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The Effect of Power Training versus Strength Training on Lower Extremity Function in Community-Dwelling.. Craig, Jason 2008

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The Effect of Power Training versus Strength Training on Lower Extremity Function in Community- Dwelling Older Adults Jason Craig Cori Hanan Ryan Jeans Christina Langer Jill Morris Supervised by: Dr. Teresa Liu-Ambrose OUTLINE 1. Background 2. Rationale 3. Methods 4. Results 5. Discussion 6. Conclusion 7. Recommendations BACKGROUND 4Background ¾ Aging population z 2003, 13% of Canadians > 65 yrs z By 2031, 23% > 65 yrs ¾ Increased proportion of older adults Æ increase in chronic disease and co- morbidities In 2006 4.3 million Canadians were 65 years or older, accounting for one third of Canada’s population (2). The number of senior citizens in Canada is increasing, which will place an increased demand on our health care system. Background ¾ Sarcopenia: the age related decline in muscle mass resulting from a decrease in the size and number of muscle fibers2 z decreased ability to produce force z increased risk of falls, impaired mobility, decreased functional independence3 Background ¾ Functional Independence: the ability to perform ADLs and IADLs without help from other individuals4 ¾ LE function is a major component of functional independence Define LE Function 7Background ¾Resistance training combats sarcopenia and minimizes the decline in LE function in older adults8 z reduces fall risk z decreases fall-related health care costs z reduces the loss of independence Falls are expensive, as they result in increased hospitalization and decreased functional independence in the older adult (10 and 11). Strength and Power Training Definitions Strength training (ST) ¾ multiple- and single- joint exercises performed at a slow velocity for 1-3 sets of 8-10 reps at 60- 80% of 1RM15 Power training (PT) ¾ multiple- and single- joint exercises performed at a high velocity for 1-3 sets of 6-10 reps at 40- 60% 1RM15 9Strength Training ¾ Positive effects of ST on the older adult: z improved muscle performance z Improved bone health z attenuation of sarcopenia9 ¾ ST has become a routinely prescribed form of exercise for older adults9 The first randomized controlled trials (RCTs) studying the effects of ST on muscle mass in the elderly appeared in the literature twenty-five years ago (9). 10 Power Training ¾ PT is emerging as an alternative form of resistance training for older adults ¾ Impaired physical performance may be due to a lack of muscle power rather than a lack of strength.14  Motor tasks performed under daily conditions require movements at higher speeds and variable external resistance9 ¾ The effects of PT on sarcopenia have not been thoroughly studied13 and may be a more effective intervention than strength training for improving function and decreasing disability in the elderly (12). Rationale ¾ Two systematic reviews have examined the effect of ST on LE function in the older adult8, 14 z reviews reported positive effect of ST on lower extremity (LE) strength; few RCTs utilized outcome measures relevant to LE function in older adults such as sit to stand ability8, 14 Rationale ¾No published systematic reviews comparing the effects of PT versus ST z Unclear which form of resistance training is more effective in improving LE function in older men and women Systematic Review Purpose 1. Examine the effect of PT versus ST on LE function in community-dwelling older adults 2. Determine the optimal method of resistance training to maintain and improve LE function in the older adult Define LE function METHODS 1. Inclusion Criteria 2. Search Strategy 3. Study Selection 4. Data Extraction 5. Study Quality 6. Data Analysis Inclusion Criteria 1) Mean age of 65 years or older 2) Independent, community-dwelling adults 3) Direct comparison of ST and PT 4) Published in English 5) Supervised exercise intervention 6) Minimum of one LE function outcome measure 1) Mean age of 65 years or older 2) Independent, community-dwelling adults -For example, papers had to mention that subjects were independent with daily living or were well functioning. 3) Direct comparison of only ST and PT -No combined training (i.e. no aerobic ex) 4) Published in English 5) Supervised exercise intervention 6) Minimum of one LE function outcome measure Outcome Measure: LE function ¾ A tool that assesses components of ADLs involving the LE ¾ Examples of acceptable LE function outcome measures include: 1) gait speed 2) chair-rise time 3) functional reach 4) static and dynamic balance Search Strategy ¾ Journal articles were selected from numerous databases including: 1. MEDLINE 2. CINAHL 3. EBM Reviews 4. Sports Discus 5. EMBASE Other Sources: 1. ProQuest and National Research Register for unpublished theses 2. Google scholar 3. Experts in the field 4. Hand searching Search Terms Power training • high velocity resistance training • high intensity resistance training • plyometrics • speed training Strength training • resistance training • weight lifting • resistance exercise • low velocity resistance training • low intensity resistance training Search