HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:
Guest Access | Sign In via User Name/Password

This Article Abstract Full Text (PDF) Free Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to My Personal Article Archive Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Casaburi, R. Search for Related Content PubMed PubMed Citation Articles by Casaburi, R.

Skeletal Muscle Function in COPD^*

^* From the Division of Respiratory and Critical Care Physiology and Medicine, Harbor-UCLA Medical Center, Torrance, CA.

Correspondence to: Richard Casaburi, PhD, MD, FCCP, Box 405, Harbor-UCLA Medical Center, 1000 W. Carson St, Torrance, CA 90509; e-mail: casaburi{at}ucla.edu

	Abstract

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 
Few effective therapies exist for patients with COPD. Rehabilitative therapy aimed at curing dysfunction of the peripheral muscles may be an appropriate addition to this short list. This review does the following: (1) presents evidence that skeletal muscle dysfunction is present in COPD patients; (2) considers the mechanisms of this dysfunction; (3) describes the role of exercise training in correcting this disorder; and (4) speculates that anabolic hormone supplementation may find a place in COPD therapy. Further research will be necessary to refine these concepts.

Key Words: anabolic • COPD • exercise • growth hormone • muscle • strength • testosterone

	Introduction

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 

Abbreviation: IGF = insulin-like growth factor

Advanced COPD burdens the patient with disabling dyspnea and a host of other symptoms and, because of the high worldwide prevalence of cigarette smoking, the number of afflicted individuals is staggering. Consider how few effective therapies we have to offer our patients afflicted with this miserable disease. Inhaled bronchodilators offer distinct, albeit modest, relief to the majority of patients. Thanks in substantial part to the individual for whom this conference is named, Dr. Thomas L. Petty, we recognize that chronic oxygen therapy is of value for the hypoxemic COPD patient. Does the list end with these two therapies? Lung volume reduction surgery, though much discussed,¹ remains both unproven and unlikely to be an option for the majority of patients. What of the efforts of our colleagues, the cellular and molecular biologists? It may be uncharitable to point out that, despite almost 15 years of siphoning the vast majority of pulmonary science research dollars into cell and molecular biology pursuits, we have no therapies for COPD in hand.

I would argue that pulmonary rehabilitation and, specifically, rehabilitative exercise training should join this short list of therapies with demonstrated efficacy. This argument is much easier to make today than it was 10 years ago. If we consider COPD to be exclusively a disease of the lung, it is hard to understand how exercise training would be of help. Clearly, exercise training does nothing to improve pulmonary mechanics, pulmonary gas exchange, or pulmonary vascular function. Formerly, it was conceded that exercise programs were primarily of psychological value, of use in motivating patients toward a higher level of activity. The current view, however, is to consider COPD a multiorgan system disease. In particular, there is accumulating evidence that the skeletal muscles (most importantly, the muscles of ambulation) do not function normally and that this dysfunction contributes to exercise intolerance. Exercise intolerance is often the COPD patient’s chief complaint.² In this view, rehabilitative exercise training has the goal of treating skeletal muscle dysfunction. Moreover, there are other therapies that might ameliorate skeletal muscle dysfunction, and these might be suitable for administration in the context of pulmonary rehabilitation.

This review will summarize the following evidence obtained to date: (1) skeletal muscle dysfunction is present in COPD; (2) the dysfunction may be multifactorial; (3) exercise training can yield physiologic improvements in muscle function; and (4) anabolic hormone supplementation is rational therapy for this disorder. This topic has also been recently addressed in a Statement of the American Thoracic Society and European Respiratory Society,³ which was composed by an international panel of experts.

	Evidence for Skeletal Muscle Dysfunction in COPD

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 
1. Several recent studies of the vastus lateralis muscle appear to show that structural and biochemical abnormalities exist in COPD patients, although age- and activity-matched control groups have not always been employed. A lower fraction of type I fibers (and higher fraction of type II fibers) are present.^{4 5} A higher fraction of myosin heavy chain type 2B isoform has been found.⁶ These findings would predict relatively poor aerobic function of these muscles. Accentuating the abnormalities in aerobic function, capillary density is decreased,^{5 7} which would result in increased diffusion distances for oxygen transport. Moreover, concentrations of aerobic, but not glycolytic, enzymes are reduced in COPD patients.^{8 9} These findings, along with reports that muscle mass is low¹⁰ (often even if the patient is of normal body weight), are consistent with poor muscle function.

