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Osteoporosis in Human Immunodeficiency Virus Patients – An Emerging Clinical Concern

Filippo Maffezzoni, Teresa Porcelli, Ioannis Karamouzis, Eugenia Quiros-Roldan, Francesco Castelli, Gherardo Mazziotti, Andrea Giustina
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Published Online: Jun 8th 2008 US Endocrinology, 2014;10(1):84–8 DOI: http://doi.org/10.17925/USE.2014.10.01.84
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1

Abstract

Overview

The advent of highly active anti-retroviral therapy (HAART) has significantly improved the survival of human immunodeficiency virus (HIV)-infected patients transforming the HIV infection from a fatal illness into a manageable chronic disease. As the number of older HIV-infected individuals increases, several ageing-related co-morbidities including osteopenia/osteoporosis and fractures have emerged. Patients exposed to HIV infection and its treatment may develop fragility fractures with potential significant impact on quality of life and survival. However, the awareness of HIV-related skeletal fragility is still relatively low and most HIV-infected patients are not investigated for osteoporosis and treated with anti-osteoporotic drugs in daily clinical practice. This article reviews the literature data on osteoporosis and osteopenia in HIV infection, focusing on the pathophysiological, clinical and therapeutic aspects of fragility fractures.

Keywords

HIV, fractures, retroviral drugs, HAART, osteoporosis

2

Article

The advent of highly active anti-retroviral therapy (HAART) has significantly improved the survival of human immunodeficiency virus (HIV)-infected patients.1 In this context, HIV-infected patients are living longer and are facing several associated morbidities related with ageing, such as diabetes, malignancies, cardiovascular diseases and osteoporosis.

The advent of highly active anti-retroviral therapy (HAART) has significantly improved the survival of human immunodeficiency virus (HIV)-infected patients.1 In this context, HIV-infected patients are living longer and are facing several associated morbidities related with ageing, such as diabetes, malignancies, cardiovascular diseases and osteoporosis. It is noteworthy that some of these comorbidities are pathophysiologically associated with HIV infection and its treatment and they may greatly affect the quality of life and survival of the affected patients.2 Since early in the era of effective HAART, a higher prevalence of low bone mineral density (BMD) has been described among HIV-infected patients and over recent years there has also been evidence that fragility fractures may occur at high frequency in this clinical context.1,3–29 However, most literature studies so far published on this topic have focused on bone metabolism and BMD,1,3–18 whereas data on fractures in HIV infection are scant and the factors influencing the fracture risk in this clinical context are still largely unknown.19–29 As a matter of fact, the awareness of HIV-related skeletal fragility is still relatively low and most HIV-infected patients are not investigated for osteoporosis and treated with anti-osteoporotic drugs in daily clinical practice.

This narrative review reports the literature data and the personal experience of the authors on skeletal fragility in HIV infection, focusing on the pathophysiological, clinical and therapeutic aspects of fragility fractures. Full text articles in the English language were selected from a PubMed search spanning 1983 to 2013, for keywords including ‘HIV’, ‘osteoporosis’, ‘fracture risk’, ‘antiretroviral therapy’, ‘endocrine disorders’, and ‘pharmacological treatment’. Reference lists in selected papers were also used to broaden the search.

Mechanisms of Skeletal Fragility in Human Immunodeficiency Virus Infection
Osteoporosis is a skeletal disorder characterised by compromised bone strength predisposing to an increased risk of fracture.30 The skeleton is an extremely dynamic tissue with a continuous remodelling process guided by bone-forming osteoblasts and bone-resorbing osteoclasts.31 The balance between bone resorption and bone formation is crucial to guarantee the skeletal homeostasis, whereas osteoporosis develops when the activity of osteoclasts is predominant in terms of bone formation. It is intuitive that osteoporosis may be caused either by a predominant increase in bone resorption, as it specifically occurs in patients with postmenopausal osteoporosis, or by a specific impairment of bone resorption, as it is generally described in patients exposed to chronic glucocorticoid excess and in those with growth hormone deficiency.31–33 Both mechanisms may occur in HIV-infected patients, with the bone turnoverfeatures being variable during the clinical history of disease in relationship with the several factors involved in the pathogenesis of skeletal fragility with variable effects on bone remodelling.

Patients with HIV infection are frequently characterised by a clustering of factors, such as heavy alcohol use, cigarette smoking, opiate use, low body mass index (BMI) and unfavourable nutritional status, which are known to predispose to fractures in the general population.14 Moreover, HIV patients may have comorbidities (i.e., liver disease, growth hormone deficiency, hypogonadism, hypovitaminosis D, insulin resistance and diabetes) and exposed to chronic treatments (i.e., with glucocorticoids and anti-depressants) potentially affecting skeletal health.2,24,34–39 These epidemiological aspects make the specific role of HIV infection in determining skeletal fragility difficult to understand. The chronic inflammatory process underlying HIV infection was shown to increase osteoclastogenesis and bone resorption via the effects of cytokines, such as tumour necrosis factor alpha (TNF-a), interleukin (IL)-6 and the ligand of the receptor activator of nuclear factor kappa-light-chainenhancer of activated B cells (NF-kB) (RANKL), produced by activated T and B cells.40,41 Moreover, TNF-a was shown to also inhibit 1-a hydroxylase, with consequent predisposition to vitamin D inadequacy.42 Interestingly, HIV was also shown to directly interact with osteoblasts and mesenchymal cells, influencing osteoblast differentiation, survival and activity.43,44

