Influence of counter-resistance training variables on elderly muscular strength: a systematic review with emphasis on dose/response relationships

Silva, Nádia Lima da; Farinatti, Paulo de Tarso Veras

doi:10.1590/S1517-86922007000100014

Abstracts

Muscular force is considered an important component of physical exercise programs. The results of this type of training depend on the combination of the number of repetitions, series, overload, sequence and intervals between series and exercises. However, it is still not very clear yet what the best combination of these variables for a good stimulus/response relationship in elderly people is. The objective of this study was to analyze the research on power-training for elderly people by means of systematic revision, with the intention to identify common trends in terms of effect of the training provoked by the manipulation of these variables. After definition of inclusion criteria, 22 cases were selected and grouped by treatment similarity (number of series; weekly frequency; intensity; intervals and order of the exercises). Techniques of descriptive statistics were used in order to determine possible trends in the stimulus/response relationship. Once identified, these trends were qualitatively analyzed. Among the variables revised, only for intensity of overload evidence that allows affirming that heavier loads would be more effective to induce force increase in this age group was found. Concerning the remaining variables, the results available in the literature do not support accurate inferences in terms of the best type of training program that connects effectiveness and safety. Therefore further studies should be conducted in order to experimentally compare the effects of the manipulation of these variables on muscular force in elderly people.

Aging; Power-training; Prescribed exercises

A força muscular é considerada componente importante de programas de exercícios físicos. Os benefícios desse tipo de treinamento dependem da combinação do número de repetições, séries, sobrecarga, seqüência e intervalos entre as séries e exercícios. No entanto, não se tem ainda muito clara qual a melhor combinação dessas variáveis para uma ótima relação dose-resposta em pessoas idosas. O objetivo do estudo foi analisar as pesquisas sobre treinamento de força para idosos, por meio de revisão sistemática, com o propósito de identificar tendências comuns em termos de efeitos do treinamento provocados pela manipulação dessas variáveis. Após definição de critérios de inclusão, foram selecionados 22 estudos, agrupados por similaridade de tratamento (número de séries, freqüência semanal, intensidade, intervalos e ordem dos exercícios). Técnicas de estatística descritiva auxiliaram na determinação de possíveis tendências nas relações dose-resposta. Uma vez identificadas, essas tendências foram analisadas qualitativamente. De todas as variáveis revisadas, somente para a intensidade da sobrecarga foram encontradas evidências permitindo afirmar que cargas maiores seriam mais eficazes para induzir aumento de força nessa faixa etária. Quanto às demais variáveis, os resultados disponíveis na literatura não dão respaldo para inferências seguras quanto ao melhor delineamento de programas de treinamento que aliem, ao mesmo tempo, efetividade e segurança. Recomenda-se, então, que estudos sejam realizados para comparar experimentalmente os efeitos da manipulação dessas variáveis sobre a força muscular de idosos.

Envelhecimento; Treinamento de força; Prescrição de exercícios

La fuerza muscular es considerada componente importante de programas de ejercicios físicos. Los beneficios de ese tipo de entrenamiento dependen de la combinación del número de repeticiones, series, sobrecarga, secuencia e intervalos entre las series y ejercicios. A pesar de esto, no se tiene aún muy claro cuál es la mejor combinación de esas variables para una óptima relación dosis-respuesta en personas ancianas. El objetivo de este estudio ha sido analizar las investigaciones sobre entrenamiento de fuerza para ancianos, mediante una revisión sistemática, con el propósito de identificar tendencias comunes en términos de efectos del entrenamiento provocados por la manipulación de estas variables. Una vez definidos los criterios de inclusión, fueron seleccionados 22 estudios, agrupados por semejanza de tratamiento (nº de series, frecuencia semanal, intensidad, intervalos y orden de los ejercicios). Técnicas de estadística descriptiva auxiliaron en la determinación de posibles tendencias en las relaciones dosis-respuesta. Al identificarse, esas tendencias fueron analizadas cualitativamente. De todas las variables revisadas, solamente para la intensidad de sobrecarga fueron encontradas evidencias, lo que permite afirmar que cargas mayores serían más eficaces para inducir un aumento de fuerza a esa edad. En relación a las demás variables, los resultados disponibles en la literatura no dan respaldo para realizar inferencias seguras respecto al mejor delineamiento de programas de entrenamiento que alíen, al mismo tiempo, efectividad y seguridad. Por tanto, se recomienda que estudios posteriores sean realizados para comparar experimentalmente los efectos de la manipulación de esas variables sobre la fuerza muscular de ancianos.