2. Several investigators have shown that lactic acidosis occurs at much lower work rates than in healthy subjects.^{9 11} Evidence supporting this observation is obtained from magnetic resonance spectroscopy; fall in muscle pH occurs at low work rates.¹² Lactic acid accumulates when oxygen transport to the exercising muscle becomes inadequate, and anaerobic glycolysis is called on to supplement aerobic adenosine triphosphate production. Recent studies show that bulk oxygen transport to the lower extremities appears to be adequate.¹³ Therefore, intrinsic abnormalities in the exercising muscles seem to be implicated. Early onset of lactic acidosis can impair the exercise tolerance of COPD patients, in that lactic acid is a ventilatory stimulant, increasing the ventilatory requirement for exercise.¹⁴

3. Although the oxygen-uptake requirements in the steady-state of exercise likely do not differ substantially in the COPD patient as compared to the healthy subject,^{15 16} the kinetics of oxygen uptake are markedly slow.^{16 17} When exercise begins, the oxygen demands of the muscle rise abruptly, but the oxygen extraction from the muscle capillary blood (and the oxygen extraction from the environment) does not reach a steady state for several minutes. This delay constitutes an oxygen debt; a large oxygen debt connotes poor aerobic function.

4. Several surgical series have shown that exercise intolerance remains prominent after single or double lung transplantation. After transplantation, lung mechanics and gas exchange are improved considerably (or even normalized), and the ventilation the patient can sustain no longer limits exercise tolerance. Despite this, exercise intolerance is still present; peak oxygen uptake averages only 40 to 50% predicted.¹⁸ The most reasonable hypothesis to explain this substantial degree of residual exercise intolerance is skeletal muscle dysfunction, although it must be allowed that immunosuppressive drugs that transplant recipients must take may contribute to poor muscle function.

	Possible Mechanisms of Muscle Dysfunction

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 
1. Deconditioning almost certainly is a major contributor to the muscle dysfunction seen in COPD patients.¹⁹ These patients generally assume an extremely sedentary lifestyle to avoid the dyspnea that activity brings. Studies of healthy subjects undergoing bed rest or astronauts experiencing prolonged weightlessness have defined the effects of deconditioning.^{19 20} The muscles of ambulation atrophy, muscle capillary density falls, aerobic enzyme concentrations decrease, and a shift in muscle fiber type from type IIa to type IIb is seen. These changes yield substantial decreases in strength and endurance.

2. Malnutrition may contribute to inability to synthesize muscle protein and may be responsible, in part, for the profound muscle wasting seen in some patients.²¹ However, recent research indicates that inflammatory mediators are elevated in some COPD patients,²² and it is speculated that these mediators may be responsible for weight loss and muscle wasting.

3. Adequate levels of anabolic hormones are required for normal muscle growth and development. There are two well-described anabolic hormone systems. Growth hormone, secreted by the pituitary, has an anabolic effect on muscles principally through stimulating production of insulin-like growth factor (IGF)- 1.²³ In men, testosterone is secreted by the testes and has a substantial anabolic effect on muscle. In women, testosterone plays a less well-understood role; circulating levels are roughly tenfold lower than in men.²⁴ However, some investigators have started to consider the feasibility of testosterone administration to women.²⁵ In healthy elderly subjects, levels of both IGF-1 and testosterone tend to be lower than in the young.^{26 27} Preliminary evidence reveals a considerable prevalence of substantially reduced levels of these circulating hormones in COPD patients.^{28 29}

4. Corticosteroids are known to cause muscle weakness. Both acute and chronic steroid myopathies have been described. The former is a profound general muscle weakness, uncommonly seen several days after treatment with high doses of IV corticosteroids.³⁰ Chronic steroid myopathy is a more common occurrence, seen after prolonged administration of lower doses of corticosteroids.³¹ The time course of reversal of chronic steroid myopathy is unclear; it seems possible that many months may be required.

5. It is altogether possible that there is a specific myopathy associated with COPD. Chronic hypoxemia or hypercapnia³ or the effects of cigarette smoking could conceivably damage the muscles. Comorbid conditions may also play a role. Electrolyte imbalance is known to impair skeletal muscle function.³² Cardiac failure is known to induce changes in muscle structure,³³ although these data have been gathered in patients with congestive heart failure, not cor pulmonale.

