cross-sectional relationship between HIV serostatus, age, thigh muscle attenuation, and thigh muscle cross-sectional area (CSA).

Methods

Mean CT-quantified Hounsfield units (HU) of the thigh muscle bundle and CSA were evaluated in 368 HIV-infected and 145 HIV-uninfected men enrolled in the Multicenter AIDS Cohort Study (MACS) Cardiovascular Substudy using multivariable linear regression. Models all were adjusted for HIV serostatus, age, race, and body mass index (BMI); each model was further adjusted for covariates that differed by HIV serostatus, including insulin resistance, hepatitis C, malignancy, smoking, alcohol use, and self-reported limitation in physical activity.

Results

HIV-infected men had greater thigh muscle CSA (p<0.001) but lower muscle density (p<0.001) compared to HIV-uninfected men. Muscle density remained lower in HIV-infected men (p = 0.001) when abdominal visceral adiposity, and thigh subcutaneous adipose tissue area were substituted for BMI in a multivariable model. Muscle density decreased by 0.16 HU per year (p<0.001) of increasing age among the HIV-infected men, but not in the HIV-uninfected men (HIV x age interaction -0.20 HU; p = 0.002).

Conclusion

HIV-infected men had lower thigh muscle density compared to HIV-uninfected men, and a more pronounced decline with increasing age, indicative of greater fatty infiltration. These findings suggest that lower muscle quality among HIV-infected persons may be a risk factor for impairments in physical function with aging.

Citation: Natsag J, Erlandson KM, Sellmeyer DE, Haberlen SA, Margolick J, Jacobson LP, et al. (2017) HIV Infection Is Associated with Increased Fatty Infiltration of the Thigh Muscle with Aging Independent of Fat Distribution. PLoS ONE 12(1): e0169184. https://doi.org/10.1371/journal.pone.0169184

Editor: Giuseppe Vittorio De Socio, Azienda Ospedaliera Universitaria di Perugia, ITALY

Received: August 16, 2016; Accepted: December 13, 2016; Published: January 6, 2017

Copyright: © 2017 Natsag et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: Some access restrictions apply to the data underlying the findings. The MACS Study data is maintained by the Center for the Analysis of MACS Data (CAMACS). To protect confidentiality of the MACS participants, this data is highly de-identified and does not contain all variables used for the current analysis. For example, data in the public dataset may be grouped into categories rather than continuous variables, and dates are changed to years. Data from these analyses may be requested from the Multicenter AIDS Cohort Study Executive Committee (MACS-EC). A summary of requested data and its intended use should be submitted in writing to: Amber D'Souza, PhD, MS, MPH; CAMACS (Center for the Analysis and Management of the data from the MACS); Johns Hopkins University, Bloomberg School of Public Health; Department of Epidemiology; 615 N. Wolfe Street, E7646; Baltimore, MD 21205-2179. Individual-level MACS data are available from Dr. Brown (tbrown27@jhmi.edu) after a review of a concept sheet by the MACS executive committee. Our current material transfer agreement with the MACS does not allow us to distribute this dataset. Distribution to others must be individually requested from the MACS.

Funding: Grant Support: The MACS is funded by the National Institute of Allergy and Infectious Diseases, with additional supplemental funding from the National Cancer Institute (grants UO1-AI-35042, UL1-RR025005, UM1-AI-35043, UO1-AI-35039, UO1-AI-35040, and UO1-AI-35041). JN has received grant support from NIH Training Grant T32 (5T32EB006351-07). This study was funded by the National Heart, Lung, and Blood Institute (grant RO1 HL095129 to Dr. Post), with additional support from the National Center for Advancing Translational Sciences, a component of the National Institutes of Health and National Institutes of Health Roadmap for Medical Research (grant UL1 TR 001079 ). KME received support from the NIH/NIA K23AG050260. JEL received support from NIH/NIAID K23AI110532. TTB was supported by NIH/NIAID K24 AI120834. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

Competing interests: TTB has served as a consultant to Gilead, Merck, ViiV Healthcare, Abbvie, EMD-Serono, and Theratechnologies. JEL has served as a consultant to Gilead Sciences and GlaxoSmithKline. KME has received research funding from Gilead and has served as a medical consultant to Theratechnologies. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Introduction

Aging is associated with slow decline in muscle mass, quality, and function beginning in mid-life. For some individuals, this decline may result in impairments in physical function, disability, and frailty. Emerging data suggest that these complications may also develop at a relatively younger age in individuals with HIV infection, even among those with virologic suppression on effective antiretroviral therapy (ART). In a cross-sectional analysis of Multicenter AIDS Cohort Study (MACS) participants, HIV-infected men had a prevalence of the frailty phenotype greater than HIV-uninfected men, with the largest differences by HIV serostatus between ages 50 and 64 years [1]. The underlying etiology of frailty in HIV-infected populations is multifactorial, and likely includes effects of chronic HIV infection, effects of ART, an increased burden of chronic co-morbidities, and lifestyle and behavioral factors.