Envejecimiento; Entrenamiento de fuerza; Prescripción de ejercicios

REVIEW ARTICLE

Influence of counter-resistance training variables on elderly muscular strength: a systematic review with emphasis on dose/response relationships

Influencia de las variables de entrenamiento contra-resistencia sobre la fuerza muscular de ancianos: una revisión sistemática con énfasis en las relaciones dosis-respuesta

Nádia Lima da Silva^I; Paulo de Tarso Veras Farinatti^II

^IUniversidade Gama Filho (UGF). Programa de Pós-Graduação em Educação Física da UGF. Laboratório de Atividade Física e Promoção da Saúde da UERJ (LABSAU), Rio de Janeiro, RJ

^IIUniversidade do Estado do Rio de Janeiro (UERJ). Laboratório de Atividade Física e Promoção da Saúde da UERJ (LABSAU). Programa de Pós-Graduação em Ciências da Atividade Física da Universo

^{Correspondence to} Correspondence to: Nádia Lima da Silva Laboratório de Atividade Física e Promoção da Saúde Universidade do Estado do Rio de Janeiro Rua São Francisco Xavier, 524, sala 8133-F, Maracanã 20550-013 Rio de Janeiro, RJ E-mail: nadialima@globo.com ou farinatt@uerj.br

ABSTRACT

Muscular force is considered an important component of physical exercise programs. The results of this type of training depend on the combination of the number of repetitions, series, overload, sequence and intervals between series and exercises. However, it is still not very clear yet what the best combination of these variables for a good stimulus/response relationship in elderly people is. The objective of this study was to analyze the research on power-training for elderly people by means of systematic revision, with the intention to identify common trends in terms of effect of the training provoked by the manipulation of these variables. After definition of inclusion criteria, 22 cases were selected and grouped by treatment similarity (number of series; weekly frequency; intensity; intervals and order of the exercises). Techniques of descriptive statistics were used in order to determine possible trends in the stimulus/response relationship. Once identified, these trends were qualitatively analyzed. Among the variables revised, only for intensity of overload evidence that allows affirming that heavier loads would be more effective to induce force increase in this age group was found. Concerning the remaining variables, the results available in the literature do not support accurate inferences in terms of the best type of training program that connects effectiveness and safety. Therefore further studies should be conducted in order to experimentally compare the effects of the manipulation of these variables on muscular force in elderly people.

Keywords: Aging. Power-training. Prescribed exercises.

RESUMEN

La fuerza muscular es considerada componente importante de programas de ejercicios físicos. Los beneficios de ese tipo de entrenamiento dependen de la combinación del número de repeticiones, series, sobrecarga, secuencia e intervalos entre las series y ejercicios. A pesar de esto, no se tiene aún muy claro cuál es la mejor combinación de esas variables para una óptima relación dosis-respuesta en personas ancianas. El objetivo de este estudio ha sido analizar las investigaciones sobre entrenamiento de fuerza para ancianos, mediante una revisión sistemática, con el propósito de identificar tendencias comunes en términos de efectos del entrenamiento provocados por la manipulación de estas variables. Una vez definidos los criterios de inclusión, fueron seleccionados 22 estudios, agrupados por semejanza de tratamiento (nº de series, frecuencia semanal, intensidad, intervalos y orden de los ejercicios). Técnicas de estadística descriptiva auxiliaron en la determinación de posibles tendencias en las relaciones dosis-respuesta. Al identificarse, esas tendencias fueron analizadas cualitativamente. De todas las variables revisadas, solamente para la intensidad de sobrecarga fueron encontradas evidencias, lo que permite afirmar que cargas mayores serían más eficaces para inducir un aumento de fuerza a esa edad. En relación a las demás variables, los resultados disponibles en la literatura no dan respaldo para realizar inferencias seguras respecto al mejor delineamiento de programas de entrenamiento que alíen, al mismo tiempo, efectividad y seguridad. Por tanto, se recomienda que estudios posteriores sean realizados para comparar experimentalmente los efectos de la manipulación de esas variables sobre la fuerza muscular de ancianos.

Palabras-clave: Envejecimiento. Entrenamiento de fuerza. Prescripción de ejercicios.

INTRODUCTION

Muscular strength may be defined as the maximal strength a muscle or muscular group can generate in a specific pattern of movement performed in a given velocity⁽¹⁾. In the last decades, it began to be considered a crucial component of physical aptitude aimed at the maintenance of quality of life of individuals, being part of the majority of physical training programs dedicated to health^(2-4).

The importance of the development of a strength training program for maintenance of work capacity has been increasing since as one ages, there is a tendency of progressive decline. For Macaluso and De Vito⁽⁵⁾, the studies about the topic bring evidence that the muscle reaches its maximal strength between the second and third decades of one's life and shows a slow or unperceiving decrease until about 50 years of age, when it begins to decline approximately 12% to 15% per decade, with faster losses above 65 years of age.

The decrease of muscular strength brings consequences to the functional autonomy of older subjects^(6-7). Latham et al.⁽⁸⁾, for instance, demonstrated that reduced levels of strength would be associated with lower gait velocity and inaptitude, which would cause increase in the risk of falls and fractures in older individuals. Generally, progressive losses of strength tend to make the elderly incapable of performing simple daily tasks, making them many times dependable on other people, which tends to greatly reduce the quality of life of these individuals^(9-10).

