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Systemic manifestations in chronic obstructive pulmonary disease

Manifestações sistêmicas na doença pulmonar obstrutiva crônica

Victor Zuniga Dourado, Suzana Erico Tanni, Simone Alves Vale, Márcia Maria Faganello, Fernanda Figueirôa Sanches, Irma Godoy

ABSTRACT

Chronic obstructive pulmonary disease is progressive and is characterized by abnormal inflammation of the lungs in response to inhalation of noxious particles or toxic gases, especially cigarette smoke. Although this infirmity primarily affects the lungs, diverse extrapulmonary manifestations have been described. The likely mechanisms involved in the local and systemic inflammation seen in this disease include an increase in the number of inflammatory cells (resulting in abnormal production of inflammatory cytokines) and an imbalance between the formation of reactive oxygen species and antioxidant capacity (leading to oxidative stress). Weakened physical condition secondary to airflow limitation can also lead to the development of altered muscle function. Chronic obstructive pulmonary disease presents diverse systemic effects including nutritional depletion and musculoskeletal dysfunction (causing a reduction in exercise tolerance), as well as other effects related to the comorbidities generally observed in these patients. These manifestations have been correlated with survival and overall health status in chronic obstructive pulmonary disease patients. In view of these facts, the aim of this review was to discuss findings in the literature related to the systemic manifestations of chronic obstructive pulmonary disease, emphasizing the role played by systemic inflammation and evaluating various therapeutic strategies.

Keywords: Pulmonary disease, chronic obstructive/complications; Nutritional status; Exercise tolerance;

RESUMO

A doença pulmonar obstrutiva crônica é progressiva e está relacionada a uma resposta inflamatória anormal dos pulmões à inalação de partículas e/ou gases tóxicos, sobretudo a fumaça de cigarro. Embora acometa primariamente os pulmões, diversas manifestações extrapulmonares relacionadas a esta enfermidade têm sido descritas. O aumento do número de células inflamatórias, que resulta em produção anormal de citocinas pró-inflamatórias, e o desequilíbrio entre a formação de radicais livres e a capacidade antioxidante, resultando em sobrecarga oxidativa, provavelmente são mecanismos envolvidos na inflamação local e sistêmica. Além disso, a diminuição do condicionamento físico secundária às limitações ventilatórias pode estar envolvida no desenvolvimento de alterações musculares. A doença pulmonar obstrutiva crônica apresenta diversas manifestações sistêmicas que incluem a depleção nutricional, a disfunção dos músculos esqueléticos, que contribui para a intolerância ao exercício, e as manifestações relacionadas a co-morbidades comumente observadas nestes pacientes. Essas manifestações têm sido relacionadas à sobrevida e ao estado geral de saúde dos pacientes. Nesse sentido, esta revisão tem como objetivo discutir os achados da literatura relacionados às manifestações sistêmicas da doença pulmonar obstrutiva crônica, ressaltando o papel da inflação sistêmica, e algumas perspectivas de tratamento.

Palavras-chave: Doença pulmonar obstrutiva crônica/complicações; Estado nutricional; Toterância ao exercício;

INTRODUCTION

Chronic obstructive pulmonary disease (COPD) is defined as a preventable and treatable respiratory disease characterized by partially reversible chronic airflow obstruction. This obstruction is progressive and is characterized by abnormal inflammation of the lungs in response to inhalation of noxious particles or toxic gases, especially cigarette smoke. Although COPD primarily affects the lungs, there are diverse systemic manifestations related to this infirmity.(1) The local and systemic manifestations of COPD are summarized in Figure 1.

Airway inflammation and destruction of lung parenchyma are the changes that are characteristic of COPD and contribute to airflow limitation, which is a functional marker of the disease. However, the clinical profile and the repercussions on the overall patient heath status suffer the influence of the chronic manifestations of COPD and reinforce the need for a multidimensional approach that takes into consideration all of the components of the disease.(2)





In addition to airway inflammation, there is evidence of systemic inflammation in patients with COPD, although the relationship between local and systemic inflammation has yet to be established.(2-3) There is also evidence of an imbalance between the formation of reactive oxygen species and antioxidant capacity, leading to oxidative stress in the lungs.
This imbalance is involved in the pathogenesis of the disease and can cause cell damage, mucous hypersecretion, antiprotease inactivation and increased pulmonary inflammation through the activation of transcription factors.(4)

There is recent evidence of changes similar to those affecting the lung. Oxidative stress and inflammation might be involved in the mechanisms of development of the systemic effects of COPD.(4) Patients with COPD present weight loss, which is an independent indicator of disease outcome.(5) Loss of lean body mass also results in peripheral muscle dysfunction, reduction in exercise tolerance and lower quality of life, alterations that are important determinants of prognosis and survival among patients with COPD.(6-7) Therefore, indices that include local and systemic manifestations of COPD might be more appropriate for determining the survival rate of these patients. In fact, the evaluation of and measures to improve nutritional status and exercise tolerance are included in the recommendations of the Global Initiative for Chronic Obstructive Lung Disease.(8)

In view of the negative repercussions that the systemic manifestations of COPD have on exercise tolerance, prognosis and patient survival, the aim of this review was to discuss the main findings in the literature regarding the systemic manifestations of COPD. We will address nutritional depletion, peripheral skeletal muscle dysfunction and other effects related to the comorbidities generally observed in patients with COPD. In addition, the role of systemic inflammation will be discussed, as will therapeutic strategies. The Medline and Lilacs databases were reviewed using the keywords related to the topics of the present study, and the searches were limited to studies published within the last fifteen years.