In addition to the aforementioned factors, HAART has been involved in the pathogenesis of osteoporosis in patients with HIV infection.34 HAART typically combines nucleoside analogue reverse transcriptase inhibitors with either HIV protease inhibitors or nonnucleoside reverse transcriptase inhibitors. The nucleoside analogues suppress the replication of retroviruses by interfering with the reverse transcriptase enzyme activity causing premature termination of the proviral HIV DNA chain. Notwithstanding the positive effects on HIV infection, these drugs may cause severe side effects as mitochondrial toxicity, hyperlactataemia and lactic acidosis that may lead to osteopenia by a mechanism related to premature skeletal ageing and/or calcium hydroxyapatite loss attempting to buffer chronic acidosis.45 Tenofovir is commonly classified as nucleotide reverse transcriptase inhibitor, but its mitochondrial toxicity is lower compared with similar drugs. However, tenofovir has dose-dependent renal toxicity, which may lead to tubular dysfunction (i.e., impaired phosphorus balance) and blunted synthesis of 1,25OH vitamin D with consequent osteomalacia.11,46,47 Protease inhibitors impair HIV replication by preventing the viral protease enzymatic action, a pivotal step in the final stages of the viral replication cycle. These drugs stimulate osteoclast differentiation and activity with an increase of bone resorption.48 Consistently with these mechanisms, BMD paradoxically drops over the first 1–2 years of HAART, although this treatment leads to an improvement of systemic inflammation, body composition and endocrine milieu.28,49,50 The bone loss is associated with marked increases in bone turnover in the first 6 months of antiretroviral therapy, with markers of bone resorption rising earlier and higher than markers of bone formation, creating a ‘catabolic window’.51

In conclusion, the pathogenesis of osteoporosis in HIV-exposed patients is multifactorial, involving infection-related factors, HAART and traditional osteoporosis risk factors, such as smoking, alcohol use, low BMI, opiate use and hypogonadism, which are found in higher prevalence in this clinical context.

Clinical Aspects of Skeletal Fragility in Human Immunodeficiency Virus Infection
According to the World Health Organization, the definitions of osteopenia and osteoporosis are based on results from bone densitometry, in which the patient’s BMD is compared with the average for young adults, after adjusting for race and gender. A T-score less than or equal to –2.5 standard deviation (SD) at the hip or spine is defined as osteoporosis, whereas osteopenia is defined as a T-score between –1 and –2.5 SD.52 These densitometric definitions are applicable only for post-menopausal women and men age 50 and older, whereas for younger subjects the Z-score (i.e., the number of SDs from age-matched controls) of 2.0 or lower is used to define a BMD ‘below the expected range for age’.53 Indeed, osteoporosis cannot be diagnosed in men under 50 and pre-menopausal women on the basis of BMD alone.53

BMD has been widely investigated in patients with HIV infection and the results of these studies are concordant with the concept that low BMD is common in this clinical setting.1 However, the results are quite variable in terms of prevalence of osteopenia and osteoporosis, in part due to the different criteria used in the literature to define these conditions. The reported prevalence rate of osteopenia in HIV-infected cohorts has been described as ranging from 22 % to 71 % with rates of osteoporosis varying from 3 % to 33 %.1 Bone loss seems to occur very early, as identified in a study of primary HIV infection in which about one-half of newly infected patients were shown to have low bone mass by dual-energy X-ray absorptiometry (DXA) scan.3 Indeed, there are prospective studies demonstrating that the initiation of HAART is accompanied by an early increase in bone resorption leading BMD to drop approximately 2–6 % over the first 1–2 years of treatment.1 This finding has been consistent across studies and seems to be independent of the specific HAART used, although tenofovir-containing regimens usually have greater reductions in BMD when started in previously untreated patients.54 Osteopenia was shown to develop in about one-third of patients with treated HIV infection during a median period of 7 years of follow-up, with the time of progression being shorter (i.e. only 2 years) in those patients with baseline normal–low BMD values.17 Moreover, men progressed more rapidly than women,17 although women have been seen to progress from advanced osteopenia to osteoporosis as rapidly as only 1 year.55

These longitudinal studies provided evidence that baseline BMD values may guide the decision on the BMD testing intervals in patients with HIV infection, as well as it was proposed for the general population.55 These densitometric data are consistent with the concept that HIV infection may be associated with skeletal fragility, although the value of BMD in predicting the fractures in this clinical setting is still uncertain. Indeed, in HIV-infected patients fractures may occur even in presence of low–normal BMD values, such as in other forms of secondary osteoporosis.32,33,56,57