Abnormalities in fat distribution or lipodystrophy, including both central lipohypertrophy and peripheral lipoatrophy, are frequently described among HIV-infected individuals. Moreover, lipodystrophy has also been associated with abnormal fatty infiltration within skeletal muscle [2,3]. Therefore, one potential mechanism for functional decline in HIV-infected persons is lipid accumulation in and around skeletal muscle, or myosteatosis. Skeletal muscle contains intramyocellular lipid (IMCL) droplets within the cytoplasm of myocytes as well as intermuscular adipocytes. Abnormal increases in the skeletal muscle fat depot are thought to negatively affect muscle function by mechanical compression, and through secreted factors including hormones and cytokines [4,5]. Muscle density or attenuation, as measured in Hounsfield Units (HU) obtained by computed tomography (CT) scanning, is a noninvasive measure of muscle density that correlates with intramuscular lipid content assessment obtained by muscle biopsy [6,7]. Lower muscle density reflects higher intramuscular lipid content, which reflects a combination of IMCL and intermuscular adipocytes. Muscle density has been used to assess adiposity of the muscle and its functional correlates [812]. Lower CT-based skeletal muscle density is a predictor of decreased muscle function [7], and is associated with sarcopenia [13], increased fracture risk [8.9], mobility limitations [11], and frailty [14] in the general population.

We hypothesized that HIV infection would be associated with increased myosteatosis and decreased muscle mass. Using data from the MACS Cardiovascular Disease (CVD) Substudy [15], we investigated the association of HIV serostatus on muscle by examining thigh muscle density and cross-sectional area (CSA).

Methods

Study population

The MACS is an ongoing prospective cohort study of the natural and treated histories of HIV-1 infection in men who have sex with men, conducted in Baltimore, Maryland/Washington, DC; Chicago, Illinois; Pittsburgh, Pennsylvania; and Los Angeles, California [16]. The cohort includes both HIV-infected and HIV-uninfected men who attend semiannual research visits that include standardized interviews, physical examinations, and blood and urine collection for laboratory measurements [16].

Between 2010–2013, MACS men aged 40 to 70 years, weighing less than 300 pounds, and having no history of cardiac surgery or percutaneous coronary intervention were recruited into a CVD Substudy whose protocol included a mid-thigh CT scan [15]. Measures of thigh muscle density were completed in 607 men from the 2010–2013 CVD Substudy. Ninety-four participants had missing or invalid mid-thigh CT scans. The current analysis included 368 HIV-infected and 145 HIV-uninfected men. The institutional review boards (IRB) of each participating site (Johns Hopkins Bloomberg School of Public Health IRB and Johns Hopkins School of Medicine IRB [Baltimore], Western IRB [Washington, DC]; Northwestern University IRB [Chicago]; University of Pittsburgh Human Research Protection Office [Pittsburgh]; University of California Los Angeles Office of Human Research Protection Program and Harbor-University of California Los Angeles IRB [Los Angeles]) approved the study. All participants provided written, informed consent according to the approved IRB consent processes.

Computed tomography and analysis procedures

CT images were analyzed by trained, experienced readers at the core CT reading center (Los Angeles Biomedical Research Institute at Harbor-UCLA) who were blinded to participant characteristics and HIV serostatus. Mid-thigh CT scans were obtained with a 3–10 mm cross-sectional single image for each subject at the midpoint between the anterior superior iliac crest and the patella. Manual tracings were performed to delineate thigh subcutaneous fat and muscle. Muscle density in HU was measured within the region bound by the fascia lata (outermost fascia) of the left thigh muscle. In image analysis, areas (cm2) of skeletal muscle and thigh subcutaneous adipose tissue (SAT) were measured by selecting the following regions of interest, defined by the following attenuation values described by Goodpaster et al [17]: -35 to -190 HU for adipose tissue, and 0–100 HU for muscle; and mean muscle attenuation was determined from all pixels within this range. CT was also used to measure abdominal visceral adipose tissue (VAT) and abdominal SAT areas (cm2) on a 3–10 mm cross-sectional single image obtained centered at the L4-L5 vertebral disc space. VAT area was quantified by delineating the intra-abdominal cavity at the internal-most aspect of the abdominal and oblique muscle walls and the posterior aspect of the vertebral body, excluding the psoas major. The body wall was manually traced, excluding all subcutaneous fat, using a spline tool. The internal region of interest was selected and area within the VAT range computed [18]. Abdominal SAT areas were calculated by subtracting intra-abdominal fat from total abdominal fat.