	Exercise Training Yields Improvements in Muscle Function in COPD

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 
The past 10 years have seen the accumulation of data supporting the concept that exercise programs are capable of inducing physiologic changes in the muscles of ambulation that improve exercise tolerance in COPD. Several pieces of evidence to support physiologic benefit can be cited.

1. Muscle biopsies performed before and after a rigorous endurance training program have demonstrated that concentrations of the enzymes facilitating oxidative metabolism are increased.³⁴

2. A given level of heavy exercise can be performed with a smaller increase in blood lactic acid level after a training program.^{11 35 36} This is associated with a proportionally lower level of carbon dioxide output and of ventilation.¹¹

3. After a training program, following the onset of constant work rate exercise, the kinetics of oxygen uptake are faster.¹⁷ This indicates better aerobic function of the muscles.

These physiologic improvements in muscle function only occur after a rigorous program of endurance training. Though physiologically based principles for exercise prescription in COPD patients have not been fully defined,³⁷ certain principles are likely to be true. As in healthy subjects, programs need to last for 5 to 8 weeks, sessions need to be held 3 to 5 times per week, and sessions need to be 30 to 45 min in duration to achieve a substantial aerobic training effect.³⁸ Exercise intensity prescription is controversial, but some authors have posited that high fractions of the peak work rate achievable (perhaps 75 to 85%) is an achievable goal.³⁹ Such training programs have been shown to yield substantial increases in exercise tolerance in patients with both moderate and severe COPD.^{11 17}

	Anabolic Hormone Supplementation is Rational Therapy for COPD Patients

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 
In view of preliminary evidence that COPD patients have low circulating levels of IGF-1 and (in men) testosterone, hormone supplementation seems an attractive method to reverse muscle dysfunction. However, not all anabolic stimuli to muscle yield similar effects. For example, endurance and strength training programs have substantially different effects on the exercising muscles. Endurance programs increase capillarity, aerobic enzyme concentrations, and mitochondrial number, but do not cause appreciable muscle fiber hypertrophy. Strength training programs, in contrast, induce dramatic hypertrophy, which increases the potential for force generation for explosive tasks, but do not yield changes that decrease diffusion distances for oxygen. Therefore, strength training increases strength and endurance training increases endurance. From studies in healthy subjects, there is preliminary evidence that both growth hormone and testosterone administration predominantly induce hypertrophy, similar to a strength training adaptation.⁴⁰ Though this conclusion is speculative, it seems unreasonable to expect that either growth hormone or testosterone administration will increase exercise endurance. However, decreased strength is commonly seen in COPD patients^{41 42} and strength is required for many everyday activities.

When growth hormone is given to growth hormone-deficient adults, muscle mass increases and strength improves. In healthy young subjects, growth hormone administration causes muscle protein synthesis to increase.⁴³ In healthy older subjects and patients with HIV-wasting syndrome, growth hormone yields increases in muscle mass.^{44 45} However, studies of functional capabilities have yielded mixed results. In COPD, a 3-week study of thrice-weekly growth hormone administration found evidence of increased muscle mass, but no change in endurance exercise capacity.⁴⁶ Because growth hormone must be administered by injection several times per week, because it is quite expensive, and because of equivocal evidence of improved exercise tolerance, questions have been raised regarding the usefulness of growth hormone as therapy for patients with chronic disease.⁴⁷

The administration of testosterone to men whose testicular production is inadequate clearly increases muscle mass and strength.⁴⁸ However, the widespread use of anabolic steroids by athletes and body builders has generated nearly a half century of controversy. It was widely believed by the sports medicine community that supraphysiologic doses of testosterone yield muscle hypertrophy and improved performance. Anecdotal evidence of effectiveness, followed by the publication of > 12 studies conducted mostly in the 1970s, proved inconclusive.⁴⁹ However, the issue seems to have been settled by a publication of a randomized, well-controlled 10-week trial of supraphysiologic doses of testosterone enanthate delivered in weekly injections.⁵⁰ Lean body mass and muscle strength increased substantially, and strength training yielded additive effects. Only a few studies have examined the effect of anabolic steroids in patients with chronic disease. In men with AIDS-wasting syndrome, replacement doses of testosterone increased lean body mass, but the change in the 6-min walk distance was not significantly different from the control group.⁵¹ Nandrolone (an orally administered anabolic steroid) or placebo was given to 217 men and women with COPD.⁵² A small increase in lean body mass and a small increase in maximum inspiratory pressure was seen in the nandrolone group. Recently, 6 months of oral stanozolol yielded a mean 1.8-kg increase in lean body mass but no increase in endurance exercise tolerance in 10 underweight COPD patients.⁵³ Before anabolic steroids can be routinely prescribed for patients with COPD, safety concerns must be addressed.^{54 55} There is a theoretic risk that an occult prostate malignancy might be stimulated to grow faster, although fairly large studies of elderly men are reassuring. Since testosterone stimulates erythrocyte production,⁵⁶ a tendency toward polycythemia might be exacerbated.