Conversely, muscular strength can be improved in elders, as long as they are submitted to a training program with overloads. Studies as the one by Hunter et al.⁽²⁾, Frontera et al.^(11-12), Fiatarone et al.⁽¹³⁾, Valkeinen et al.⁽¹⁴⁾ and Latham et al.⁽¹⁵⁾ reinforce this possibility, demonstrating that this kind of training improves muscle, articular and bone function and structure in any age. The accumulation of positive results in this direction explains the considerable increase of strength training programs aimed to older subjects indeed.

However, the benefits promoted by counter-resistance training depend on the manipulation of several factors; among them, intensity, frequency and training volume are highlighted. Such factors derive from the combination of number of repetitions, series, overload, sequence and intervals between series and exercises, as well as the velocity of the movements' performance imposed to training^(16,18,22). Nevertheless, it is not clear yet what the best combination of these variables for an optimum dose-response relationship is. Studies as the ones revised by Gomes and Pereira⁽¹⁷⁾, for instance, show that different combinations may be equally efficient for reaching these goals. Even facing this uncertainty, a guideline usually followed by specialists in strength training for healthy young adults is the one suggested by the American College of Sports Medicine, which recommends 8 to 10 exercises with 3 series of 8 to 12 maximal repetitions (RM), in a 2 to 3 days weekly frequency as a starting point⁽¹⁸⁾. In its text, though, nothing is specifically recommended to older populations.

Pearson et al.⁽¹⁹⁾ when publishing the basic guidelines of the National Strength and Conditioning Association (NSCA) for strength training for athletes, mention in the section dedicated to older athletes that no special recommendation could be given since there would not be studies supporting such situation. They even affirm that for older athletes the same recommendations given to young individuals could be applied. Since the recommendations by the NSCA refer closer to athletes, the guidelines by the ACSM have been more widely spread.

Within this context, if there are concerns about the methodological variables associated with strength training prescription for healthy young adults yet, the problem is even bigger when older subjects are considered. It is worth remembering that some time ago resisted exercises with important overloads were considered inadequate to this age group^(20-21).

Conversely, due to the lack of data specifically with elders, recommendations of normative agencies (such as the ACSM) have been worldwide used for the prescription of strength training. In other words, it seems that there are no great concerns about training variables adaptation to the characteristics related to a senescent body. Such thinking raises the following issue: in terms of dose-response, which would be the most efficient training methodology for the development of muscle strength in older individuals?

One may think then, that further systematic review studies, seeking for the identification of common references concerning the methodological variables of the strength training for this population would be needed. Some studies were conducted with this purpose. However, the analyzed population was of apparently healthy young adults, as in the case of the study by Rhea et al.⁽²²⁾. These authors performed a meta-analysis for the determination of the dose-response relationship concerning intensity, frequency and number of series of the counter-resistance training, concerning muscle strength gain. Another study was developed by Wolf et al.⁽¹⁶⁾, with the aim to investigate the same relationship when comparing programs involving single and multiple series.

Concerning the elderly population, only one study that analyzed as a whole the results of the experimental studies available was found; namely, the meta-analysis performed by Latham et al.⁽⁸⁾. Nonetheless, the focus of the authors was more epidemiological, considering the training effects on aspects such as falls prevention and reduction of physical inaptitude. The study did not consider the methodological aspects of the proposed trainings and strength gain produced by them.

Therefore, in order to obtain more data concerning the isolated as well as combined role of the training variables for the strength gain in this age group, more investment in systematic reviews with emphasis on the dose-response relationships is justified. Thus, the aim of the present study is to analyze the research on strength training for older individuals through systematic review. The aim was to identify possible common trends concerning training effects caused by the manipulation of the following variables: workload; number of series; weekly frequency; recovery interval and order of the exercises.

METHODOLOGY

The study consisted of a systematic review. The following inclusion criteria were adopted in order to select the studies for analysis: a) experimental studies, in which only training with overload had been used; b) target population composed of apparently healthy individuals of both sexes, aged 60 years or older.

Only the studies published and found through electronic search on Medline, Lilacs and Sport Discuss participated in the selection. The following steps were used for the studies' prospection: a) search algorithms with recognition of specialized literature; b) reference lists of the found studies; c) manual search of the articles in magazines not virtually found.

166 studies were initially selected from which only 22 fulfilled the pre-set inclusion criteria. The following items were analyzed from the selected studies: a) interventions training methodology (number of series; number of repetitions; weekly frequency; exertion intensity; order and interval between exercises series; b) the found results.

In order to analyze the found results, the 22 selected studies were grouped by treatment similarity (number of series; weekly frequency; intensity; intervals and exercises order) and their results concerning strength gain were summed and over the sum the mean was applied for determination of the dose-response of their treatments. The differences between the found means in each study group were qualitatively analyzed.