Measurement of grip strength

Each semiannual MACS visit since 2006 has included an assessment of grip strength using a Jamar Dynamometer (Sammons Preston Rolyan, Bolingbrook, IL). The test was performed three times sequentially at the same MACS visit and an average was taken of the three measurements. We used the grip strength measurement closest in time to the CT scan visit within ± 4 visits (2 years). The median time between the CT scanning and the grip strength visits was 14 days, with an interquartile range (IQR) of -31 to 49 days.

Biochemical and clinical parameters

Biochemical and clinical data were collected at the previous MACS visit closest to the CT scanning, generally within 6 months. Insulin concentrations were measured using radioimmunoassay (CV = 2.6%, Linco Research, St. Charles, MO). Fasting plasma glucose levels were measured by the combined hexokinase/glucose-6-phosphate dehydrogenase method (CV 1.8%). Glucose and insulin were processed at a central laboratory (Heinz Laboratory, Pittsburgh, PA). Insulin resistance was estimated using the Homeostasis Model Assessment of Insulin Resistance (HOMA-IR = [fasting plasma insulin (μU/ml) x fasting plasma glucose (mmol/ liter)]/ 22.5) at the substudy visit [19].

Alcohol consumption was categorized into none, mild to moderate (no more than 1–2 drinks per typical day for participants who consumed alcohol at least monthly, or no more than 3–4 drinks per typical day of drinking for participants who drank alcohol less than once a month), moderate to heavy (3–4 drinks per typical day for participants reporting alcohol on a monthly or more frequent basis, or ≥5 drinks per a day for participants who drank alcohol less than once a month), and binge drinking (≥5 drinks per a day at least once a month). Chronic hepatitis C virus (HCV) infection was defined as the presence of detectable HCV RNA. Diabetes was defined by self-report in addition to the use of diabetes medication or fasting glucose ≥ 126 mg/dL or hemoglobin A1c ≥ 6.5%. Self-reported limitations in physical activity were assessed using the SF-36 questionnaire; participants answered either “Yes, limited a lot”, “Yes, limited a little” or “No, not limited” to the question “Does your health now limit you in vigorous activities, such as running, lifting heavy objects, participating in strenuous sports?”. History of any malignancy was collected by self-report at each semi-annual visit and validated using clinical records. HIV-related variables included plasma HIV-1 RNA levels, CD4+ T lymphocyte counts, history of an AIDS-defining malignancy or opportunistic infection, and duration of highly active antiretroviral therapy (HAART) use (DHHS/Kaiser guidelines).

Statistical methods

The distributions of demographic and clinical factors among HIV-infected and HIV-uninfected men were compared with muscle parameters using the Wilcoxon rank-sum test or chi square test, as appropriate. Univariate and multivariable linear regressions were performed using thigh-muscle density and CSA as outcome variables separately, with the covariates of HIV serostatus, age, race, and body mass index (BMI). Each model was further adjusted for covariates that differed by HIV serostatus (Table 1), which included HOMA-IR, history of any malignancy, cumulative pack-year smoking, degree of alcohol consumption, chronic HCV infection, and self-reported limitation in physical activity. When any of the muscle parameters were different by HIV serostatus, we added an HIV x age interaction term to explore if age modified the relationship between the muscle parameter and HIV serostatus. VAT and thigh SAT were compared by HIV serostatus using linear regression analysis adjusted for age, race and BMI. Further relationships were investigated between muscle parameters and VAT and thigh SAT, both of which were added to the multivariable model instead of BMI, and adjusted by age, race, HIV serostatus, HOMA-IR, history of malignancy, cumulative pack-year smoking, degree of alcohol consumption, chronic HCV infection, and self-reported limitations in physical activity. Correlation between grip strength and thigh muscle parameters was evaluated using Spearman's rank correlation.