In summary, curing the dysfunction of the peripheral musculature of patients with COPD may in the near future become a routine part of the therapeutic plan. Research into the nature of the defect in muscle function, optimal exercise strategies, and more beneficial anabolic drugs is likely to be productive.

	Footnotes

 
Supported by the Tobacco Related Disease Research Program of the University of California.

	References

TOP Abstract Introduction Evidence for Skeletal Muscle... Possible Mechanisms of Muscle... Exercise Training Yields... Anabolic Hormone Supplementation... References

 

1. Fessler, HE, Wise, RA (1999) Lung volume reduction surgery: is less really more? Am J Respir Crit Care Med 159,1031-1035[Free Full Text]
2. Casaburi, R (1993) Exercise training in chronic obstructive lung disease. Casaburi, R Petty, TL eds. Principles and practice of pulmonary rehabilitation ,204-224 WB Saunders Philadelphia, PA.
3. Skeletal muscle dysfunction in chronic obstructive pulmonary disease: a statement of the American Thoracic Society and European Respiratory Society. Am J Respir Crit Care Med 1999; 159:S1–S40
4. Jakobsson, P, Jorfeldt, L, Brundin, A (1990) Skeletal muscle metabolites and fiber types in patients with advanced chronic obstructive pulmonary disease (COPD), with and without chronic respiratory failure. Eur Respir J 3,192-196[Abstract]
5. Whittom, F, Jobin, J, Simard, P-M, et al (1998) Histochemical and morphological characteristics of the vastus lateralis muscle in COPD patients. Med Sci Sports Exerc 30,1467-1474[ISI][Medline]
6. Satta, A, Migliori, GB, Spanevello, A, et al (1997) Fiber types in skeletal muscles of chronic obstructive pulmonary disease patients related to respiratory function and exercise tolerance. Eur Respir J 10,2853-2860[Abstract]
7. Jobin, J, Maltais, F, Doyon, JF, et al (1998) Chronic obstructive pulmonary disease: capillarity and fiber-type characteristics of skeletal muscle. J Cardiopulm Rehab 18,432-437[CrossRef][Medline]
8. Jakobsson, P, Jordfelt, L, Henriksson, J (1995) Metabolic enzyme activity in the quadriceps femoris muscle in patients with severe chronic obstructive pulmonary disease. Am J Respir Crit Care Med 151,374-377[Abstract]
9. Maltais, F, Simard, A-A, Simard, C, et al (1996) Oxidative capacity of the skeletal muscle and lactic acid kinetics during exercise in normal subjects and in patients with COPD. Am J Respir Crit Care Med 153,288-293[Abstract]
10. Schols, AMWJ, Wouters, EFM, Soeters, PB, et al (1991) Body composition by bioelectrical impedance analysis compared to deuterium dilution and skinfold anthropometry in patients with chronic obstructive pulmonary disease. Am J Clin Nutr 53,421-424[Abstract/Free Full Text]
11. Casaburi, R, Patessio, A, Ioli, F, et al (1991) Reductions in exercise lactic acidosis and ventilation as a result of exercise training in patients with obstructive lung disease. Am Rev Respir Dis 143,9-18[ISI][Medline]
12. Payen, JF, Wuyam, B, Levy, P, et al (1993) Muscular metabolism during oxygen supplementation in patients with chronic hypoxemia. Am Rev Respir Dis 147,592-598[ISI][Medline]
13. Maltais, F, Jobin, J, Sullivan, MJ, et al (1998) Lower limb metabolic and hemodynamic responses during exercise in normal subjects and in COPD. J Appl Physiol 84,1573-1580[Abstract/Free Full Text]
14. Casaburi, R, Storer, TW, Wasserman, K (1987) Mediation of reduced ventilatory response to exercise after endurance training. J Appl Physiol 63,1533-1538[Abstract/Free Full Text]
15. Gallager, CG (1994) Exercise limitation and clinical exercise testing in chronic obstructive pulmonary disease. Clin Chest Med 15,305-326[ISI][Medline]
16. Nery, LE, Wasserman, K, Andrews, JD, et al (1982) Ventilatory and gas exchange kinetics during exercise in chronic airways obstruction. J Appl Physiol 53,1594-1602[Abstract/Free Full Text]