NUTRITIONAL STATUS

Weight loss has been described as a clinical sign in the evolution of patients with COPD since the 1960s, and it has been associated with poor survival rates.(9) The prevalence of malnutrition varies, ranging from 26% to 47% among patients with COPD.(10-11) Retrospective studies have indicated that reductions in body weight, resulting in values below 90% of the ideal weight and in low body mass indices, are negative prognostic factors, independent of the severity of the disease.(5) Body mass index and survival are inversely related in patients with COPD.(5,12) In all of the groups, weight loss is associated with increased mortality. In addition, patients with severe COPD and body mass indices lower than 25 kg/m2 present better survival rates after gaining weight.(13)

Several etiologies have been proposed for the nutritional deficiency observed in patients with COPD. However, the mechanisms involved have yet to be well elucidated.(14) Imbalance between energy intake and energy expenditure, due to decreased intake or increased expenditure, seems to be the factor involved in most cases.(15) The possible mechanisms involved in weight loss in patients with COPD are schematically presented in Figure 2.






Elevated levels of pro-inflammatory cytokines have been related to weight loss and wasting.(16) The results of clinical and experimental studies suggest that the liberation of inflammatory mediators can contribute to the development of hypermetabolism, to reduced energy intake and to an inadequate response to caloric intake, leading to the nutritional alterations observed in patients with COPD. Cytokines such as tumor necrosis factor-alpha (TNF-a) and interleukin (IL)-1B can cause anorexia and proteolysis, the latter related to the activation and acceleration of the enzyme ubiquitin, a proteasome present in the peripheral skeletal muscles. Alterations in the leptin metabolism might also be involved in the development of nutritional changes in patients with COPD. Leptin is a signal for cerebral and peripheral tissue alterations as well as regulating caloric intake, basal energy expenditure and body weight. The results of the few studies that have been conducted on the topic suggest that inflammation can alter the leptin metabolism in patients with COPD. However, the role that leptin plays in the development of nutritional changes in these patients is unknown, and further studies are needed in order to understand it.(17)

We should also take into consideration that patients with COPD frequently present hypoxemia, especially in the advanced stages of the disease. Some data in the literature suggest that hypoxemia could stimulate the production of inflammatory mediators and participate in the development of the nutritional changes seen in patients with COPD.(18)
Malnourished patients present more intense dyspnea, lower quality of life and lower exercise tolerance.(19-20)

Body mass index and weight loss are risk factors for hospitalization due to the exacerbation of the disease, are indicative of a poor prognosis in the evolution of the exacerbation and can be determinants of the need for mechanical ventilation.(21) In addition, survival time after the exacerbation has been found to correlate, in an independent way, with body mass index, and low body mass index has been found to correlate with an increase in postoperative morbidity in patients submitted to lung volume reduction surgery.(23) Nutritional depletion has also been associated with the higher mortality rates and greater frequency of hospitalization among patients with COPD on prolonged home oxygen therapy.(25)

Therapeutic strategy
Recently, the Cochrane Library published a meta-analysis in which the available studies of nutritional supplementation in patients with COPD were re-evaluated.(25) The authors found that food supplementation had no effect on anthropometric measurements, pulmonary function or exercise tolerance. However, recent studies have shown that food supplementation provides benefits for certain subgroups of COPD patients and for those presenting less accentuated nutritional changes.(26)

Despite their side effects, anabolic steroids might be an option for increasing muscle mass and improving function in patients who do not respond to traditional nutritional therapy.(26) In one study, it was shown that patients with COPD who receive anabolic steroids for short periods present an increase in lean body mass without any significant side effects.(26) However, the authors of that study found no improvement in exercise tolerance or dyspnea. Among the principal risks of androgen administration, specifically in women, are masculinization, skin reactions, altered plasma lipids and behavioral changes.(27) Prolonged androgen therapy can increase the risk of cardiovascular events due to the decrease in HDL cholesterol levels. The literature presents inconsistent data regarding the correlation between androgen supplementation and the development of breast cancer.(27)

Further studies are needed in order to investigate the additional benefits of anabolic steroid therapy in terms of exercise tolerance and quality of life. In addition, the type of exercise combined with the anabolic therapy must be investigated since strength training has a greater influence on the metabolism of testosterone and amino acids.(28)

CHANGES IN RESPIRATORY MUSCLE FUNCTION

Patients with COPD frequently present weakness and decreased respiratory muscle endurance. The factors that can deteriorate muscle function and structure can be classified into two groups: intrinsic and extrinsic.(29) Among the extrinsic factors are geometric changes in the chest wall, changes in lung volume, and systemic metabolic factors. As intrinsic factors, changes in muscle fiber size, sarcomere length, muscle mass and muscle metabolism have been reported.(29)