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Table 1. Study population characteristics.

https://doi.org/10.1371/journal.pone.0169184.t001

Lastly, we explored factors associated with CSA and thigh muscle density in the HIV-infected men using linear regression modeling. In addition to demographic, metabolic, clinical, and behavioral factors, we examined associations with HIV-related factors (CD4+ T lymphocyte count, presence of detectable plasma HIV-1 RNA), and HIV treatment related variables (cumulative years use of any ART, protease inhibitor (PI), non-nucleoside reverse transcriptase inhibitor (NNRTI), zidovudine (AZT), stavudine (D4T), or tenofovir (TDF)). Variables that were associated with the outcome in univariate models were included in multivariable models. We also substituted measures of regional adiposity (VAT and thigh SAT) for BMI in the multivariable models. All statistical analyses were performed using Stata 13.1 (StataCorp, College Station, TX). Statistical significance was established at a two-sided p-value <0.05.

Results

Among the 368 HIV-infected and 145 HIV-uninfected men, the HIV-infected men were younger, more likely to be black, and had higher HOMA-IR, greater cumulative pack year smoking history, were more likely to have chronic HCV infection, and were more likely to have a history of malignancy (Table 1). After adjustment for age, race and BMI, HIV-infected men had significantly greater VAT and significantly less thigh SAT, respectively (VAT difference = 41.7 cm2, 95% CI 27.2, 56.3; p<0.001; thigh SAT difference = -18.2 cm2, 95% CI -22.8, -13.6; p<0.001) compared to HIV-uninfected men.

Thigh muscle cross-sectional area

As shown in Table 2, greater thigh muscle CSA was correlated with lower age and increased BMI, VAT, thigh SAT, and grip strength. In models adjusted for age, race, and BMI, HIV-infected men had greater thigh CSA (difference = 7.1 cm2; 95% CI 2.8, 11.4; p<0.001) compared to HIV-uninfected men; these associations remained significant when the model was further adjusted for HOMA-IR, malignancy, cumulative pack-year smoking, alcohol use, chronic HCV infection, and self-reported limitation in physical activity (Table 3). There was no interaction between age and HIV (p = 0.58).

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Table 2. Pearson Correlations (r) between age, BMI, grip strength, thigh muscle cross sectional area, thigh muscle density (TMD), visceral adipose area, thigh subcutaneous adipose area and insulin resistance among HIV-infected and HIV-uninfected men.

https://doi.org/10.1371/journal.pone.0169184.t002

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Table 3. Differences in Muscle CSA and attenuation between HIV-infected vs uninfected groups.

https://doi.org/10.1371/journal.pone.0169184.t003

We next explored the effect of HIV-serostatus on thigh CSA, when VAT and thigh SAT were substituted for BMI in the multivariable model. The magnitude of difference in thigh muscle CSA by HIV serostatus was attenuated and statistical significance was lost (difference = 3.6 cm2; 95% CI -2.0, 9.2; p = 0.21). In this model, VAT was strongly associated with higher thigh CSA (9.9 cm2 per ln increase (95% CI: 6.2, 13.7; p<0.001), but thigh SAT was not (1.1 cm2 per ln increase (95% CI: -1.5, 3.8, p = 0.41).

In univariate models restricted to HIV-infected men (S1 Table), lower thigh muscle cross-sectional area was associated with older age, white (vs black) race, lower BMI, lower VAT, lower thigh SAT, lower HOMA-IR, chronic HCV infection, cumulative smoking, binge alcohol drinking, and lower current CD4 cell count. In the multivariable model including BMI (Model A, S1 Table), lower CSA was associated with older age, lower BMI, and binge alcohol drinking. Similar results were obtained when VAT and thigh SAT were substituted for BMI (Model B), although race (black vs white race, 10.2 cm2 (3.2, 17.2)) and chronic hepatitis C infection (-9.7 cm2 (-18.4, -1.04)) became statistically significant. To help explain the difference in the effect of race between Models A and B, we compared BMI and VAT by race. Interestingly, whereas BMI was similar in the black and white men (median 25.7 vs 25.4 kg/m2, p = 0.66), VAT was lower in the black men then the white men (ln VAT 4.6 vs 5.2 cm2, p<0.001).