Data from the HIV Outpatient Study (HOPS) showed a slight annual increase in fracture rates among the HIV patients reflecting an improvement of patient survival, as well as a possible increase of awareness for bone health concerns.22 Güerri-Fernandez et al. reported a fivefold increase in risk of incident hip fractures in HIV-infected patients compared with the HIV-uninfected subjects, independent of age, gender and comorbidities.21 Similar results, albeit of a lesser magnitude, were observed for non-hip fractures (hazard ratio [HR] 1.63, 95 % confidence interval [CI] 1.12–2.32) or all clinical fractures (HR 1.75, 95 % CI 1.24–2.48).21 All these data support the concept that HIV-infected persons have a higher than expected risk of fracture at sites generally associated with osteoporosis. Several factors have been reported to be associated with fractures in HIV infection, such as older age, substance abuse, heavy alcohol consumption, low BMI, hepatitis C virus (HCV) co-infection, diabetes, prevalent fractures and low nadir CD4 cell count.19–22,24 However, it is particularly difficult to ascertain the effect of untreated HIV infection on fracture risk, since over the last 20 years the pool of untreated HIV-infected persons has been limited as a result of the progressive increase of HAART use in this clinical context. The association of HAART exposure and fracture risk showed contradictory results. Several studies reported high fracture rates during HAART, with greater effects occurring with protease inhibitors and tenofovir.20,24,27,29,58,59 However, other studies did not confirm these results22,25,60 and a decrease of fracture risk after starting HAART was observed in some experiences.61

Almost all fracture data in HIV-infected patients derive from populationbased studies using an historical assessment of clinical fractures. As a matter of fact, this approach, even if cost-effective for epidemiological studies, was not reliable for investigating the true prevalence and incidence of vertebral fractures in HIV population and likely underestimated skeletal fragility in this clinical setting. As vertebral fractures are often asymptomatic and largely underdiagnosed based upon clinical records, the radiological and morphometric approach has emerged as the method of choice for evaluating the true prevalence of fractures in population studies.62 Vertebral fractures are clinically important because they affect the clinical outcome of patients with osteoporosis in terms of development of new fractures and an increase in morbidity and mortality.63,64 These aspects may be of clinical relevance in frail patients, such as those with HIV infection. Torti et al., for the first time used a morphometric approach to investigate the prevalence of vertebral fractures in HIV patients.24 The analysis was performed on available chest X-rays and allowed to demonstrate the presence of vertebral fractures in about 27 % of males with HIV infection, in close relationship with overweight, older age and diabetes.24 The finding of almost one out of three HIV-infected patients bearing one or more radiological fractures is of potential clinical relevance mainly because bone damage seems to be largely more frequent than that assessed in previous studies by BMD measurement (osteoporosis prevalence estimated around 15 %).13 Therefore, such as in other forms of secondary osteoporosis,32,65–68 lateral spine X-rays may have a role in the screening algorithms of osteoporosis in HIV infection even before DXA scanning. Interestingly, in the study of Torti et al., most patients with vertebral fractures did not have indication to perform DXA, according to the FRAX® algorithm.24

Therapeutic Aspects
As in the general population, HIV-infected patients can be advised to modify lifestyle, stop cigarette smoking and heavy alcohol consumption, as well as increasing physical exercise to control body weight. It is noteworthy that several of the risk factors for fragility fractures are shared with other common ‘lifestyle’ diseases, such as coronary heart disease, diabetes, malignancies and liver disease, which are also frequent in people with HIV.69–71 This provides an additional rationale for a planned screening programme for these risk factors among the HIV population.72

Patients with HIV infection should also be advised to increase the daily intake of calcium, which was shown to be significantly decreased in these patients in relationship with impaired BMD.73 However, hypovitaminosis D is highly prevalent in this clinical context and adequate vitamin D supplementation is required to guarantee calcium absorption and avoid or correct osteomalacia.

All the aforementioned general measures are necessary but likely not sufficient to prevent the fragility fractures in HIV-infected patients. Anti-osteoporotic drugs could be needed to counteract the negative effects of HIV infection and its treatment on skeletal remodelling. Bisphosphonates, such as alendronate and zoledronic acid, were tested in patients with HIV infection with positive effects in terms of decrease in bone turnover and improvement of BMD (see Table 1).74–81 Moreover, zoledronic acid was shown to exert extraskeletal effects on the immune system with potential favourable outcome of HIV infection during HAART.82 However, there are still some unclear aspects concerning the use of bisphosphonates in patients with HIV infection. First, the cost-effectiveness of bisphosphonates in HIV infection is unknown, since there are no data on fractures (see Table 1). Moreover, the longterm effectiveness of bisphosphonates in HIV patients is unknown and this aspect is clinically relevant considering the early occurrence of osteoporosis after HIV exposure and the long-term survival of the patients undergoing HAART. Furthermore, the long-term safety of bisphosphonates is also uncertain. As a matter of fact, osteonecrosis of the jaw may be a clinical concern in patients with deranged immune system, such as those with HIV infection.83 The presence of one or more radiological vertebral fractures may be an important element in guiding the decision to start anti-osteoporotic treatment since patients bearing vertebral fractures are at highest absolute risk of a further fracture independently of BMD values.63 Moreover, morphometric re-evaluation of the spine during bisphosphonate therapy (after 12–24 months) may allow patients who may eventually refracture under treatment to be detected. These patients may be defined as ‘resistant’ to bisphosphonates and may be candidate to anabolic treatment with teriparatide.