Pulmonary hyperinflation is one of the factors that affect muscle function. Hyperinflation changes the shape and geometry of the chest wall and leads to a chronic reduction in the diaphragm apposition zone.(30) In addition, the flattening of the diaphragm reduces fiber length, which is an important determinant of the force-generating capacity of a muscle.
In patients with COPD, the diaphragm works under an increased mechanical load due to the airflow limitation and the geometric changes to the thorax resulting from pulmonary hyperinflation. In addition to the mechanical disadvantage, other changes, such as altered electrolytic status, as well as effects on proinflammatory mediators and growth factor, can interfere with respiratory muscle function. The diaphragms of such patients preserve the intrinsic capacity to generate pressure, but muscle function can be affected by the extrinsic factors.(31) There are also changes in the diaphragm structure. Those changes are characterized by an increase in the percentage of type I fibers and a reduction in the percentage of type II fibers, as well as by an increase in the oxidative capacity of all fibers.(32) These adaptations indicate aerobic adaptation of the diaphragm in response to the disease. However, that adaptation is insufficient to restore strength and endurance to their normal values.

CHANGES IN PERIPHERAL SKELETAL MUSCLE FUNCTION

Patients with COPD who use the resources of the health services approximately twice a year present significantly greater quadriceps strength than do those who use these services more frequently.(33) A cross-sectional area of the thigh, evaluated through tomography, of less than 70 cm2 has been implicated as the principal predictor of mortality and as the point at which catabolism prevails over anabolism in patients with COPD.(6,34) These results suggest that the structure and function of the peripheral muscles have a significant impact on the overall health status of patients with COPD. The muscles of patients with COPD can present changes in strength, mass, morphology and bioenergetics, which are described below.

Muscle strength and mass
Muscle weakness is proportional to loss of muscle mass.(29) There is evidence that patients with COPD present a significant reduction in upper and lower limb strength when compared to matched controls.(35) In addition, the cross-sectional area of the thigh is significantly smaller in patients with COPD.(35)

Reduction in muscle strength is predominant in the lower limbs. Among the possible explanations for this are the fact that activities related to gait development are usually avoided by patients with COPD due to the sensation of dyspnea, as well as the predominance of upper-limb use in the performance of daily activities and the great number of scapular girdle muscles responsible for the elevation of the arms participating concomitantly in the accessory respiration. These are the mechanisms that are most responsible for upper limb muscle strength being relatively preserved in patients with COPD.(29,35)

Muscle morphology
Reduction in the muscle contractile activity influences tropism, as well as affecting the balance between muscle synthesis and muscle degradation.(37) As a consequence of prolonged disuse and immobilization, there is a predominance of slow-twitch muscle fibers in healthy individuals. This muscle fiber profile has been identified in patients with COPD.(38)
In addition to the muscle fiber redistribution observed in patients with COPD, there is evidence that the cross-sectional area of all (slow-twitch and fast-twitch) muscle fibers is significantly reduced in patients with COPD.(38)

Muscle bioenergetics
In studies that used material collected through vastus lateralis muscle biopsies, it was observed that patients with COPD present a significant reduction in oxidative enzymes,(39-41) together with a lack of a reduction in glycolytic enzyme levels,(29,39-41) or even an increase in the same.(29,41) Another bioenergetic change reported in patients with COPD is the reduction in the metabolism of muscle phosphocreatine,(29) one of the main factors involved in the lactate anaerobic metabolism.(42)
In summary, patients with COPD present low oxidative capacity, normal or increased glycolytic capacity, and decreased lactate anaerobic metabolism.(39,41) A slowing of the anaerobic lactate metabolism,(29) which is responsible for high-intensity, short-duration activities,(42) concomitant with a reduction in oxidative activity, reinforces the predominance of the anaerobic lactate system in patients with COPD,(43) which results in early-onset lactic acidosis and exercise intolerance.(29)

ETIOLOGY OF PERIPHERAL SKELETAL MUSCLE DYSFUNCTION

Figure 3 summarizes the main etiological factors of peripheral skeletal muscle dysfunction in patients with COPD. Changes in skeletal muscles have been related to various factors, including decreased physical conditioning, metabolism of amino acids, systemic inflammation and oxidative stress. The different mechanisms are briefly described herein.





Decreased conditioning
When exposed to repetitive dynamic situations, patients with COPD present an increase in the ventilatory demand, which forces them to avoid these activities and, as a consequence, they suffer from chronic sedentary behavior.(29) This, in turn, reduces strength and muscle mass, as well as aerobic capacity, resulting in an even more intense ventilatory demand for the same dynamic activities, closing the dyspnea-sedentary lifestyle-dyspnea cycle.(29) Due to this knowledge and to findings in the literature, it became necessary to investigate the changes in muscle function that might be responsible for the exercise intolerance seen in patients with COPD.(15,29)

Muscle fiber redistribution (with an increase in the percentage of type I fibers, a decrease in oxidative enzymes and the maintenance of glycolytic enzymes commonly found in patients with COPD) has been related to hypoxemia.(15) However, various authors have reported that muscle fiber redistribution is a consequence of immobility, a situation that principally affects type I fibers. In addition, the fact that the functional, morphological and bioenergetic changes are totally reversible after appropriate reconditioning programs(39) reinforces the participation of chronic reduction in conditioning as the main mechanism of the peripheral skeletal muscle dysfunction.