Thigh muscle density

Lower thigh muscle density (fattier muscle) was correlated with greater VAT, thigh SAT, BMI, and weaker grip strength (Table 2). In models adjusted for age, race, and BMI, HIV-infected men had lower thigh muscle density (difference = -1.6 HU; 95% CI -2.4, -0.9; p<0.001) compared to HIV-uninfected men (Table 3). Results were similar after adjustment for additional variables which differed by HIV-serostatus (Table 3, Model 2). Thigh muscle density decreased by 0.16 HU per year (95% CI -0.23, -0.08; p<0.001) with increasing age among the HIV-infected men, but did not change significantly with age in the HIV-uninfected men (HIV x age interaction -0.20 HU; 95% CI -0.32; -0.07; p = 0.002) (Fig 1).

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Fig 1. Association of thigh muscle density and age among HIV-infected (red) and HIV-uninfected (blue) men in the MACS Cohort.

https://doi.org/10.1371/journal.pone.0169184.g001

Thigh muscle density remained lower in HIV-infected men (difference = -1.6 HU; 95% CI -2.4, -0.76; p<0.001) even when VAT and thigh SAT were substituted for BMI in the multivariate model, suggesting that HIV-infection is associated with lower muscle density independent of fat distribution.

In univariate models restricted to the HIV-infected men, lower thigh muscle density was associated with older age, higher BMI, higher VAT, higher thigh SAT, cumulative smoking and binge alcohol drinking (Table 4) while cumulative D4T and TDF use were associated with higher thigh muscle density. In the multivariable model (Table 4) including BMI, lower thigh muscle density was associated with older age, higher BMI, cumulative smoking, and binge alcohol drinking, and less cumulative D4T use. Similar results were obtained when VAT and thigh SAT were substituted for BMI (data not shown).

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Table 4. Factors Associated with Thigh Muscle Density (TMD) among HIV-infected Men.

Multivariable model includes age, race, BMI plus other factors associated with TMD in univariate models.

https://doi.org/10.1371/journal.pone.0169184.t004

Discussion

In this well-characterized cohort of HIV-infected and similar HIV-uninfected men, we found that HIV-infected men had greater thigh muscle mass but lower thigh muscle density, indicative of greater of fatty skeletal muscle infiltration. In addition, both lower thigh muscle CSA and density correlated with weaker grip strength. Furthermore, lower thigh muscle density was associated with advancing age among HIV-infected men only. Taken together, our findings suggest that fatty infiltration of the muscle, often associated with aging, is more pronounced in HIV-infected men. These findings may have relevant implications for the development of physical function impairment, frailty and fractures, in middle-aged and older HIV-infected populations.

To our knowledge, this is the largest study to compare muscle density by HIV serostatus. Previous studies examining fatty infiltration of the muscle in HIV-infected persons have focused on those with HIV-associated lipodystrophy [2,3,20]. Torriani et al [2] found that psoas muscle density on CT was significantly lower in HIV-infected men with lipodystrophy, with median density of 55 HU compared with HIV-infected men without lipodystrophy (57 HU) and HIV-uninfected controls (59.5 HU). The median psoas muscle density was higher than observed in our study population, which may be due to the nearly 10-year difference in age between the two study populations. Torriani et al similarly found that higher VAT was significant predictor of lower psoas muscle density. However, we further found that thigh muscle density remained significantly lower among HIV-infected men, independent of VAT and thigh SAT areas. Although we were unable to detect a relationship between muscle density and insulin resistance, prior studies measuring muscle fatty infiltration using 1H-magnetic resonance spectroscopy have found an association between increased intramyocellular fat and insulin resistance among HIV-infected lipodystrophic individuals [2, 20, 21].

In the general population, muscle density declines with advancing age [7,13,22,23]. The cross-sectional association with age and lower muscle density in HIV-infected but not uninfected men in our study may suggest a faster rate of age-related decline in muscle density (i.e. increase in fatty infiltration) among HIV-infected persons. A prior study by Taafe, et al, reported a 4–5 HU loss followed by 2–3 HU gain in muscle density with detraining and retraining among older, HIV-uninfected adults, thus our small (-1.5 HU) differences by HIV serostatus are likely clinically meaningful [24]. Furthermore, the interaction by age and HIV serostatus suggests that magnitude of the difference by HIV serostatus may increase at older ages. We speculate that increased muscle fat content reflects early decline in muscle quality, preceding the loss of lean muscle mass and decline in muscle performance and physical function.

