Tuesday, June 24, 2014

Want to Age in Good Health? Build Muscle


Presented below is an old study from 2008, but it's a study that makes a powerful correlation between muscular strength and reduced mortality rates in men. We have seen similar research suggesting that the best way to maintain a strong immune system (in a study of HIV+ men) was to maintain as much muscle mass as possible, which is why anabolic steroids are often part of the treatment protocol for HIV/AIDS.

What more reason can we need to get into the gym and stay in shape? If we are going to age, and modern medicine is determined to see that we will, why not do it in as much health as we can?

Do you want to be 80 and need a walker, or do you want to look like this guy, incredibly fit despite his age? We do not have to age badly and lose vitality - staying fit is the best way to enjoy life for as long as our hearts are beating.

Association between muscular strength and mortality in men: prospective cohort study

Jonatan R Ruiz, Xuemei Sui, Felipe Lobelo, James R Morrow Jr, Allen W Jackson, Michael Sjöström, Steven N Blair

Abstract


Objective To examine prospectively the association between muscular strength and mortality from all causes, cardiovascular disease, and cancer in men.

Design Prospective cohort study.

Setting Aerobics centre longitudinal study.

Participants 8762 men aged 20-80.

Main outcome measures All cause mortality up to 31 December 2003; muscular strength, quantified by combining one repetition maximal measures for leg and bench presses and further categorised as age specific thirds of the combined strength variable; and cardiorespiratory fitness assessed by a maximal exercise test on a treadmill.

Results During an average follow-up of 18.9 years, 503 deaths occurred (145 cardiovascular disease, 199 cancer). Age adjusted death rates per 10 000 person years across incremental thirds of muscular strength were 38.9, 25.9, and 26.6 for all causes; 12.1, 7.6, and 6.6 for cardiovascular disease; and 6.1, 4.9, and 4.2 for cancer (all P<0 .01="" 0.58="" 0.68="" 0.71="" 0.72="" 0.74="" 0.77="" 0.90="" 0.96="" 0.97="" 1.00="" 1.07="" 1.0="" 1.10="" across="" activity="" adjusting="" adjustment="" after="" age="" alcohol="" all="" and="" association="" attenuated="" baseline="" between="" body="" br="" cancer="" cardiorespiratory="" cardiovascular="" cause="" causes="" conditions="" confidence="" death="" disease="" family="" fitness.="" fitness="" for="" from="" further="" hazard="" history="" however="" incremental="" index="" intake="" interval="" linear="" mass="" medical="" mortality="" muscular="" of="" pattern="" persisted="" physical="" ratios="" referent="" smoking="" strength="" the="" thirds="" to="" trend="" was="" were="">
Conclusion Muscular strength is inversely and independently associated with death from all causes and cancer in men, even after adjusting for cardiorespiratory fitness and other potential confounders.
Full Citation:
Ruiz, JR, Sui, X, Lobelo, F, Morrow Jr, JR, Jackson, AW, Sjöström, M, and Blair, SN. (2008, July 1).
Association between muscular strength and mortality in men: prospective cohort study. BMJ; 337:a439. doi: 10.1136/bmj.a439

Rather than bore you with the whole study, here are the final sections, including the Discussion and Strengths and Limitations. The results are pretty clear - more muscular strength equals better health and lower mortality rates.

Discussion


Muscular strength was significantly and inversely associated with risk of death from all causes and cancer after controlling for potential confounders, including cardiorespiratory fitness. The inverse association was consistent in strata of age (<60 60="" adjusted="" adjustment="" after="" age="" all="" analysis="" and="" associated="" association="" at="" attenuated="" body="" both="" br="" cancer="" cardiorespiratory="" cardiovascular="" cause="" causes="" combined="" confounders="" controlling="" death="" disease="" effects="" entered="" fitness.="" fitness="" for="" from="" further="" group="" having="" high="" highlight="" importance="" in="" index="" inversely="" kg="" least="" levels="" lower="" lowest="" m2="" mass="" men.="" men="" model="" moderate="" mortality="" muscular="" not="" of="" on="" once="" other="" population="" potential="" rate="" reduce="" results="" risk="" showed="" significant="" significantly="" strength.="" strength="" than="" that="" the="" these="" this="" to="" unfit="" was="" were="" with="" years="" yet="">
We investigated the association between standardised measures of upper and lower body muscular strength and disease specific risk of mortality in a large cohort of men with extensive follow-up. Muscular strength and cardiorespiratory fitness were moderately correlated (age adjusted partial r=0.33), suggesting that the association between muscular strength and risk of death from cancer works at least partially through different mechanisms than those associated with the protective effects of cardiorespiratory fitness. That the association between muscular strength and risk of death from cardiovascular disease was not significantly independent of cardiorespiratory fitness highlights the key role of cardiorespiratory fitness in the development of cardiovascular disease in men; however, their combined effects cannot be easily disentangled in an observational study. In this cohort the number of deaths from cardiovascular disease was lower than that from cancer (145 and 199, respectively). This may have reduced the statistical power to detect a significant independent association between muscular strength and risk of death from cardiovascular disease.