The bioenergetic changes found in patients with COPD are explained, in part, by the chronic reduction in conditioning frequently present in these patients. In normal individuals, during periods of inactivity, there is initially a reduction in the aerobic capacity due to the reduction in the systolic volume and in the cardiac index and, subsequently, there is a reduction in the capacity to extract oxygen.(42) In normal individuals, the mitochondrial density can be increased, doubling its value over five weeks of training. However, a week of inactivity is responsible for the loss of 50% of what was achieved in five weeks of training.(42) Three or four weeks of reconditioning are needed for the mitochondrial density to recover its previous density.(42)

Similarly, in biopsies performed on the anterior tibial and deltoid muscles,(44,45) no enzyme changes were observed in the vastus lateralis. In a study evaluating the anterior tibial enzyme profiles of patients with COPD who were not treated with corticosteroids (n = 15), patients under treatment with prednisolone (n = 14), and homogeneous controls (n = 10), the results presented no evidence of changes in the enzyme profiles of the two groups of patients with COPD. Similarly, other authors(45) evaluated the enzyme and muscle fiber profiles in patients with COPD and in homogeneous control individuals through deltoid biopsies. Those authors found no differences between the groups. There was no redistribution of muscle fibers, and the concentration of citrate synthase was found to be similar between the group of patients with COPD and the control group.

The evidence of unchanged enzyme and muscle fiber profiles in postural and upper limb muscles implicates disuse as the main cause of muscle changes in patients with COPD. First, the anterior tibial muscle plays a role in posture maintenance. Therefore, it is essentially comprised of type I fibers and is constantly active. Second, most of the daily activities are performed using the upper limbs, and this propitiates almost constant activity for the deltoid. The high degree of activity of these muscles probably guarantees the preservation of muscle function, structure and bioenergetics.

The influence of the metabolism of amino acids
Some COPD manifestations jeopardize the metabolism of amino acids and promote muscle loss in affected patients.(37) Patients with COPD present changes in the profile of plasma and skeletal muscle amino acids.(37) Lower serum concentrations of glutamate, glutamine and alanine have been found in patients with emphysema who suffer from nutritional depletion.(46) In addition, branched chain amino acids, especially alanine, are found in low plasma concentrations in patients with COPD. This reduction is more evident in patients with lower than normal body weight.(47)

These amino acids perform various important functions: alanine interferes with glyconeogenesis; glutamine is metabolized in the liver and in the gastrointestinal tract, energizing leukocytes and fibroblasts; and glutamate participates in all transamination reactions in the skeletal muscles.(37)

The influence of systemic inflammation
Production of insulin-like growth factor 1, which mediates the growth hormone anabolic action, is counter-regulated by TNF-a, IL-1 and IL-6.(48) In addition, elevated levels of IL-6 correlate negatively with levels of testosterone and dehydroepiandrosterone, which also have anabolic effects.(34) The negative effect that IL-6 has on the functional capacity of elderly individuals has been described by some authors.(49) Higher IL-6 levels are associated with poor survival rates and significant impairment of the functional capacity in elderly individuals.(50)

The influence of the pro-antioxidant metabolism
Some authors have suggested that the participation of the imbalance of the pro-antioxidant metabolism in patients with COPD is an important mechanism in the determination of musculoskeletal dysfunction in this population.(51-52) In 2003, some authors(51) evaluated the systemic oxidative stress caused by localized exercise of the quadriceps. The authors measured the plasma levels of thiobarbituric acid reactive substances and the production of oxygen-derived free radicals as an index of oxidative stress index and the vitamin E levels as antioxidants. Patients with COPD presented significantly lower quadriceps muscle resistance than did homogeneous control individuals. The concentration of thiobarbituric acid reactive substances was significantly higher in patients with COPD six hours after having performed the exercise. In patients with COPD, vitamin E levels were significantly lower than in the control individuals, and thiobarbituric acid reactive substances were found to correlate negatively and significantly with vitamin E, a correlation not found in control individuals.

Other authors(52) evaluated, through vastus lateralis biopsy, reduced glutathione activity and oxidized glutathione activity in seventeen patients with COPD and five homogeneous control individuals. When the individuals were submitted to only one session of submaximal training, there were no significant differences in the reduced glutathione or in the oxidized glutathione profiles, either in the patients with COPD or in the controls. However, when the analysis was performed after an eight-week treatment regimen (five sessions per week), there was a significant increase in the reduced glutathione levels in the control group, whereas, in the individuals with COPD, there was no statistically significant difference.
These findings suggest that patients with COPD are incapable of improving their antioxidant capacity after a physical conditioning regimen, in contrast to what commonly occurs in healthy individuals.