Another clinical challenge is the definition of the therapeutic threshold for starting anti-resorptive therapy. In the general population aged 50 or older, the therapeutic decision-making is mainly guided by the definition of the individual fracture risk by algorithms, such as FRAX, which consider several factors predisposing to skeletal fragility.84 In HIVinfected patients, the FRAX algorithm was shown to underestimate the fracture risk,24 mainly because patients with HIV infection are usually evaluated for skeletal fragility at a younger age than those already considered for the validation of FRAX. For the same reasons, BMD alone cannot be considered to assess the fracture risk in patients with HIV infection since there are no absolute densitometric criteria to define osteoporosis in men younger than 50 and in pre-menopausal women.53 As a matter of fact, DXA screening is usually recommended in HIVinfected men older than 50 years and HIV-infected post-menopausal women.85 In patients starting anti-osteoporotic treatment, BMD should be re-tested after 12–18 months to monitor the effectiveness of the therapy, whereas in patients not treated with bone-active drugs the re-testing of BMD may be guided by the baseline values taking into account the available prospective data on the changes in BMD in HIV patients and in post-menopausal women.17,55

Hypogonadism and growth hormone (GH) deficiency may occur in HIVinfected individuals35 and these conditions may contribute to bone loss in this clinical context, such as in the general population.61,86 Although there is a rationale for using testosterone and recombinant GH,33,87 there is still insufficient evidence to recommend these drugs for treatment of skeletal fragility in HIV infection.88–96

Conclusion
Bone loss occurs frequently in HIV-infected patients and the aetiology of this disorder is multifactorial involving the chronic inflammation, direct effects of HIV on bone cells, effects of HAART on bone remodelling and bone metabolism, as well as the clustering in HIV-infected patients of traditional risk factors for skeletal fragility. The relative contribution of these factors in each patient may be variable and the definition of the individual risk factor for fractures in HIV-infected subjects remains a clinical challenge.

Patients with HIV infection develop fragility fractures. Indeed, the extent of the problem is currently underestimated, but it may become clinically relevant in the near future when the HIV patients will approach to the older decades of life. The crucial point, therefore, is to identify specific diagnostic and therapeutic strategies able to protect the skeleton from the negative effects of HIV infection, since the early phases of natural history of disease. Specifically, the efforts should be devoted to early diagnosis of fractures with the spine morphometric approach and to assess the effectiveness of anti-osteoporotic drugs in the prevention of fractures in this clinical context.

2

References

  1. Powderly WG, Osteoporosis and bone health in HIV,
    Curr HIV/AIDS Rep, 2012;9:218–22.

  2. Luetkemeyer AF, Havlir DV, Currier JS, CROI 2013: Complications
    of HIV disease, viral hepatitis, and antiretroviral therapy, Top
    Antivir Med, 2013;21:62–74.

  3. Rothman MS, Bessesen MT, HIV infection and osteoporosis:
    pathophyshiology, diagnosis and treatment options, Curr
    Osteoporos Rep, 2012;10:270–7.

  4. Brown TT, Qaqish RB, Antiretroviral therapy and the prevalence
    of osteopenia and osteoporosis: a meta-analytic review, AIDS,
    2006;20:2165–74.

  5. Lima AL, de Oliveira PR, Plapler PG, et al., Osteopenia and
    osteoporosis in people living with HIV: multiprofessional
    approach, HIV AIDS (Auckl), 2011;3:117–24.

  6. Cazanave C, Dupon M, Lavignolle-Aurillac V, et al., Reduced
    bone mineral density in HIV infected patients: prevalence and
    associated factors, AIDS, 2008;22:395–402.

  7. Yin MT, McMahon DJ, Ferris DC, et al., Low bone mass and high
    bone turnover in postmenopausal human immunodeficiency
    virus-infected women, J Clin Endocrinol Metab, 2010;95:620–9.

  8. Yin MT, Zhang CA, McMahon DJ, et al., Higher rates of bone
    loss in postmenopausal hiv-infected women: a longitudinal
    study, J Clin Endocrinol Metab, 2012;97:554–62.

  9. Teichmann J, Stephan E, Discher T, et al., Changes in
    calciotropic hormones and biochemical markers of bone
    metabolism in patients with human immunodeficiency virus
    infection, Metabolism, 2000;49:1134–9.