Apart from our preliminary analyses in the aerobics centre longitudinal study,28 only one study has assessed the association between muscular strength and all cause mortality after adjusting for cardiorespiratory fitness and age, smoking status, and body mass index and found that handgrip strength and upper body strength (push-ups) were not significantly associated with risk of death from all causes.18 A significant inverse association between muscular strength (measured by handgrip strength) and risk of mortality has been reported in several other studies.15 16 17 19 20 21 22 23 24 25 27 The main limitation of this test is that the measurement is highly influenced by the grip span of the dynamometer and hand size.44 45 46 None of these previous studies standardised the grip span or assessed a second muscle group. Furthermore, hand grip uses a relatively small muscle group and is not well correlated with measures of overall muscular strength as determined by measurements of strength using large muscle groups.47 Assessing additional muscle groups may provide a better overall index of muscular strength, especially when measured in large muscle groups. Moreover, cardiorespiratory fitness was not measured in these studies, and we know that cardiorespiratory fitness is strongly associated with morbidity and mortality.7 8 9 10 11 12 13 37 38 39

The apparent protective effect of muscular strength against risk of death might be due to muscular strength in itself, to muscle fibre type or configuration, or as a consequence of regular physical exercise, specifically resistance exercise. Muscle fibre type and configuration has a genetic component and influences strength, yet it is clear that resistance type physical activities are major determinants of muscular strength.5 48 We have previously reported a strong and positive association between the frequency of self reported resistance exercise and maximal muscular strength in men enrolled in the aerobics centre longitudinal study—that is, the higher the participation in resistance exercise the higher the muscular strength.32 This observation suggests that the measurements of muscular strength obtained in the present study provide an adequate representation of the resistance exercise habits in our cohort. Results from intervention studies indicate that resistance training enhances muscular strength and endurance, muscle mass, functional capacity, daily physical activity, risk profile for cardiovascular disease, and quality of life.5 These factors are well known predictors of higher risk of mortality. The benefits of resistance training are evident in men and women, young adults, and older people, in overweight and obese adults as well as in people of normal weight, and in people with or without disability, or with cardiovascular disease.5 We observed an inverse association between muscular strength and risk of death from all causes and cancer in older men (≥60 years) and younger men (<60 age="" also="" and="" as="" associated="" becomes="" benefit="" br="" consequently="" declines="" dependent="" directly="" experience="" from="" functional="" having="" higher="" in="" levels="" mass="" may="" men="" more="" muscle="" muscular="" of="" older="" on="" performance="" strength.="" strength="" suggests="" that="" these="" this="" years="">
The observed association between muscular strength and risk of death from all causes or cancer was also independent of body weight. We showed an inverse association between muscular strength and risk of death from all causes and cancer in overweight and obese men, as well as between muscular strength and risk of all cause mortality in those of normal body weight. Body mass index may have a different meaning in those who have greater muscular strength. For example, leg press strength for a man weighing 60 kg would be expected to be lower than that for a man weighing 90 kg. That is why we included body mass index in the multivariate analyses. Thus we not only controlled for the effect of weight but also height, which might have influenced the torque or force production. A high body mass index can result from a greater amount of fat or muscle. Yet in epidemiological studies most of the people with a higher body mass index also had higher fat levels.