TREATMENT STRATEGIES

Aerobic exercise
Aerobic exercise is recommended for individuals with COPD and should be initiated regardless of the COPD stage at which the patient is determined to be.(8) This kind of training increases mitochondrial oxidative enzyme levels, capillarization of the trained muscles, aerobic threshold and maximum oxygen uptake, as well as decreasing creatine-phosphate recovery time, thereby resulting in greater exercise tolerance.(42)

Strength training
Since muscle weakness contributes to exercise intolerance in individuals with chronic pulmonary disease, strength training is a rational option in the pulmonary rehabilitation process.(29) Currently, there is evidence that this training can result in a significantly greater improvement of the quality of life than that provided by aerobic exercise.(53) Although researchers and health professionals debate the importance of muscle strength in the functional capacity of patients with COPD, there is no consensus regarding the implementation of strength training in pulmonary rehabilitation programs.

Neuromuscular electric stimulation
Neuromuscular electric stimulation has been routinely used in the rehabilitation of patients with neuromuscular and orthopedic disease. There is mounting evidence that it can also be useful in patients presenting peripheral skeletal muscle dysfunction and exercise intolerance resulting from systemic diseases.(54)

Neuromuscular electric stimulation can be especially useful in patients presenting severe COPD and significant musculoskeletal dysfunction. The benefits of this type of therapy might be particularly evident in patients with intense dyspnea, who are incapable of performing even extremely light activities. In this type of patient, neuromuscular electric stimulation might alleviate the effects of the muscle dysfunction, making it possible for them to participate in pulmonary rehabilitation programs involving physical conditioning.(55)

Antioxidant therapy
Oxidative stress plays an important role in the physiopathology of COPD. In view of this, antioxidant therapy seems to be a rational strategy for patients affected by the disease. To date, the main antioxidant available for the treatment of patients with COPD is N-acetylcysteine.(56) This antioxidant can reduce the rate of annual decrease in forced expiratory volume in one second in patients with COPD. Some authors,(56) in a multicenter study, reported no influence of N-acetylcysteine on the forced expiratory volume in one second of 523 patients who were in follow-up treatment for three years. However, the functional residual capacity was significantly decreased in the group treated with N-acetylcysteine. Further investigation is needed, especially regarding the effects that antioxidant therapy has on COPD progression, on the frequency of exacerbations and on symptom relief.

OTHER EFFECTS

Influence of the use of corticosteroids
Together with muscle dysfunction, osteoporosis is also frequent in patients with COPD. The use of corticosteroids, inhaled or systemic, can cause bone loss in these patients, although there are also studies that show decreased bone density in those who did not receive corticosteroids.(57)

Patients under treatment with corticosteroids for more than a month can present a significant decrease in testosterone levels, resulting in sexual dysfunction.(17) The corticosteroid dosage is inversely proportional to the serum levels of testosterone, probably due to corticosteroid-induced suppression of the secretion of gonadotropin-releasing hormone by the pituitary gland.(17)

Patients with COPD who are under prolonged treatment with corticosteroids present less muscle strength than do those who are not. Studies with rats revealed that corticosteroids stimulate proteolysis, inhibit protein synthesis and hinder amino acid transport to muscle cells. Corticosteroids and acidosis activate the ubiquitin pathway, which is known to increase protein degradation, especially in those patients using corticosteroids due to exacerbations.(17)

Cardiovascular diseases
Patients presenting low forced expiratory volume in one second have a higher risk of death due to cardiovascular diseases. It has been shown that there is a association between baseline pulmonary function values and the incidence of coronary disease and cerebrovascular diseases.(58) The inflammatory process seen in patients with COPD might be the mechanism responsible for this association.(3)

Some authors,(59) in a study of 6629 patients, showed there is a correlation among airway obstruction, systemic inflammation, and the increase in heart diseases. The presence of an inflammatory process, evidenced by the increase in C-reactive protein levels, caused an up to two-fold increase in the risk of heart diseases in the group of patients with severe obstruction in comparison to the group in which there were no alterations in the spirometric tests.

Similarly, low doses (50-200 µg) of inhaled corticosteroids have been shown to reduce the risk of acute myocardial infarction in patients with COPD.(60) The present study raises the hypothesis that the anti-inflammatory effect of corticosteroids modifies the expression of genes related to the inhibition of the synthesis of cytokines such as IL-2, IL-6 and TNF-a, as well as influencing endothelial adhesion, enzyme levels and levels of other proteins involved in inflammation. However, further studies are needed in order to investigate the effects of anti-inflammatory treatment on the risk of acute myocardial infarction in patients with COPD.

CONCLUSION

According to what has been discussed above, COPD must be considered a systemic disease, and the extrapulmonary manifestations must be considered in the evaluation of its severity. In addition, the treatment of these manifestations could modify the prognosis of these patients. Further studies elucidating the systemic manifestations, especially those affecting nutritional status and peripheral skeletal muscle function, are needed for the development of new treatment strategies, which might improve the exercise tolerance and the overall health status of these patients.