  10. Aukrust P, Haug CJ, Ueland T, et al., Decreased bone formative
    and enhanced resorptive markers in human immunodeficiency
    virus infection: indication of normalization of the boneremodeling
    process during highly active antiretroviral therapy,
    J Clin Endocrinol Metab, 1999;84:145–50.

  11. Focà E, Motta D, Borderi M, et al., Prospective evaluationof bone
    markers,parathormone and 1,25-(OH)2 vitamin D in HIV-positive
    patients after the initiation of tenofovir/emtricitabine with
    atazanavir/ritonavir or efavirenz, BMC Infect Dis, 2012;12:38.

  12. Hernández Quero J, Ortego Centeno N, Muñoz-Torres M, et al.,
    Alterations in bone turnover in HIV-positive patients, Infection,
    1993;21:220–2.

  13. Arnsten JH, Freeman R, Howard AA, et al., Decreased bone
    mineral density and increased fracture risk in aging men with
    or at risk for HIV infection, AIDS, 2007;21:617–23.

  14. Jones S, Restrepo D, Kasowitz A, et al., Risk factors for
    decreased bone density and effects of HIV on bone in the
    elderly, Osteoporos Int, 2008;19:913–8.

  15. Mary-Krause M, Viard JP, Ename-Mkoumazok B, et al.,
    Prevalence of low bone mineral density in men and women
    infected with human immunodeficiency virus 1 and a proposal
    for screening strategy, J Clin Densitom, 2012;15:422–33.

  16. Briot K, Kolta S, Flandre P, et al., Prospective one-year bone
    loss in treatment-naïve HIV+ men and women on single or
    multiple drug HIV therapies, Bone, 2011;48:1133–9.

  17. Negredo E, Bonjoch A, Gómez-Mateu M, et al., Time of
    progression to osteopenia/osteoporosis in chronically
    HIV-infected patients: screening DXA scan, PLoS One,
    2012;7(10):e46031.

  18. Brown TT, McComsey GA, King MS, et al., Loss of bone mineral
    density after antiretroviral therapy initiation, independent
    of antiretroviral regimen, J Acquir Immune Defic Syndr,
    2009;51:554–61.

  19. Triant VA, Brown TT, Lee H, Grinspoon SK, Fracture prevalence
    among human immunodeficiency virus (HIV)-infected versus
    non-HIV-infected patients in a large U.S. healthcare system,
    J Clin Endocrinol Metab, 2008;93:3499–504.

  20. Womack JA, Goulet JL, Gibert C, et al., Increased risk of fragility
    fractures among HIV infected compared to uninfected male
    veterans, PLoS One, 2011;6(2):e17217.

  21. Güerri-Fernandez R, Vestergaard P, Carbonell C, et al.,
    HIV infection is strongly associated with hip fracture risk,
    independently of age, gender, and comorbidities: A populationbased
    cohort study, J Bone Miner Res, 2013;28:1259–63.

  22. Young B, Dao CN, Buchacz K, et al., Increased rates of bone
    fracture among HIV-infected persons in the HIV Outpatient
    Study (HOPS) compared with the US general population,
    2000–2006, Clin Infect Dis, 2011;52:1061–8.

  23. Prior J, Burdge D, Maan E, et al., Fragility fractures and
    bone mineral density in HIV positive women: a case-control
    population-based study, Osteoporos Int, 2007;18:1345–53.

  24. Torti C, Mazziotti G, Soldini PA, et al., High prevalence of
    radiological vertebral fractures in HIV-infected males, Endocrine,
    2012;41:512–7.

  25. Yin MT, Shi Q, Hoover DR, et al., Fracture incidence in HIVinfected
    women: results from the Women’s Interagency HIV
    Study, AIDS, 2010;24:2679–86.

  26. Collin F, Duval X, Le Moing V, et al., Ten-year incidence and risk
    factors of bone fractures in a cohort of treated HIV1-infected
    adults, AIDS, 2009;23:1021–4.

  27. Horizon AA, Joseph RJ, Liao Q, et al., Characteristics of foot
    fractures in HIV-infected patients previously treated with
    tenofovir versus non-tenofovir-containing highly active
    antiretroviral therapy, HIV AIDS (Auckl), 2011;3:53–9.

  28. McComsey GA, Kitch D, Daar ES, et al., Bone mineral density
    and fractures in antiretroviral-naïve persons randomized to
    receive abacavir-lamivudine or tenofovir disoproxil fumarateemtricitabine
    along with efavirenz or atazanavir-ritonavir: Aids
    Clinical Trials Group A5224s, a substudy of ACTG A5202, J Infect
    Dis, 2011;203:1791–801.

  29. Hansen AB, Gerstoft J, Kronborg G, et al., Incidence of low and
    high-energy fractures in persons with and without HIV infection:
    a Danish population-based cohort study, AIDS, 2012;26:285–93.

  30. Consensus development conference: diagnosis, prophylaxis,
    and treatment of osteoporosis, Am J Med, 1993;94:646–50.