PRESENTATION AND DISCUSSION OF RESULTS

Number of series

The analysis of the 'number of series' variable revealed that within the 22 studies which fulfilled the selection criteria, only three presented as aim the comparison of its effect on the strength gain (chart 1). From these, only one had as aim to specifically investigate the different strength gains facing different number of series for the same muscle group; namely, the one developed by Harris et al.⁽²³⁾. The other two, by Menkes et al.⁽²⁴⁾ and Treuth et al.⁽²⁵⁾, verified the difference in the strength gain between lower (LL) and upper limbs (UL), (1 series for UL and 2 series for LL). The results of these two kinds of studies are presented in chart 1. There was no significant difference between the training groups, which may suggest that the upper limbs would need greater work volume. However, no study compared the obtained results with an equal number of series for UL and LL. Another issue refers to possible differences of response in men and women, since the two studies were developed only with men.

Women and men participated in the study developed by Harris et al.⁽²³⁾. Two series of 15RM; 3 of 9RM and 4 of 6RM were compared; however, no significant difference between groups was identified. This result could suggest that, in older ages, the number of series would not influence in the strength gains. Nonetheless, since it is the only study with such outline, any affirmation would be too early. Yet, the lack of data concerning the best number of series for the development of strength is not exclusive to training with elders. As illustration, in a recent review, Gomes and Pereira⁽¹⁷⁾ demonstrated that there was not sufficient evidence to affirm that multiple series are better than single series when reviewing the studies available about training for young adults.

Although no strong evidence has appeared concerning the best number of series for the development of muscular strength in the elderly, the majority of the analyzed studies pointed to the utilization of three series in their treatment, totalizing thirteen studies. Only three adopted two series and two a single series (chart 2).

If a mean of the results in strength increase of all studies which used three series was possible, a result of 40% would be found. In the ones which used two series 37.3% would be found; and of the ones which used only one series, 58%. This kind of analysis is questionable, since the analyzed studies present different outlines (exertion intensity, weekly frequency, involved muscular groups and training duration). Conversely, concerning such restrictions, one cannot deny that the focus is illustrative in terms of the weak relationship of the number of series with effective strength gains in this population.

A single study found was not considered for the calculation of the mean gain mentioned: it is the study developed by Lamoureux et al.⁽²⁶⁾. Such fact is due to its completely different outline from the others. The authors investigated the effect of the progressive increase of the workload as well as the number of series during six-month training, which led to an increase of 235% in the strength of the involved subjects. No other study with similar aim and methods was found, making a comparative analysis difficult.

Weekly frequency

Only one study was found with the concern to investigate the influence of the 'weekly frequency' variable in the muscular strength gain in older subjects. Taaffe et al.⁽³¹⁾ developed a study with 53 individuals distributed in four groups: one which trained once a week; another which trained two times a week; a third which trained three times a week; and a fourth which was characterized as control group. The trainings lasted 24 weeks and the authors did not find significant differences among the experimental groups.

Despite the lack of comparative studies which support the hypothesis that routines involving three weekly sessions are better than those involving one or two sessions, 19 of the 22 analyzed studies used a frequency of three weekly times in their research (chart 3). Only one study used two sessions, while none conducted research with a single weekly training session.

Adopting the same mentioned outline for the number of series, when the mean of the obtained results in the 19 studies which used a training weekly frequency of three days is considered, an approximate value of 45.03% in strength gain in elders will be found. Harris et al.⁽²³⁾, in studies developed with application of only two weekly sessions found a very similar mean of 47.5%. Somehow, such fact tends to reinforce the findings by Taaffe et al.⁽³¹⁾. However, the analysis consistency is harmed due to the studies' distinct outlines.

It is worth mentioning once again that the study by Lamoureux et al.⁽²⁶⁾, was not considered for the determination of the mean strength gain due to its methodological characteristics completely different from the others. Besides applying a progressive increase of the workload intensity and the number of series during six months of training, the authors also varied the weekly frequency, beginning with a three-day frequency at the first three months and finishing with two weekly training sessions at the last three months. As previously mentioned, this variation in the subjects' treatment as well as not finding another similar study, do not lead to any further conclusions. The strength gains though, were fairly higher than the ones observed by the remaining studies.

Workload intensity

The workload intensity in the strength training, represented by the 1RM percentage or by the number of maximal repetitions that the individuals perform at each series developed in the counter-resistance program, is the variable which has taken the most space in the studies of the specialists of the field, comparing with the others.

From the 22 studies analyzed, six adopted as main topic the comparison between low and high intensities; among which, four found significant differences with advantage for the high workloads, most of the times established in a threshold of 80% of 1RM^(3,27,37). Only the study by Tisutisumi et al.⁽³⁵⁾ worked with loads which were kept between 75 and 85%. Generally, loads between 40% and 65% of 1RM are considered low, as can be seen in chart 4.

Considering the same approach used for the previous variables, the mean gains obtained by the individuals who trained with high intensity behaved steady at around 55.6%, while the ones who trained with low intensity were kept at around 39.9% (chart 5).