REFERENCES

1. Sociedade Brasileira de Pneumologia e Tisiologia. II Consenso Brasileiro sobre Tuberculose: Diretrizes Brasileiras para Tuberculose 2004. J Bras Pneumol. 2004;30 Suppl 1:S1-S42.
2. Wouters EF. Local and systemic inflammation in chronic obstructive pulmonary disease. Proc Am Thorac Soc. 2005;2(1):26-33.
3. Gan WQ, Man SF, Senthilselvan A, Sin DD. Association between chronic obstructive pulmonary disease and systemic inflammation: a systematic review and a meta-analysis. Thorax. 2004;59(7):574-80. Comment in: Thorax. 2005;60(7):612-3; author reply 612-3.
4. MacNee W. Pulmonary and systemic oxidant/antioxidant imbalance in chronic obstructive pulmonary disease. Proc Am Thorac Soc. 2005;2(1):50-60.
5. Landbo C, Prescott E, Lange P, Vestbo J, Almdal TP. Prognostic value of nutritional status in chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 1999;160(6):1856-61.
6. Marquis K, Debigaré R, Lacasse Y, LéBlanc P, Jobin J, Carrier G, et al. Midthigh muscle cross-sectional area is a better predictor of mortality than body mass index in patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 2002;166(6):809-13. Comment in: Am J Respir Crit Care Med. 2002;166(6):787-9.
7. Celli BR, Cote CG, Marin JM, Casanova C, Montes de Oca M, Mendez RA, et al. The body-mass index, airflow obstruction, dyspnea, and exercise capacity index in chronic obstructive pulmonary disease. N Engl J Med. 2004;350(10):1005-12. Comment in: ACP J Club. 2004;141(2):53; N Engl J Med. 2004;350(10):965-6; N Engl J Med. 2004;350(22):2308-10; author reply 2308-10.
8. World Health Organization. Global Initiative for Chronic Obstructive Lung Disease. Global strategy for the diagnosis, management, and prevention of chronic obstructive pulmonary disease updated. Washington: National Institutes of Health and National Heart, Lung, and Blood Institute; 2004.
9. Schols AM. Nutrition in chronic obstructive pulmonary disease. Curr Opin Pulm Med. 2000;6(2):110-5.
10. Paiva SA, Godoy I, Vannucchi H, Favaro RM, Geraldo RR, Campana AO. Assessment of vitamin A status in chronic obstructive pulmonary disease patients and healthy smokers. Am J Clin Nutr. 1996;64(6):928-34.
11. Godoy I, Castro e Silva MH, Togashi RH, Geraldo RR, Campana AO. Is chronic hypoxemia in patients with chronic obstructive pulmonary disease associated with more marked nutritional deficiency? A study of fat-free-mass evaluated by anthropometry and bioelecritical impedance methods. J Nutr Health Aging. 2000;4(2):102-8.
12. Schols AM, Slangen J, Volovics L, Wouters EF. Weight loss is a reversible factor in the prognosis of chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 1998;157(6 Pt 1):1791-97.
13. Prescott E, Almdal T, Mikkelsen KL, Tofteng CL, Vestbo J, Lange P. Prognostic value of weight change in chronic obstructive pulmonary disease: results from the Copenhagen City Heart Study. Eur Respir J. 2002;20(3):539-44.
14. Wouters, EF. Nutrition and metabolism in COPD. Chest. 2000;117(5 Suppl 1):274S-80S.
15. Ferreira I, Brooks D, Lacasse Y, Goldstein R. Nutrition intervention in COPD; a systematic overview. Chest. 2001;119(2):353-63.
16. Godoy I, Donahoe M, Calhoun WJ, Mancino J, Rogers RM. Elevated TNF-alpha production by peripheral blood monocytes of weight-losing COPD patients. Am J Respir Crit Care Med. 1996;153(2):633-7.
17. Creutzberg E. Leptin in relation to systemic inflammation and regulation of the energy balance. Eur Respir Mon 2003;24:56-67
18. Takabatake N, Nakamura H, Abe S, Inoue S, Hino T, Saito H, et al. The relationship between chronic hypoxemia and activation of the tumor necrosis factor-alpha system in patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 2000;161(4 Pt 1):1179-84.
19. Neder JA, Nery LE, Cendon Filha SP, Ferreira IM, Jardim JR. Reabilitação pulmonar: fatores relacionados ao ganho aeróbio de pacientes com DPOC. J Pneumol. 1997;23(3):115-23.
20. Mostert R, Goris A, Weling-Scheepers C, Wouters EF, Schols AM. Tissue depletion and health related quality of life in patients with chronic obstructive pulmonary disease. Respir Med. 2000;94(9):859-67.
21. Kessler R, Faller M, Fourgaut G, Mennecier B, Weintzenblum E. Predictive factors of hospitalization for acute exacerbation in a series of 64 patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 1999;159(1):158-64.
22. Connors AF Jr, Dawson NV, Thomas C, Harrel FE Jr, Desbiens N, Fulkerson WJ, et al. Outcomes following acute exacerbation of severe chronic obstructive lung disease. The SUPPORT investigators (Study of Understand Prognoses and Preferences for Outcomes and Risks of Treatments). Am J Respir Crit Care Med. 1996;154(4 Pt 1):959-67. Erratum in: Am J Respir Crit Care Med. 1997;155(1):386.