  31. Canalis E, Giustina A, Bilezikian JP, Mechanisms of anabolic
    therapies for osteoporosis, N Engl J Med, 2007;357:905–16.

  32. Mazziotti G, Angeli A, Bilezikian JP, et al., Glucocorticoidinduced
    osteoporosis: an update, Trends Endocrinol Metab,
    2006;17:144–9.

  33. Giustina A, Mazziotti G, Canalis E, Growth hormone, insulin-like
    growth factors, and the skeleton, Endocr Rev, 2008;29:535–59.

  34. Mazziotti G, Canalis E, Giustina A, Drug-induced Osteoporosis:
    Mechanisms and Clinical Implications, Am J Med,
    2010;123:877-84.

  35. Brown TT, The effects of HIV-1 infection on endocrine organs,
    Best Pract Res Clin Endocrinol Metab, 2011;25:403–13.

  36. Cotter AG, Powderly WG, Endocrine complications of human
    immunodeficiency virus infection: hypogonadism, bone
    disease and tenofovir-related toxicity, Best Pract Res Clin
    Endocrinol Metab, 2011;25:501–15.

  37. Gutierrez AD, Balasubramanyam A, Dysregulation of glucose
    metabolism in HIV patients: epidemiology, mechanisms, and
    management, Endocrine, 2012;41:1–10.

  38. Koutkia P, Eaton K, You SM, et al., Growth hormone secretion
    among HIV infected patients: effects of gender, race and fat
    distribution, AIDS, 2006;20:855–62.

  39. Rodríguez M, Daniels B, Gunawardene S, Robbins GK, High
    frequency of vitamin D deficiency in ambulatory HIV-Positive
    patients, AIDS Res Hum Retroviruses, 2009;25:9–14.

  40. Vikulina T, Fan X, Yamaguchi M, et al., Alterations in the
    immuno-skeletal interface drive bone destruction in HIV-1
    transgenic rats, Proc Natl Acad Sci U S A, 2010;107:13848–53.

  41. Pacifici R, Role of T cells in the modulation of PTH action:
    physiological and clinical significance, Endocrine,
    2013;44:576–82.

  42. Haug CJ, Aukrust P, Haug E, et al., Severe deficiency of
    1,25-dihydroxyvitamin D3 in human immunodeficiency virus
    infection: association with immunological hyperactivity and
    only minor changes in calcium homeostasis, J Clin Endocrinol
    Metab, 1998;83:3832–8.

  43. Cotter EJ, Malizia AP, Chew N, et al., HIV proteins regulate bone
    marker secretion and transcription factor activity in cultured
    human osteoblasts with consequent potential implications
    for osteoblast function and development, AIDS Res Hum
    Retroviruses, 2007;23:1521–30.

  44. Borderi M, Gibellini D, Vescini F, et al., Metabolic bone disease
    in HIV infection, AIDS, 2009;23:1297–310.

  45. Carr A, Miller J, Eisman JA, Cooper DA, Osteopenia in HIVinfected
    men: association with asymptomatic lactic acidemia
    and lower weight pre-antiretroviral therapy, AIDS, 2001;15:703–9.

  46. Parsonage MJ, Wilkins EG, Snowden N, et al., The development
    of hypophosphataemic osteomalacia with myopathy in two
    patients with HIV infection receiving tenofovir therapy,
    HIV Med, 2005;6:341–6.

  47. Rosenvinge MM, Gedela K, Copas AJ, et al., Tenofovir-linked
    hyperparathyroidism is independently associated with the
    presence of vitaminD deficiency, J Acquir Immune Defic Syndr,
    2010;54:496–9.

  48. Gibellini D, Borderi M, de Crignis E, et al., Analysis of the effects
    of specific protease inhibitors on OPG/RANKL regulation in an
    osteoblast-like cell line, New Microbiol, 2010;33:109–15.

  49. Stellbrink HJ, Orkin C, Arribas JR, et al., Comparison of changes
    in bone density and turnover with abacavir-lamivudine versus
    tenofovir-emtricitabine in HIV-infected adults: 48 weeks results
    from the ASSERT study, Clin Infect Dis, 2010;51:963–72.

  50. van Vonderen MG, Lips P, van Agtmael MA, et al., First line
    zidovudine/lamivudine/lopinavir leads to greater bone
    loss compared to nevirapine/lopinavir/ritonavir, AIDS,
    2009;23:1367–76.

  51. Brown TT, HIV: an underrecognized secondary cause of
    osteoporosis?, J Bone Miner Res, 2013;28:1256–8.

  52. Report of a WHO Study Group. Assessment of fracture risk and
    its application to screening for postmenopausal osteoporosis,
    World Health Organ Tech Rep Ser, 1994;843:1–129.

  53. Schousboe JT, Shepherd JA, Bilezikian JP, Baim S, Executive
    summary of the 2013 International Society for Clinical
    Densitometry Position Development Conference on bone
    densitometry, J Clin Densitom, 2013;16:455–66.