17. Casaburi, R, Porszasz, J, Burns, MR, et al (1997) Physiologic benefits of exercise training in rehabilitation of severe COPD patients. Am J Respir Crit Care Med 155,1541-1551[Abstract]
18. Casaburi, R (1996) Deconditioning. Fishman, AP eds. Pulmonary rehabilitation ,213-230 Marcel Dekker New York, NY.
19. Mercier, JR, Hokanson, JF, Brooks, GA (1995) Effects of cyclosporin A on skeletal muscle mitochondrial respiration and endurance times in rats. Am J Respir Crit Care Med 151,1848-1851[Abstract]
20. Bloomfield, SA (1997) Changes in musculoskeletal structure and function with prolonged bed rest. Med Sci Sports Exerc 29,197-206[ISI][Medline]
21. Rochester, DF (1992) Nutritional repletion. Semin Respir Med 13,44-52
22. Schols, AM, Buurman, WA, Staal van den Brekel,, et al (1996) Evidence for a relation between metabolic derangements and increased levels of inflammatory mediators in a subgroup of patients with chronic obstructive pulmonary disease. Thorax 51,819-824[Abstract/Free Full Text]
23. LeRoith, D, Adama, M, Werner, H, et al (1991) Insulin-like growth factors and their receptors as growth regulators in normal physiology and pathologic states. Trends Endocrinol Metab 2,134-139[CrossRef]
24. Sinha-Hikim, I, Arver, S, Beall, G, et al (1998) The use of a sensitive equilibrium dialysis method for the measurement of free testosterone levels in healthy, cycling women and in human immunodeficiency virus-infected women. J Clin Endocrinol Metab 83,1312-1318[Abstract/Free Full Text]
25. Davis, SR, Burger, HG (1998) The rationale for physiological testosterone replacement in women. Bailliere’s Clin Endrocrinol Metab 12,391-405
26. Davidson, JM, Chen, JJ, Crapo, L, et al (1983) Hormonal changes and sexual function in aging men. J Clin Endrocrinol Metab 57,71-77[Abstract]
27. Rudman, D, Mattson, DE, Nagraj, HS (1988) Plasma testosterone in nursing home men. J Clin Epidemiol 41,231-236[CrossRef][ISI][Medline]
28. Casaburi, R, Goren, S, Bhasin, S (1996) Substantial prevalence of low anabolic hormone levels in COPD patients undergoing rehabilitation [abstract]. Am J Respir Crit Care Med 153,A128
29. Semple, D’AP, Beastall, GH, Watson, WS, et al (1980) Serum testosterone depression associated with hypoxia in respiratory failure. Clin Sci 58,105-106[Medline]
30. Shee, CD (1990) Risk factors for hydrocortisone myopathy in acute severe asthma. Respir Med 84,229-233[ISI][Medline]
31. DeCramer, M, deBock, V, Dom, R (1996) Functional and histologic picture of steroid-induced myopathy in chronic obstructive pulmonary disease. Am J Respir Crit Care Med 153,1958-1964[Abstract]
32. Fiaccadori, E, Coffrini, E, Fracchia, C, et al (1994) Hypophosphatemia and phosphorus depletion in respiratory and peripheral muscles of patients with respiratory failure due to COPD. Chest 105,1392-1398[Abstract/Free Full Text]
33. Sullivan, MJ, Green, HJ, Cobb, FR (1990) Skeletal muscle biochemistry and histology in ambulatory patients with long-term heart failure. Circulation 81,518-527[Abstract/Free Full Text]
34. Maltais, F, Leblanc, P, Simard, C, et al (1996) Skeletal muscle adaptation to endurance training in patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med 154,442-447[Abstract]
35. Mohsenifar, Z, Horak, D, Brown, HV, et al (1983) Sensitive indices of improvement in a pulmonary rehabilitation program. Chest 83,189-192[Abstract/Free Full Text]
36. Vallet, G, Ahmaidi, S, Serres, I, et al (1997) Comparison of two training programmes in chronic airway limitation patients: standardized versus individualized protocols. Eur Respir J 10,114-122[Abstract]
37. Casaburi, R (1998) Special considerations for exercise training in chronic lung disease. ACSM resource manual: guidelines for exercise testing and prescription 3rd ed. ,334-338 Williams and Wilkins Baltimore, MD.