23. Mazolewski P, Turner JF, Baker M, Kurtz T, Little AG. The impact of nutritional status on the outcome of lung reduction surgery: a prospective study. Chest. 1999;116(3):693-6.
24. Chailleux E, Laaban JP, Veale D. Prognostic value of nutritional depletion in patients with COPD treated by long-term oxygen therapy: data from the ANTADIR observatory. Chest. 2003;123(5):1460-6.
25. Ferreira IM, Brooks D, Lacasse Y, Goldstein RS, White J. Nutritional supplementation for stable chronic obstructive pulmonary disease (Cochrane Review). In: The Cochrane Library, n.2, 2005. Oxford: Update Software.
26. Schols AM. Nutritional and metabolic modulation in chronic obstructive pulmonary disease management. Eur Respir J Suppl. 2003;46:81s-6s.
27. Storer TW. Exercise in chronic pulmonary disease: resistence exercise prescription. Med Sci Sports Exerc. 2001;33(7 Suppl):S680-6.
28. McArdle WD, Katch FI, Katch VL. Força muscular: treinando os músculos para se tornarem mais fortes In: McArdle WD, Katch FI, Katch VL, editors. Fisiologia do exercício: energia, nutrição e desempenho humano. 5a ed. Rio de Janeiro: Guanabara Koogan; 2001. p.513-61.
29. Skeletal muscle dysfunction in chronic obstructive pulmonary disease. A Statement of the American Thoracic Society and European. Am J Respir Crit Care Med. 1999; 159(4):S2-S40.
30. Cassart M, Pettiaux N, Gevenois PA, Paiva M, Estenne M. Effect of chronic hyperinflation on diaphragm length and surface area. Am J Respir Crit Care Med. 1997;156(2 Pt 1):504-8.
31. Orozco-Levi M. Structure and function of the respiratory muscles in patients with COPD: impairment or adaptation? Eur Respir J. 2003;46:41s-51s.
32. Levine S, Nguyen T, Kaiser LR, Shrager JB. Evaluating respiratory muscle adaptations: a new approach. Am J Respir Crit Care Med. 2002;166(11):1418-9. Comment in: Am J Respir Crit Care Med. 2002;166(11):1491-7.
33. Decramer M, Gosselink R, Troosters T, Verschueren M, Evers G. Muscle weakness is related to utilization of health care resources in COPD patients. Eur Respir J. 1997;10(2):417-23.
34. Debigare R, Marquis K, Côté CH, Tremblay RR, Michaud A, LeBlanc P, et al. Catabolic/anabolic balance and muscle wasting in patients with COPD. Chest. 2003;124(1):83-9. Comment in: Chest. 2003;124(1):1-4.
35. Bernard S, LeBlanc P, Whitton F, Carrier G, Jobin J, Belleau R, et al. Peripheral muscle weakness in patients with chronic obstructive pulmonary disease. Am. J Respir Crit Care Med. 1998;158(2):629-34.
36. Gosselink R, Troosters T, Decramer M. Distribution of muscle weakness in patients with stable chronic obstructive pulmonary disease. J Cardiopulm Rehabil. 2000;20(6):353-60.
37. Jagoe RT, Engelen MPKJ. Muscle wasting and changes in muscle protein metabolism in chronic obstructive pulmonary disease. Eur Respir J Suppl. 2003;46: 52s-63s.
38. Whittom F, Jobin J, Simard PM, Leblanc P, Simard C, Bernard S, et al. Histochemical and morphological characteristics of the vastus lateralis muscle in patients with chronic obstructive pulmonary disease. Med Sci Sports Exerc. 1998; 30(10):1467-74.
39. Maltais F, Simard AA, Simard C, Jobin J, Desgagnes P, LeBlanc P. 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. 1996;153(1):288-93.
40. Maltais F, LeBlanc P, Whittom F, Simard C, Marquis K, Bélanger M, et al. Oxidative enzyme activities of the vastus lateralis muscle and the functional status in patients with COPD. Thorax. 2000;55(10):848-53.
41. Allaire J, Maltais F, Doyon JF, Noel M, LeBlanc P, Carrier G, et al. Peripheral muscle endurance and the oxidative profile of the quadriceps in patients with COPD. Thorax. 2004;59(8):673-8.
42. Powers SK, Howley ET. Bioenergética. In: Powers SK, Howley ET, editores. Fisiologia do exercício: teoria e aplicação ao condicionamento e ao desempenho 3a ed. São Paulo: Manole; 2000. p.21-44.
43. Steiner MC, Morgan MD. Enhancing physical performance in chronic obstructive pulmonary disease. Thorax. 2001;56(1):73-7.
44. Pouw EM, Koerts-de Lang E, Gosker HR, Freling G, van der Vusse GJ, Wouters EF, et al. Muscle metabolic status in patients with severe COPD with and without long-term prednisolone. Eur Respir J. 2000;16(2):247-52.
45. Gea JG, Pasto M, Carmona MA, Orozco-Levi M, Palomeque J, Broquetas J. Metabolic characteristics of the deltoid muscle in patients with chronic obstructive pulmonary disease. Eur Respir J. 2001;17(5):939-45.
46. Schols AM, Soeters PB, Dingemans AM, Mostert R, Frantzen PJ, Wouters EF. Prevalence and characteristics of nutritional depletion in patients with stable CPOD eligible for pulmonary rehabilitation. Am Rev Respir Dis. 1993;147(5):1151-6.