  54. Gallant JE, DeJesus E, Arribas JR, et al. Tenofovir DF,
    emtricitabine, and efavirenz vs. zidovudine, lamivudine, and
    efavirenz for HIV, N Engl J Med, 2006;354:251–60.

  55. Gourlay ML, Fine JP, Preisser JS, et al., Bone-density testing
    interval and transition to osteoporosis in older women,
    N Engl J Med, 2012;366:225–33.

  56. Mazziotti G, Gola M, Bianchi A, et al., Influence of diabetes
    mellitus on vertebral fractures in men with acromegaly,
    Endocrine, 2011;40:102–8.

  57. Mazziotti G, Bilezikian J, Canalis E, et al., New understanding
    and treatments for osteoporosis, Endocrine, 2012;41:58–69.

  58. Bedimo R, Maalouf NM, Zhang S, et al., Osteoporotic fracture
    risk associated with cumulative exposure to tenofovir and
    other antiretroviral agents, AIDS, 2012;26:825–31.

  59. Yin MT, Kendall MA, Wu X, et al., Fractures after antiretroviral
    initiation, AIDS, 2012;26:2175–84.

  60. Yong MK, Elliott JH, Woolley IJ, Hoy JF, Low CD4 count is
    associated with an increased risk of fragility fracture in HIVinfected
    patients, J Acquir Immune Defic Syndr, 2011;57:205–10.

  61. Mundy LM, Youk AO, McComsey GA, Bowlin SJ, Overall benefit
    of antiretroviral treatment on the risk of fracture in HIV: nested
    case-control analysis in a health-insured population, AIDS,
    2012;26:1073–82.

  62. Griffith JF, Genant HK, New advances in imaging osteoporosis
    and its complications, Endocrine, 2012;42:39–51.

  63. Cauley JA, Hochberg MC, Lui LY, et al., Long-term risk of
    incident vertebral fractures, JAMA, 2007;298:2761–7.

  64. Jalava T, Sarna S, Pylkkänen L, et al., Association between
    vertebral fracture and increased mortality in osteoporotic
    patients, J Bone Miner Res, 2003;18:1254–60.

  65. Bonadonna S, Mazziotti G, Nuzzo M, et al., Increased
    prevalence of radiological spinal deformities in active
    acromegaly: a cross-sectional study in postmenopausal
    women, J Bone Miner Res, 2005;20:1837–44.

  66. Mazziotti G, Bianchi A, Bonadonna S, et al., Increased
    prevalence of radiological spinal deformities in adult
    patients with GH deficiency: influence of GH replacement
    therapy, J Bone Miner Res, 2006;21:520–8.

  67. Mazziotti G, Bianchi A, Porcelli T, et al., Vertebral fractures in
    patients with acromegaly: a 3-year prospective study, J Clin
    Endocrinol Metab, 2013;98:3402–10.

  68. Mancini T, Mazziotti G, Doga M, et al., Vertebral fractures in
    males with type 2 diabetes treated with rosiglitazone, Bone,
    2009;45:784–8.

  69. Aboud M, Elgalib A, Pomeroy L, et al, Cardiovascular risk
    evaluation and antiretroviral therapy effects in an HIV cohort:
    implications for clinical management: the CREATE 1 study,
    Int J Clin Pract, 2010;64:1252–9.

  70. Elgalib A, Aboud M, Kulasegaram R, et al., The assessment of
    metabolic syndrome in UK patients with HIV using two different
    definitions: CREATE 2 study, Curr Med Res Opin, 2011;27:63–9.

  71. Wierzbicki AS, Purdon SD, Hardman TC, et al., HIV lipodystrophy
    and its metabolic consequences: implications for clinical
    practice, Curr Med Res Opin, 2008;24:609–24.

  72. Peters BS, Perry M, Wierzbicki AS, et al, A cross-sectional
    randomised study of fracture risk in people with HIV infection
    in the Probono 1 Study, PLoS One, 2013;8:e78048.

  73. Li Vecchi V, Soresi M, Giannitrapani L, et al., Dairy calcium
    intake and lifestyle risk factors for bone loss in hiv-infected and
    uninfected Mediterranean subjects, BMC Infect Dis, 2012;12:192.

  74. Guaraldi G, Orlando G, Madeddu G, et al., Alendronate reduces
    bone resorption in HIV-associated osteopenia/osteoporosis,
    HIV Clin Trials, 2004;5:269–77.

  75. Negredo E, Martinez-Lopez E, Paredes R, et al., Reversal of
    HIV-1-associated osteoporosis with once-weekly alendronate,
    AIDS, 2005;19:343–5.

  76. Mondy K, Powderly WG, Claxton SA, et al., Alendronate, vitamin
    D, and calcium for the treatment of osteopenia/ osteoporosis
    associated with HIV infection, J Acquir Immune Defic Syndr,
    2005;38:426–31.

  77. McComsey GA, Kendall MA, Tebas P, et al., Alendronate with
    calcium and vitamin D supplementation is safe and effective
    for the treatment of decreased bone mineral density in HIV,
    AIDS, 2007;21:2473–82.