It is interesting to verify in chart 4 that two studies: Kalapotharakos et al.⁽³⁾ and Seynnes et al.⁽²⁷⁾, presented a very similar outlining when the weekly frequency was considered (3 x week), 1 RM percentage (80%) and training time (12 and 10 weeks, respectively). The other two studies, by Tisutisumi et al.⁽³⁵⁾ and Vincent et al.⁽³⁷⁾, worked with one and two series and training time of 24 and 25 weeks, respectively. It is worth mentioning that Vincent et al.⁽³⁷⁾, using the lowest number of series, found the highest strength gains with high load intensity (79%).

Two studies did not find significant differences in the strength increase of elders when trainings with high and low loads were compared. The one by Hunter et al.⁽²⁾ compared a group which trained with two series at 80% of 1RM intensity with a group which trained one day a week at 50%; another day at 65%; and on the third day at 80%. The authors found a mean strength increase of 28.5% and 37.1% for upper and lower limbs respectively, for the first and second groups. However, it would not be possible to characterize the second group as trained only with low loads, but varied instead. There are no other studies which can aid in the discussion of the role of loads variation in the potential increase of strength in short and middle-term trainings. Nonetheless, one may think that the strength gains derived from coordinative adaptations, predominant in this kind of program, are the origin of the obtained results. Perhaps the neural component is sensitive to this kind of manipulation, once it is reflected in the recruitment pattern of the motor units^(1-2). Hence, the motor repertoire associated with the program is enriched, with possible effect on the contraction optimization in the proposed exercises⁽¹⁾.

The study by Harris et al.⁽²³⁾ did not find significant differences between different work intensities, comparing groups which trained with two series of 15RM; three series of 9RM and 4 series of 6RM. The gains observed by the authors, respectively for each group, were of 44.51 and 50% of the strength measured on the baseline. As the number of series also varied, the total work of the groups behaved similarly, which makes it difficult to conclude that the different intensities added to the number of maximal repetitions performed would have the same potential of strength development.

Therefore, generally speaking, there is evidence that the high intensity workloads cause a significantly higher increase in strength gains in elders than with lower workloads. These findings may be explained by the fact that the main factors which contribute to the strength increase due to training are the neural and hypertrophic adaptations⁽³⁹⁾. In an early moment of the training, the neural development tends to be the preferential via for the improvement of the capacity to mobilize workloads, since a higher level of strength may be created through the increase of the frequency as well as the recruitment of motor units of the muscular groups involved in the movement^(40-41). Kraemer et al.⁽⁴²⁾, within this context, point that the recruitment of the motor units through the high intensity of the neural work may previously enable underused muscular fibers to be trained.

This possibility seems to be well-accepted by the literature: of the 16 studies found which did not have as aim to compare different training intensities over the strength gains, 12 used workloads above 75% of 1 RM in their treatments, while only four applied loads below this limit (chart 5). Once again, the expressive results obtained in the study by Lamoureux et al.⁽²⁶⁾ separately highlight: the authors found in response to high load training (85% of 1RM), an increase of 235% in strength in elders. Despite a very different outline from the remaining studies, such finding reinforces the evidence that intense loads generate higher strength increases comparing with reduced loads.

Intervals and exercises order

Since it has received less attention from the researchers, the 'interval between series and exercises' variable was not main object of investigation in any of the 22 studies included in this systematic review. Moreover, not all investigated studies described the interval time adopted in the treatment as part of the experimental procedures. Of the 22 analyzed studies, only 14 described the used intervals, which varied from one to three minutes. Regardless the intensity and volume of the series used in the training, the great majority (10 studies) adopted, even with no evidence that this is the ideal parameter for elders, the mean time of two minutes for recovery between series and exercises.

Concerning the exercises order, of all the variables involved in the counter-resistance training, this one seems to be the one with the least attention. Besides not having been aim of specific investigation in any of the 22 studies found, not even the used order in their treatments was reported. Thus, no inference or comment on the relative influence of this variable in the context of a dose-response relationship is possible.

It is interesting to note that Simão⁽³⁹⁾, when reviewing studies conducted with young adults, found the same difficulties to identify consensus concerning these training variables. In other words, although it is accepted that exercises involving large muscular groups should be placed at the beginning of training sessions, this recommendation does not seem to find support in several scientific evidences. The same episode occurred with the 'interval between series and exercises' variable the author only found studies analyzing intervals in tests of maximal workload, but none which had focused them as study object in an exercises sequence.

FINAL CONSIDERATIONS

The benefits promoted by the counter-resistance training depend on the combination of variables with the number of repetitions, series, overload, sequence and intervals between series and exercises⁽¹⁶⁾.

When reviewing the studies published so far with the aim to verify the existence of common trends concerning the methodological variables of strength training for elders (load intensity; number of repetitions; number of series; interval between series; exercises order and weekly frequency), the best combination of these variables for an optimum dose-response relationship was uncertain. Furthermore, it widely reproduces what is observed concerning the training of young adults. Therefore, the results found in the present review lead to a conclusion similar to that of the review study by Gomes and Pereira⁽¹⁷⁾: different combinations of the training variables may be equally efficient for strength development of elders.