38. . American College of Sports Medicine Position Stand. (1998) The recommended quantity and quality of exercise for developing and maintaining cardiorespiratory and muscular fitness in healthy adults. Med Sci Sports Exerc 30,975-991[ISI][Medline]
39. Punzal, PA, Ries, AL, Kaplan, RM, et al (1991) Maximum intensity exercise training in patients with chronic obstructive pulmonary disease. Chest 100,618-623[Abstract/Free Full Text]
40. Sipilä, S, Suominen, H (1995) Effects of strength and endurance training on thigh and leg muscle mass and composition in elderly women. J Appl Physiol 75,334-340[Abstract/Free Full Text]
41. Gosselink, R, Troosters, T, Decramer, M (1996) Peripheral muscle weakness contributes to exercise limitation in COPD. Am J Respir Crit Care Med 153,976-980[Abstract]
42. Bernard, S, Leblanc, P, Whittom, F, et al (1998) Peripheral muscle weakness in patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med 158,629-634[Abstract/Free Full Text]
43. Cuneo, RC, Salomon, F, Wiles, CM, et al (1991) Growth hormone treatment in growth hormone-deficient adults: I. Effects on muscle mass and strength. J Appl Physiol 70,688-694[Abstract/Free Full Text]
44. Papadakis, MA, Grady, D, Black, D, et al (1996) Growth hormone replacement in healthy older men improves body composition but not functional ability. Ann Intern Med 124,708-716[Abstract/Free Full Text]
45. Schambelan, M, Mulligan, K, Grunfeld, C, et al (1996) Recombinant human growth hormone in patients with HIV-associated wasting. Ann Intern Med 125,873-882[Abstract/Free Full Text]
46. Burdet, L, deMuralt, B, Schultz, Y, et al (1997) Administration of growth hormone to underweight patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med 156,1800-1806[Abstract/Free Full Text]
47. Mantzoros, CS, Moses, AL (1996) Whither recombinant human growth hormone? Ann Intern Med 125,932-934[Free Full Text]
48. Bhasin, S, Storer, TW, Berman, N, et al (1997) Testosterone replacement increases fat-free mass and muscle size in hypogonadal men. J Clin Endrocrinol Metab 82,407-413[Abstract/Free Full Text]
49. Casaburi R, Storer TW, Bhasin S. Testosterone effects on body composition and muscle performance. In: Bhasin S, Gabelnick H, Spieler J, et al, eds. Androgens: biology, pharmacology and clinical applications, New York, NY: Wiley Liss, 1996; 283–288
50. Bhasin, S, Storer, TW, Berman, N, et al (1996) The effects of supraphysiological doses of testosterone on muscle size and strength in normal men. N Engl J Med 335,1-7[Abstract/Free Full Text]
51. Grinspoon, S, Corcoran, C, Askari, H, et al (1998) Effects of androgen administration in men with the AIDS wasting syndrome. Ann Intern Med 129,18-26[Abstract/Free Full Text]
52. Schols, AM, Soeters, PB, Mostert, R, et al (1995) Physiologic effects of nutritional support and anabolic steroids in patients with chronic obstructive pulmonary disease: a placebo controlled randomized trial. Am J Respir Crit Care Med 152,1268-1274[Abstract]
53. Ferriera, EM, Verreschi, IT, Nery, LE, et al (1998) The influence of 6 months of oral anabolic steroids on body mass and respiratory muscles in undernourished COPD patients. Chest 114,19-28[Abstract/Free Full Text]
54. Bagatell, CJ, Bremner, WJ (1996) Androgens in men: uses and abuses. N Engl J Med 334,707-714[Free Full Text]
55. Rolf, C, Nieschlag, E (1998) Potential adverse effects of long-term testosterone therapy. Bailliere’s Clin Endocrinol Metab 12,521-534[CrossRef][ISI][Medline]
56. Brinka, PJ, Jochen, AL, Cuisinier, M, et al (1995) Polycythemia as a complication of testosterone replacement therapy in nursing home men with low testosterone levels. J Am Geriatric Soc 43,899-901[ISI][Medline]

This Article Abstract Full Text (PDF) Free Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to My Personal Article Archive Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Casaburi, R. Search for Related Content PubMed PubMed Citation Articles by Casaburi, R.