  78. Bolland MJ, Grey AB, Horne AM, et al., Annual zoledronate
    increases bone density in highly active antiretroviral
    therapy-treated human immunodeficiency virus-infected
    men: a randomized controlled trial, J Clin Endocrinol Metab,
    2007;92:1283–8.

  79. Huang J, Meixner L, Fernandez S, McCutchan JA, A
    doubleblinded, randomized controlled trial of zoledronate
    therapy for HIV-associated osteopenia and osteoporosis,
    AIDS, 2009;23:51–7.

  80. Rozenberg S, Lanoy E, Bentata M, et al., Effect of alendronate
    on HIV-associated osteoporosis: a randomized, double-blind,
    placebo-controlled, 96-week trial (ANRS 120), AIDS Res Hum
    Retroviruses, 2012;28:972–80.

  81. Bolland MJ, Grey A, Horne AM, et al., Effects of intravenous
    zoledronate on bone turnover and bone density persist for at
    least five years in HIV-infected men, J Clin Endocrinol Metab,
    2012;97:1922–8.

  82. Poccia F, Gioia C, Martini F, et al., Zoledronic acid and
    interleukin-2 treatment improves immunocompetence in HIVinfected
    persons by activating Vgamma9Vdelta2 T cells, AIDS,
    2009;23:555–65.

  83. Siwamogstham P, Kuansuwan C, Reichart PA, Herpes zoster
    in HIV infection with osteonecrosis of the jaw and tooth
    exfoliation, Oral Dis, 2006;12:500–5.

  84. Lewiecki EM, Compston JE, Miller PD, et al., Official Positions for
    FRAX® Bone Mineral Density and FRAX® simplification from Joint
    Official Positions Development Conference of the International
    Society for Clinical Densitometry and International Osteoporosis
    Foundation on FRAX®, J Clin Densitom, 2011;14:226–36.

  85. Brown TT, Challenges in the management of osteoporosis
    and vitamin D deficiency in HIV infection, Top Antivir Med,
    2013;21:115–8.

  86. Tuck SP, Francis RM, Testosterone, bone and osteoporosis,
    Front Horm Res, 2009;37:123–32.

  87. Bhasin S, Cunningham GR, Hayes FJ, et al., Testosterone therapy
    in men with androgen deficiency syndromes: an Endocrine
    Society clinical practice guideline, J Clin Endocrinol Metab,
    2010;95:2536–59.

  88. Bhasin S, Parker RA, Sattler F, et al., Effects of testosterone
    supplementation on whole body and regional fat mass
    distribution in human immunodeficiency virus-infected
    men with abdominal obesity, J Clin Endocrinol Metab,
    2007;92:1049–57.

  89. Bhasin S, Storer TW, Asbel-Sethi N, et al., Effects of testosterone
    replacement with a nongenital, transdermal system, Androderm,
    in human immunodeficiency virus-infected men with low
    testosterone levels, J Clin Endocrinol Metab, 1998;83:3155–62.

  90. Bhasin S, Storer TW, Javanbakht M, et al., Testosterone
    replacement and resistance exercise in HIV-infected men
    with weight loss and low testosterone levels, JAMA,
    2000;283:763–70.

  91. Rabkin JG, Wagner GJ, Rabkin R, A double-blind placebocontrolled
    trial of testosterone therapy for HIV-positive men with
    hypogonadal symptoms, Arch Gen Psychiatry, 2000;57:141–7.

  92. Knapp PE, Storer TW, Herbst KL, et al., Effects of a
    supraphysiological dose of testosterone on physical function,
    muscle performance, mood, and fatigue in men with HIVassociated
    weight loss, Am J Physiol Endocrinol Metab,
    2008;294(6):E1135–43.

  93. Fairfield WP, Finkelstein JS, Klibanski A, Grinspoon SK, Osteopenia
    in eugonadal men with acquired immune deficiency syndrome
    wasting syndrome, J Clin Endocrinol Metab, 2001;86:2020–6.

  94. Dolan Looby SE, Collins M, Lee H, Grinspoon S, Effects of longterm
    testosterone administration in HIV-infected women: a
    randomized, placebo-controlled trial, AIDS, 2009;23:951–9.

  95. Lo J, You SM, Canavan B, et al., Low-dose physiological growth
    hormone in patients with HIV and abdominal fat accumulation:
    a randomized controlled trial, JAMA, 2008;300:509–19.

  96. Napolitano LA, Schmidt D, Gotway MB, et al., Growth hormone
    enhances thymic function in HIV-1-infected adults, J Clin Invest,
    2008;118:1085–98.

3

Article Information

Disclosure

The authors have no conflicts of interest to declare.

Correspondence

Andrea Giustina, Chair of Endocrinology, A.O. Spedali Civili di Brescia, 25123 Brescia, Italy. E: a.giustina@libero.it
An erratum to this article can be found below.

Received

2013-12-21T00:00:00

4

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