Individually analyzed, the variables have not been widely investigated with the aim to determine the effects on the strength gain of this or that strategy when populations with older subjects were considered. Concerning the number of series and weekly frequency, only one study involving each of these variables was found. None presented significant differences between the results of the groups which worked with different manipulations, which tends to reinforce the idea that there are several obscure aspects concerning the dose-response relationships in strength training with elders. The results available in the literature; therefore, do not support the almost consensual choice of the analyzed studies: three series performed in a frequency of three weekly days for the designing of their training programs. It seems that this choice has been based only on the recommendations by the ACSM for the training of young adults, regardless the biological differences which may somehow influence the trainability potential of older subjects.

Concerning the exertion intensity, six studies compared strength gains in elders submitted to trainings with high and low intensities; four found significant differences, showing evidence that higher loads would be more efficient for the production of strength increase in this age group. These findings support the almost exclusive adoption high training intensities from the found studies. However, there are still obscure zones, specially concerning programs with varied load or the effects derived from short and long training periods in other words, the manipulation of the work intensity and the magnitude of strength gains attributed to coordinative and hypertrophic adaptations in older subjects still raises concerns which deserve further investigation.

It was not possible to develop considerations concerning the manipulation of the variables associated with the intervals between exercises and series neither the exercises order. None of them was main objective of investigation in any of the 22 studies included in the present systematic review. Concerning the 'exercises order', besides not having been investigated, one can see that the studies did not even describe it. This fact is a gap to be explored, since the procedures usually adopted refer to the recommendations by the ACSM⁽¹⁸⁾ when the exercises involving large muscular groups are performed prior to those which recruit smaller groups. Studies in our laboratory show that this is not always the most suitable procedure, depending on the training session's purpose as well as the fitness level of the practitioner⁽³⁹⁾. Data on how older individuals respond to different acute and chronic exercises order were not found in the literature researched.

Thus, it can be concluded that further investigation is needed concerning different combinations of variables of strength training for the elderly. Within this context, we suggest that additional effort should be applied with the purpose to make them clearer, especially concerning the outline of training programs which combine effectiveness and safety.

REFERENCES

Received in 17/7/05.

Final version received in 19/4/06.

Approved in 19/7/06.

All the authors declared there is not any potential conflict of interests regarding this article.