D4T, an early thymidine analogue NRTIs, is strongly associated with lipoatrophy, mitochondrial toxicity, and adipocyte apoptosis [25]. Given the known relationship between D4T use and hepatic steatosis [26], we had hypothesized that D4T use would be associated with a greater degree of fatty infiltration of the muscle. In contrast to our hypothesis, we found the opposite: cumulative D4T use was associated with higher thigh muscle density (i.e., less fatty infiltration). These findings suggest that the effect of D4T on muscle fat could be more similar to fat depletion changes in subcutaneous fat or bone marrow fat [27]. ART treatment regimens are heterogeneous and vary over time within individuals, thus limited conclusions can be made regarding ART effects in the context of cross-sectional studies. Furthermore, participants with prior D4T exposure had longer exposure to all ART, and only four participants were receiving D4T at the time of CT assessment. Thus our results may simply represent a chance finding.

Contrary to our hypothesis, HIV-infected men had greater thigh muscle CSA compared to HIV-uninfected men, after adjustment for age, race and BMI, but not when adjusted for VAT and thigh SAT. The HIV-infected men tended to have higher VAT than the HIV-uninfected men, and VAT, but not thigh SAT, was strongly related to CSA. Taken together, these results suggest that apparent differences by HIV serostatus in thigh CSA in the univariate and BMI-adjusted models may be related to differences in fat distribution, particularly increased VAT. Prior studies such as the FRAM study [28], have found lower total skeletal muscle mass measured by magnetic resonance imaging among HIV-infected men compared to controls, possibly due to increased HIV disease severity: in the FRAM study, 40% of the HIV-infected group had detectable HIV-1 RNA, and the median CD4+ T lymphocyte count (391 cell/μL) was lower than in our cohort. Furthermore, BMI was significantly lower in the FRAM HIV-infected group compared to the controls, and muscle mass was not adjusted for BMI or fat distribution [28].

Our study had several limitations. First, the MACS population includes only men and our findings may not be generalizable to women. It is possible that the presence of hormonal abnormalities, such as hypogonadism, may be important in the relationship between HIV and thigh muscle density; the role of hormonal alterations in muscle fat infiltration should be further investigated in future analyses. Our sample was over 30% non-white. While we adjusted all analyses for race, there are likely complex relationships between race, body composition, and muscle parameters. For example, the effect of race on CSA was only apparent after the effects of VAT were taken into account. Given that VAT was lower in the black men than the white men, despite similar BMI, the differential effect of race on CSA when BMI or regional fat was included in the multivariable model (S1 Table) most likely represents negative confounding. These relationships should be explored in further studies. Next, although lower thigh muscle density was associated with lower grip strength, the relationship between muscle density and strength may have been much more apparent if we were able to test thigh muscle strength. Unfortunately, this measurement was not available. Furthermore, we did not have objective measures of physical activity or dietary assessments. Many HIV-infected men in the MACS have a history of significant immunosuppression and are highly ART experienced. Although we have attempted to examine these factors in the analysis, it is possible that the age effects with respect to muscle parameters that we observed in this analysis among HIV-infected men are a reflection of longer exposure to toxic ART and previous immunosuppression. Finally, the cross-sectional design limits the causal inferences that we can draw from the observed associations.

In summary, HIV-infected men have lower CT-quantified thigh muscle density, a measure of fatty infiltration and indicative of lower muscle quality, compared to HIV-uninfected men. In addition, we found that HIV-infected men had a more pronounced decline in thigh muscle density with increasing age. These findings suggest impairments in muscle quality among HIV-infected persons that may have implications for functional decline, impaired mobility, falls, and fracture risk with aging. Longitudinal research is required to confirm our finding in additional populations, and future studies should seek to identify interventions to prevent or reverse HIV-associated myosteatosis and subsequently limit physical function decline among aging HIV-infected persons.

Supporting Information

S1 Table. Factors Associated with Thigh Cross Sectional Area (CSA) Among HIV-infected Men.

Model A includes BMI plus other factors associated with CSA in univariate models. Model B includes the same variables as Model A, but regional fat measures are substituted for BMI.

https://doi.org/10.1371/journal.pone.0169184.s001

(DOCX)

Acknowledgments

The authors thank Andrea Stronski for administrative support for this study.

This study was previously presented in part at the Endocrine Society Annual Meeting 2015, San Diego, CA.