Given that the prevalence of overweight and obesity exceeds 66% in the United States49 and that overweight and obese people are at a substantially higher risk of disability50 and death,51 52 these results have important implications for public health. Exercise recommendations to prevent or treat obesity have focused mainly on aerobic activities, yet resistance exercise is an important complement for weight control, mainly as a result of the increases in metabolically active muscle mass.2 Under most circumstances, and especially during physical inactivity, resting energy expenditure is the largest component of total energy expenditure. The energy expenditure related to muscle metabolism is the only component of resting energy expenditure that might vary considerably.2 The resting metabolic requirements of splanchnic tissues, brain, and skin vary little under normal conditions, mainly because of their relatively constant mass and protein turnover rates. In contrast, large variations in muscle mass are possible, and the rate of muscle protein turnover (synthesis and breakdown) may vary as well. The synthesis and breakdown of muscle protein are principally responsible for the energy expenditure of resting muscle. In theory, every 10 kg difference in lean mass translates to a difference in energy expenditure of about 100 kcal daily, assuming a constant rate of protein turnover.2 A difference in energy expenditure of about 100 kcal daily translates to about 4.7 kg of fat mass yearly. Over a long period the maintenance of a large muscle mass and consequent muscle protein turnover can contribute to the prevention of obesity. Therefore it is reasonable to presume that when sustained over time, resistance exercise training should help to prevent or revert increases in body fat.5

Strengths and limitations


The results of the present study should be interpreted with caution. Generalisation of the findings may only apply to well educated white men of middle to upper socioeconomic status. Values for blood pressure and cholesterol levels, body weight, and cardiorespiratory fitness from participants in the aerobics centre longitudinal study were similar to those reported in two population based studies in North America.8 Moreover, there is no reason to believe that the benefits of muscular strength would be different in other ethnic or socioeconomic groups. Because of the limited sample of women, who contributed relatively few deaths to the main study, we were unable to perform a meaningful parallel analysis on women. Therefore women were not included in this substudy. No detailed information about drug use or diet was available, which may have biased the results through residual confounding. It seems unlikely, however, that these factors would account for all of the observed association between muscular strength and mortality. That none of the participants reported a family history of cancer might be a limitation of the main study owing to self selection bias. In fact, only 1.16% of men in the entire cohort of the aerobics centre longitudinal study reported a family history of cancer. Future studies should include such information whenever possible.

A major strength of this study was the inclusion of objective and standardised maximal tests for muscular strength (upper and lower body) and cardiorespiratory fitness using highly reliable measurement protocols in a large cohort of men with extensive follow-up. Undetected subclinical disease is always a concern in any observational study, but it is less likely to have occurred in our cohort because of the comprehensive physical examination and the clinical assessment completed by each participant. Moreover, participants were healthy enough to achieve at least 85% of aged predicted maximal heart rate during the treadmill test.

Conclusions


Muscular strength was independently associated with risk of death from all causes and cancer in men. These findings are valid for men of normal weight, those who are overweight, and younger or older men, and are valid even after adjusting for several potential confounders, including cardiorespiratory fitness. Muscular strength seems to add to the protective effect of cardiorespiratory fitness against the risk of death in men. Whether the association between muscular strength and risk of death from cardiovascular disease is independent of typical confounders as well as of cardiorespiratory fitness warrants further investigation.

Prospective studies among diverse populations and among women are needed to examine the independent and combined associations of muscular strength and cardiorespiratory fitness with disease specific mortality. It might be possible to reduce all cause mortality among men by promoting regular resistance training involving the major muscle groups of the upper and lower body two or three days a week.5 Resistance training should be a complement to rather than a replacement for aerobic exercise. The recommendation for moderate to vigorous physical activity and resistance training are supported by the current research owing to the reduction in risk of death from all causes and cancer associated with increased cardiorespiratory fitness or muscular strength.3 4 5 6

What is already known on this topic
  • Cardiorespiratory fitness provides strong and independent prognostic information about the overall risk of illness and death
  • Most prospective studies examining the association between muscular strength and death have had limitations
What this study adds
  • Muscular strength in major muscle groups is independently associated with death from all causes and cancer in men aged 20-82
  • These findings are valid for those who are of normal weight or overweight, younger or older, and even after adjusting for several potential confounders, including cardiorespiratory fitness
  • Muscular strength seems to add to the protective effect of cardiorespiratory fitness against the risk of death in men

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