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15. Latham N, Anderson C, Bennett D, Stretton C. Progressive resistance strength training for physical disability in older people. Cochrane Database Syst Rev. 2003; CD002759.
16. Wolfe BL, Lemura LM, Cole PJ. Quantitative analysis of single- vs. multiple set programs in resistance training. J Strength Cond Res. 2004;18:35-47.
17. American College of Sports Medicine. Position stand: progression models in resistance training for healthy adults. Med Sci Sports Exerc. 2002;34:364-80.
18. Rhea MR, Alvar BA, Burkett LN, Ball SD. A meta-analysis to determine the dose response for strength development. Med Sci Sports Exerc. 2003;456-64.
19. Gomes PS, Pereira MIR. Treinamento contra resistência: revisitando freqüência semanal, número de séries, número de repetições, intervalo de recuperação e velocidade de execução. Rev Bras Fisiol Exerc. 2002;1:16-32.
20. Pearson D, Faigenbaum A, Conley MMD, Kraemer WJ. The National Strength and Conditioning Association's basic guidelines for the resistance training of athletes. J Strength Cond. 2000;22:14-27.
21. Todd J, Todd T. Peter V. Karpovich: transforming the strength paradigm. J Strength Cond Res. 2003;17:213-20.
22. Westcott W, Baechle T. Treinamento de força para a terceira idade. São Paulo: Manole, 2001.
23. Harris C, DeBeliso M, Spitzer-Gibson TA, Adams KJ. The effect of resistance-intensity on strength-gain response in the older adult. J Strength Cond Res. 2004; 18:833-8.
24. Menkes A, Mazel S, Redmond RA, Koffler K, Libanati CR, Gundberg CM, et al. Strength training increases regional bone mineral density and bone remodeling in middle-aged and older men. J Appl Physiol. 1993;74:2478-84.
25. Treuth MS, Ryan AS, Pratley RE, Rubin MA, Miller JP, Nicklas BJ, et al. Effects of strength training on total and regional body composition in older men. J Appl Physiol. 1994;77:614-20.
26. Lamoureux E, Sparrow WA, Murphy A, Newton RU. The effects of improved strength on obstacle negotiation in community-living older adults. Gait Posture. 2003;17:273-83.
27. Seynnes O, Singh MAF, Hue O, Pras P, Legros P, Bernard PL. Physiological and functional responses to low-moderate versus high-intensity progressive resistance training in frail elders. J Gerontol Med Sci. 2004;59:503-9.
28. Reeves ND, Narici MV, Maganaris CN. Effect of resistance training on skeletal muscle-specific force in elderly humans. J Appl Physiol. 2004;96:885-92.
29. Miszko TA, Cress ME, Slade JM, Covey CJ, Agrawal SK, Doerr CE. Effect of strength and power training on physical function in community-dwelling older adults. J Gerontol. 2003;58:171-5.
30. Brandon LJ, Boyette LW, Gaasch DA, Lloyd A. Effects of lower extremity strength training on functional mobility in older adults. J Aging Physical Activity. 2000;8: 214-27.
31. Taaffe DR, Duret C, Wheeler S, Marcus R. Once-weekly resistance exercise improves muscle strength and neuromuscular performance in older adults. J Am Geriatr Soc. 1999;47:1208-14.
32. Morganti CM, Nelson ME, Fiatarone MA, Dallal GE, Economos CD, Crawford BM, et al. Strength improvements with 1 yr of progressive resistance training in older women. Med Sci Sports Exerc. 1995;27:906-12.
33. Judge JO, Whipple RH, Wolfson LI. Effects of resistive and balance exercises on isokinetic strength in older persons. J Am Geriatr Soc. 1994;42:937-46.
34. Pika G, Lindenberg E, Charette S, Marcus R. Muscle strength and fiber adaptations to a year-long resistance training program in elderly men and women. J Gerontol Med Sci. 1994;49:23-7.
35. Tsutsumi T, Don BM, Zaichkowsky LD, Delizonna LL. Physical fitness and psychological benefits of strength training in community dwelling older adults. Appl Human Sci. 1997;16:257-66.
36. Schlicht J, Camaione DN, Owen SV. Effect of intense strength training on standing balance, walking speed, and sit-to-stand performance in older adults. J Gerontol Med Sci. 2001;56:281-6.
37. Vincent KR, Braith RW. Resistance exercise and bone turnover in elderly men and women. Med Sci Sports Exerc. 2002;34:17-23.
38. Hurley BF, Redmond RA, Pratley RE, Treuth MS, Rogers MA, Goldberg AP. Effects of strength training on muscle hypertrophy and muscle cell disruption in older men. J Sports Med. 1995;16:378-84.
39. Simão Junior RF. Influência da ordem dos exercícios sobre o número de repetições, percepção subjetiva de esforço e consumo de oxigênio em sessões de treinamento resistido [Tese de Doutorado]. Rio de Janeiro: Universidade Gama Filho, 2004.
40. Bloomer RJ, Ives JC. Varying neural and hypertrophic influences in a strength program. J Strength Cond Res. 2000;22:30-5.
41. Burke RE. Selective recruitment of motor units. West Sussey: Sons, 1991.
42. Kraemer WJ, Fleck SJ, Evans WJ. Strength and power training: physiological mechanisms of adaptation. Exerc Sport Sci Rev. 1996;24:363-97.

Correspondence to:

Nádia Lima da Silva

Laboratório de Atividade Física e Promoção da Saúde

Universidade do Estado do Rio de Janeiro

Rua São Francisco Xavier, 524, sala 8133-F, Maracanã

20550-013 Rio de Janeiro, RJ

E-mail:

nadialima@globo.com ou

farinatt@uerj.br

Publication Dates

Publication in this collection
11 Sept 2007
Date of issue
Feb 2007

History

Accepted
19 July 2006
Reviewed
19 Apr 2006
Received
17 July 2005

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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[12] 12. Frontera W, Meredith CN, O'Reilly KP, Knuttgen HG, Evans WJ. Strength conditioning in older man: skeletal muscle hypertrophy and improved function. J Appl Physiol. 1988;64:1038-44.

[13] 13. Fiantarone MA, Marks EC, Ryan ND, Meredith CN, Lipsitz LA, Evans WJ. High-intensity strength training in nonagenarians. JAMA. 1990; 264:3029-34.

[14] 14. Valkeinen H, Alen M, Hannonen P, Hakkinen A, Airaksinen O, Hakkinen K. Changes in knee extension and flexion force, EMG and functional capacity during strength training in older females with fibromyalgia and healthy controls. Rheumatology. 2004;43:225-8.

[15] 15. Latham N, Anderson C, Bennett D, Stretton C. Progressive resistance strength training for physical disability in older people. Cochrane Database Syst Rev. 2003; CD002759.

[16] 16. Wolfe BL, Lemura LM, Cole PJ. Quantitative analysis of single- vs. multiple set programs in resistance training. J Strength Cond Res. 2004;18:35-47.

[17] 17. American College of Sports Medicine. Position stand: progression models in resistance training for healthy adults. Med Sci Sports Exerc. 2002;34:364-80.

[18] 18. Rhea MR, Alvar BA, Burkett LN, Ball SD. A meta-analysis to determine the dose response for strength development. Med Sci Sports Exerc. 2003;456-64.