Author Contributions

  1. Conceptualization: JN KME DES SAH JM LPJ FJP SLK JEL WSP TTB.
  2. Data curation: JN DES LPJ TTB.
  3. Formal analysis: JN DES LPJ TTB.
  4. Funding acquisition: WSP JM LPJ FJP SLK TTB.
  5. Investigation: JN DES SAH JM LPJ FJP SLK JEL WSP TTB.
  6. Methodology: JN DES LPJ WSP TTB.
  7. Project administration: JM LPJ WSP TTB.
  8. Resources: JM LPJ FJP SLK JEL WSP TTB.
  9. Software: JN DES LPJ TTB.
  10. Validation: JN DES LPJ TTB.
  11. Visualization: JN KME TTB.
  12. Writing – original draft: JN KME TTB.
  13. Writing – review & editing: DES SAH JM LPJ FJP SLK JEL WSP TTB.

References

  1. 1. Althoff KN, Jacobson LP, Cranston RD, Detels R, Phair JP, Li X, et al. Age, comorbidities, and AIDS predict a frailty phenotype in men who have sex with men. J Gerontol.A Biol.Sci.Med.Sci. 2014 Feb;69(2):189–98. PMCID:PMC4038242 pmid:24127428
  2. 2. Torriani M, Hadigan C, Jensen ME, Grinspoon S. Psoas muscle attenuation measurement with computed tomography indicates intramuscular fat accumulation in patients with the HIV-lipodystrophy syndrome. J Appl.Physiol (1985.) 2003 Sep;95(3):1005–10
  3. 3. Torriani M, Thomas BJ, Barlow RB, Librizzi J, Dolan S, Grinspoon S. Increased intramyocellular lipid accumulation in HIV-infected women with fat redistribution. J Appl.Physiol (1985.) 2006 Feb;100(2):609–14. PMCID:PMC3205444
  4. 4. Wronska A, Kmiec Z. Structural and biochemical characteristics of various white adipose tissue depots. Acta Physiol (Oxf) 2012 Jun;205(2):194–208
  5. 5. Addison O, Drummond MJ, LaStayo PC, Dibble LE, Wende AR, McClain DA, et al. Intramuscular fat and inflammation differ in older adults: the impact of frailty and inactivity. J Nutr.Health Aging 2014 May;18(5):532–8 pmid:24886741
  6. 6. Goodpaster BH, Kelley DE, Thaete FL, He J, Ross R. Skeletal muscle attenuation determined by computed tomography is associated with skeletal muscle lipid content. J.Appl.Physiol. 2000 Jul;89(1):104–10 pmid:10904041
  7. 7. Goodpaster BH, Carlson CL, Visser M, Kelley DE, Scherzinger A, Harris TB, et al. Attenuation of skeletal muscle and strength in the elderly: The Health ABC Study. J Appl.Physiol (1985.) 2001 Jun;90(6):2157–65
  8. 8. Lang T, Cauley JA, Tylavsky F, Bauer D, Cummings S, Harris TB. Computed tomographic measurements of thigh muscle cross-sectional area and attenuation coefficient predict hip fracture: the health, aging, and body composition study. J.Bone Miner.Res. 2010 Mar;25(3):513–9. PMCID:PMC3153392 pmid:20422623
  9. 9. Kim JH, Choi SH, Lim S, Lim JY, Kim KW, Park KS, et al. Thigh muscle attenuation measured by computed tomography was associated with the risk of low bone density in community-dwelling elderly population. Clin.Endocrinol.(Oxf) 2013 Apr;78(4):512–7
  10. 10. Kelley DE, Slasky BS, Janosky J. Skeletal muscle density: effects of obesity and non-insulin-dependent diabetes mellitus. Am J Clin.Nutr. 1991 Sep;54(3):509–15 pmid:1877507
  11. 11. Visser M, Goodpaster BH, Kritchevsky SB, Newman AB, Nevitt M, Rubin SM, et al. Muscle mass, muscle strength, and muscle fat infiltration as predictors of incident mobility limitations in well-functioning older persons. J Gerontol.A Biol.Sci.Med.Sci. 2005 Mar;60(3):324–33 pmid:15860469
  12. 12. Therkelsen KE, Pedley A, Speliotes EK, Massaro JM, Murabito J, Hoffmann U, et al. Intramuscular fat and associations with metabolic risk factors in the Framingham Heart Study. Arterioscler.Thromb.Vasc.Biol. 2013 Apr;33(4):863–70. PMCID:PMC3696991 pmid:23349188