47. Yoneda T, Yoshikawa M, Fu A, Tsukaguchi K, Okamoto Y, Takenaka H. Plasma levels of amino acids and hypermetabolism in patients with chronic obstructive pulmonary disease. Nutrition. 2001;17(2):95-9.
48. Frost RA, Lang CH, Gelato MC. Transient exposure of human myoblasts to tumor necrosis factor-alpha inhibits serum and insulin-like growth factor-I stimulated protein synthesis. Endocrinology 1997;138(10):4153-9.
49. de Martino M, Galli L, Chiarelli F, Verrotti A, Rossi ME, Bindi G, et al. Interleukin-6 release by cultured peripheral blood mononuclear cells inversely correlates with height velocity, bone age, insulin-like growth factor-I, and insulin-like growth factor binding protein-3 serum levels in children with perinatal HIV-1 infection. Clin Immunol. 2000;94(3):212-8.
50. Harris TB, Ferrucci L, Tracy RP, Corti MC, Wacholder S, Ettinger WH Jr, et al. Associations of elevated interleukin-6 and C-reactive protein levels with mortality in the elderly. Am J Med. 1999;106(5):506-12.
51. Couillard A, Maltais F, Saey D, Debigare R, Michaud A, Koechlin C, et al. Exercise-induced quadriceps oxidative stress and peripheral muscle dysfunction in patients with chronic obstructive pulmonary disease. Am Respir Crit Care Med. 2003;167(12):1664-9.
52. Rabinovich RA, Ardite E, Troosters T, Carbo N, Alonso J, Gonzalez de Suso JM, et al. Reduced muscle redox capacity after endurance training in patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 2001;164(7):1114-8. Comment in: Am J Respir Crit Care Med. 2001;164(7):1101-2; Am J Respir Crit Care Med. 2002;165(9):1336-7; author reply 1337-8.
53. Puhan MA, Schunemann HJ, Frey M, Scharplatz M, Bachmann LM. How should COPD patients exercise during respiratory rehabilitation? Comparison of exercise modalities and to treat skeletal muscle dysfunction. Thorax. 2005;60(5):367-75.
54. Ambrosino N, Strambi S. New strategies to improve exercise tolerance in chronic obstructive pulmonary disease. Eur Respir J. 2004;24(2):313-22.
55. Neder JA. Estratégias emergentes para o recondicionamento muscular esquelético na DPOC. In: Terra Filho M, Fernandes ALG, Stirbulov R, editores. Pneumologia: atualização e reciclagem. São Paulo: Vivali; 2001. v.4, p.1-13.
56. Decramer M, Dekhuijzen PN, Troosters T, Van Herwaarden C, Rutten-Van Molken M, Van Schayck CP, et al. The Bronchitis Randomized On NAC Cost-Utility Study (BRONCUS): hypothesis and design. BRONCUS-trial Committee. Eur Respir J. 2001;17(3):329-36.
57. Berry JK, Baum C. Reversal of chronic obstructive pulmonary disease-associated weight loss: are there pharmacological treatment options? Drugs. 2004;64(10: 1041-52.
58. Sunyer J, Ulrik CS. Level of FEV1 as a predictor of all-cause and cardiovascular mortality: an effort beyond smoking and physical fitness? Eur Respir J. 2005;25(4): 587-8. Comment on: Eur Respir J. 2005;25(4):618-25.
59. Sin DD, Man SF. Why are patients with chronic obstructive pulmonary disease at increased risk of cardiovascular diseases? The potential role of systemic inflammation in chronic obstructive pulmonary disease. Circulation. 2003;107(11): 1514-9.
60. Huiart L, Ernst P, Ranouil X, Suissa S. Low-dose inhaled corticosteroids and the risk of acute myocardial infarction in COPD. Eur Respir J. 2005;25(4):634-9. Comment in: Eur Respir J. 2005;25(4):589-90.
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*Study carried out in the Department of Pulmonology of the Universidade Estadual Paulista (UNESP, Paulista State University) at Botucatu School of Medicine, Botucatu, São Paulo, Brazil
1. Physiotherapist and Adjunct Professor at the Universidade Federal dos Vales do Jequinhonha e Mucuri (UFVJM, Federal University of the Jequitinhonha and Mucuri Valleys), Diamantina, Minas Gerais, Brazil
2. Pulmonologist in the Department of Pulmonology of the Universidade Estadual Paulista (UNESP, Paulista State University) at Botucatu School of Medicine, Botucatu, São Paulo, Brazil
3. Physical Therapist and Doctoral student in the Postgraduate Program of Clinical Physiopathology of the Department of Clinical Medicine of the Universidade Estadual Paulista (UNESP, Paulista State University) at Botucatu School of Medicine, Botucatu, São Paulo, Brazil
4. Adjunct Tenured Professor in the Pulmonology Department of the Universidade Estadual Paulista (UNESP, Paulista State University) at Botucatu School of Medicine, Botucatu, São Paulo, Brazil
Correspondence to: Victor Zuniga Dourado. Peixe Vivo, 119 apto 203, Bela Vista - CEP: 39100-000, Diamantina, MG. Brasil. E-mail: vzuniga@universiabrasil.net
Submitted: 20 June 2005. Accepted, after review: 7 July 2005.

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