[19] 19. Gomes PS, Pereira MIR. Treinamento contra resistência: revisitando freqüência semanal, número de séries, número de repetições, intervalo de recuperação e velocidade de execução. Rev Bras Fisiol Exerc. 2002;1:16-32.

[20] 20. Pearson D, Faigenbaum A, Conley MMD, Kraemer WJ. The National Strength and Conditioning Association's basic guidelines for the resistance training of athletes. J Strength Cond. 2000;22:14-27.

[21] 21. Todd J, Todd T. Peter V. Karpovich: transforming the strength paradigm. J Strength Cond Res. 2003;17:213-20.

[22] 22. Westcott W, Baechle T. Treinamento de força para a terceira idade. São Paulo: Manole, 2001.

[23] 23. Harris C, DeBeliso M, Spitzer-Gibson TA, Adams KJ. The effect of resistance-intensity on strength-gain response in the older adult. J Strength Cond Res. 2004; 18:833-8.

[24] 24. Menkes A, Mazel S, Redmond RA, Koffler K, Libanati CR, Gundberg CM, et al. Strength training increases regional bone mineral density and bone remodeling in middle-aged and older men. J Appl Physiol. 1993;74:2478-84.

[25] 25. Treuth MS, Ryan AS, Pratley RE, Rubin MA, Miller JP, Nicklas BJ, et al. Effects of strength training on total and regional body composition in older men. J Appl Physiol. 1994;77:614-20.

[26] 26. Lamoureux E, Sparrow WA, Murphy A, Newton RU. The effects of improved strength on obstacle negotiation in community-living older adults. Gait Posture. 2003;17:273-83.

[27] 27. Seynnes O, Singh MAF, Hue O, Pras P, Legros P, Bernard PL. Physiological and functional responses to low-moderate versus high-intensity progressive resistance training in frail elders. J Gerontol Med Sci. 2004;59:503-9.

[28] 28. Reeves ND, Narici MV, Maganaris CN. Effect of resistance training on skeletal muscle-specific force in elderly humans. J Appl Physiol. 2004;96:885-92.

[29] 29. Miszko TA, Cress ME, Slade JM, Covey CJ, Agrawal SK, Doerr CE. Effect of strength and power training on physical function in community-dwelling older adults. J Gerontol. 2003;58:171-5.

[30] 30. Brandon LJ, Boyette LW, Gaasch DA, Lloyd A. Effects of lower extremity strength training on functional mobility in older adults. J Aging Physical Activity. 2000;8: 214-27.

[31] 31. Taaffe DR, Duret C, Wheeler S, Marcus R. Once-weekly resistance exercise improves muscle strength and neuromuscular performance in older adults. J Am Geriatr Soc. 1999;47:1208-14.

[32] 32. Morganti CM, Nelson ME, Fiatarone MA, Dallal GE, Economos CD, Crawford BM, et al. Strength improvements with 1 yr of progressive resistance training in older women. Med Sci Sports Exerc. 1995;27:906-12.

[33] 33. Judge JO, Whipple RH, Wolfson LI. Effects of resistive and balance exercises on isokinetic strength in older persons. J Am Geriatr Soc. 1994;42:937-46.

[34] 34. Pika G, Lindenberg E, Charette S, Marcus R. Muscle strength and fiber adaptations to a year-long resistance training program in elderly men and women. J Gerontol Med Sci. 1994;49:23-7.

[35] 35. Tsutsumi T, Don BM, Zaichkowsky LD, Delizonna LL. Physical fitness and psychological benefits of strength training in community dwelling older adults. Appl Human Sci. 1997;16:257-66.

[36] 36. Schlicht J, Camaione DN, Owen SV. Effect of intense strength training on standing balance, walking speed, and sit-to-stand performance in older adults. J Gerontol Med Sci. 2001;56:281-6.

[37] 37. Vincent KR, Braith RW. Resistance exercise and bone turnover in elderly men and women. Med Sci Sports Exerc. 2002;34:17-23.

[38] 38. Hurley BF, Redmond RA, Pratley RE, Treuth MS, Rogers MA, Goldberg AP. Effects of strength training on muscle hypertrophy and muscle cell disruption in older men. J Sports Med. 1995;16:378-84.

[39] 39. Simão Junior RF. Influência da ordem dos exercícios sobre o número de repetições, percepção subjetiva de esforço e consumo de oxigênio em sessões de treinamento resistido [Tese de Doutorado]. Rio de Janeiro: Universidade Gama Filho, 2004.

[40] 40. Bloomer RJ, Ives JC. Varying neural and hypertrophic influences in a strength program. J Strength Cond Res. 2000;22:30-5.

[41] 41. Burke RE. Selective recruitment of motor units. West Sussey: Sons, 1991.

[42] 42. Kraemer WJ, Fleck SJ, Evans WJ. Strength and power training: physiological mechanisms of adaptation. Exerc Sport Sci Rev. 1996;24:363-97.

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