  13. 13. Delmonico MJ, Harris TB, Visser M, Park SW, Conroy MB, Velasquez-Mieyer P, et al. Longitudinal study of muscle strength, quality, and adipose tissue infiltration. Am J Clin.Nutr. 2009 Dec;90(6):1579–85. PMCID:PMC2777469 pmid:19864405
  14. 14. Idoate F, Cadore EL, Casas-Herrero A, Zambom-Ferraresi F, Marcellan T, Ruiz de GA, et al. Adipose tissue compartments, muscle mass, muscle fat infiltration, and coronary calcium in institutionalized frail nonagenarians. Eur.Radiol. 2015 Jul;25(7):2163–75 pmid:25510447
  15. 15. Post WS, Budoff M, Kingsley L, Palella FJ Jr., Witt MD, Li X, et al. Associations between HIV infection and subclinical coronary atherosclerosis. Ann.Intern.Med. 2014 Apr 1;160(7):458–67 pmid:24687069
  16. 16. Kaslow RA, Ostrow DG, Detels R, Phair JP, Polk BF, Rinaldo CR Jr. The Multicenter AIDS Cohort Study: rationale, organization, and selected characteristics of the participants. Am J Epidemiol. 1987 Aug;126(2):310–8 pmid:3300281
  17. 17. Goodpaster BH, Thaete FL, Simoneau JA, Kelley DE. Subcutaneous abdominal fat and thigh muscle composition predict insulin sensitivity independently of visceral fat. Diabetes 1997 Oct;46(10):1579–85 pmid:9313753
  18. 18. Potretzke AM, Schmitz KH, Jensen MD. Preventing overestimation of pixels in computed tomography assessment of visceral fat. Obes.Res. 2004 Oct;12(10):1698–701 pmid:15536234
  19. 19. Matthews DR, Hosker JP, Rudenski AS, Naylor BA, Treacher DF, Turner RC. Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 1985 Jul;28(7):412–9 pmid:3899825
  20. 20. Luzi L, Perseghin G, Tambussi G, Meneghini E, Scifo P, Pagliato E, et al. Intramyocellular lipid accumulation and reduced whole body lipid oxidation in HIV lipodystrophy. Am J Physiol Endocrinol.Metab 2003 Feb;284(2):E274–E280 pmid:12388139
  21. 21. Gan SK, Samaras K, Thompson CH, Kraegen EW, Carr A, Cooper DA, et al. Altered myocellular and abdominal fat partitioning predict disturbance in insulin action in HIV protease inhibitor-related lipodystrophy. Diabetes 2002 Nov;51(11):3163–9 pmid:12401706
  22. 22. Marcus RL, Addison O, Dibble LE, Foreman KB, Morrell G, Lastayo P. Intramuscular adipose tissue, sarcopenia, and mobility function in older individuals. J Aging Res. 2012;2012:629637. PMCID:PMC3303569 pmid:22500231
  23. 23. Marcus RL, Addison O, Kidde JP, Dibble LE, LaStayo PC. Skeletal muscle fat infiltration: impact of age, inactivity, and exercise. J Nutr.Health Aging 2010 May;14(5):362–6. PMCID:PMC3758242 pmid:20424803
  24. 24. Taaffe DR, Henwood TR, Nalls MA, Walker DG, Lang TF, Harris TB. Alterations in muscle attenuation following detraining and retraining in resistance-trained older adults. Gerontology 2009;55(2):217–23. PMCID:PMC2756799 pmid:19060453
  25. 25. Guaraldi G, Stentarelli C, Zona S, Santoro A. HIV-associated lipodystrophy: impact of antiretroviral therapy. Drugs 2013 Sep;73(13):1431–50 pmid:24002702
  26. 26. Miller KD, Cameron M, Wood LV, Dalakas MC, Kovacs JA. Lactic acidosis and hepatic steatosis associated with use of stavudine: report of four cases. Ann.Intern.Med. 2000 Aug 1;133(3):192–6 pmid:10906833
  27. 27. Huang JS, Mulkern RV, Grinspoon S. Reduced intravertebral bone marrow fat in HIV-infected men. AIDS 2002 Jun 14;16(9):1265–9 pmid:12045492
  28. 28. Yarasheski KE, Scherzer R, Kotler DP, Dobs AS, Tien PC, Lewis CE, et al. Age-related skeletal muscle decline is similar in HIV-infected and uninfected individuals. J.Gerontol.A Biol.Sci.Med.Sci. 2011 Mar;66(3):332–40. PMCID:PMC3041474 pmid:21310810