Strategy ¾ The search was further limited to: 1. Humans 2. English language 3. Age 65 years or older, or was combined with keywords for older adults (aged, elder, geriatric, senior, older people) Data Extraction ¾ Developed and pilot tested own data extraction tool from multiple sources ¾ Data extraction included: 1. Study characteristics 2. Intervention characteristics 3. Outcome measures 4. Drop-Outs and Adverse Events 5. Study quality 6. Major study conclusions Study Quality and Level of Evidence PEDro ¾ 8-10 = Excellent ¾ 6-7 = Good ¾ 4-5 = Moderate ¾ 1-3 = Poor Oxford CEBM Levels of Evidence •To assess the quality of the included studies two independent reviewers used the PEDro scale and the Oxford Center of Evidence Based Medicine Levels of Evidence. •PEDro, is a 11 item quality AX tool, designed primarily for the evaluation of physiotherapy-based studies •Although there are limitations to using the PEDro scale such as the difficulty in PT interventions to blind subjects to their tx group, it was sensitive to differences in the quality of the included studies. • A third reviewer resolved any disagreements regarding PEDro scores or the level of evidence assigned to a study. Data Analysis ¾ A meta-analysis was planned initially, but was not performed because of statistical and clinical heterogeneity ¾ Standardized mean differences and 95% confidence intervals (CI) were calculated for continuous outcome measures using Hedges adjusted g, which accounts for small sample size. ¾ Conventional effect sizes used. • 0.2  = small • 0.5 = medium • 0.8 = large Cohen’s d does not account for sample size. 22 Data Analysis ¾ No significant differences at baseline, therefore post-test scores were used for effect size calculation. ¾ Only outcome measures that were utilised in the majority of studies were analysed. ¾ Primary analysis compared PT vs ST ¾ Secondary analysis compared PT and ST vs control RESULTS Study Selection Excluded by screening abstracts (N = 165 ) Excluded by removing duplicates (N= 77) •Two reviewers independently screened titles and then abstracts from the database searches to identify potentially relevant articles. •Disagreements during the first two stages of screening were resolved by including the studies for the next stage of review to eliminate selection bias. •After removal of duplicates 94 articles remained. Excluded after evaluation of abstracts (N = 65) •Not head to head •Not supervised •Age Excluded from SR (N = 23) •No functional outcome •No PT component •Full evaluation of abstracts excluded several more articles (for reasons such as not a head to head comparison, not a supervised ex. intervention, and age limitations). 29 articles remained. •Full text copies of the selected studies were then obtained and two reviewers independently reviewed the articles to determine if inclusion criteria were met. Articles were excluded for several reasons (no functional outcome measures, no PT).   Any disagreements during the final stage of study selection were resolved by a third reviewer. •In the end 6 RCTs remained for data extraction. 27 Study Quality and Level of Evidence ¾ PEDro z Good quality = 3 z Moderate quality = 2 z Poor quality = 1 ¾ Intention to treat = 0 ¾ Blinding = 2 ¾ Oxford CEBM Levels of Evidence z All 2B, low quality RCTs Explain what pedro scores mean Study Characteristics ¾ Control group = 3 ¾ No control group = 3 ¾ All studies performed in a structured setting ¾ Female only = 3 ¾ Male only = 1 ¾ Male and female = 2 ¾ Sample size = 20-61 subjects ¾ Age range = 60-90 years 29 Study Characteristics ¾ Drop-outs z 1-11 subjects, with an average of 5 per study ¾ Adverse events z Reported = 3/Unreported = 3 ¾ Compliance: z Reported = 3/Unreported = 3 z 88-95 % compliance was recorded ¾ No treatment group had disproportionate drop-outs, adverse events or compliance. Reasons for drop-out included transportation, personal and family complications, medical issues, and time commitments. Reported adverse events included exacerbation of plantar fasciitis and pre-existing osteoarthritis (Sayers), as well as six falls and three musculoskeletal injuries including a hamstring tear (Mizko). Intervention Characteristics NUMBER OF EXERCISES •6-8 exercises = 4 studies •2-4 exercises = 2  studies SETS 1-3 REPETITIONS 6-8 TRAINING DURATION 8-16 weeks FREQUENCY 2-3 times per week INTENSITY •Strength: Ranged from body weight to 80% 1RM •Power: Ranged from 40-75% 1RM with exception of the weighted vest Number of Exercise…… The types of exercise performed in the studies were: 1) leg press (4 studies), 2) knee ext.(all studies), 3) leg curl (5 studies), 4) ankle PF (3 studies), 5) squats (1 study), 6) hip flexion (1 study), 7) chair stands (1 study) 4 studies also included upper extremity exercises in their program such as chest press, seated row, bicep curl, and tricep ext. All these characteristics met ACSM guidelines for PT and ST except: 1. one study that used BW for ST and a weighted vest for PT as their intensity levels. The weighted vest was increased by 2% of the subjects BW if the subject was able to perform prior weight with no difficulty. Intervention Characteristics Exercise Speed (Tempo) •PT groups completed the exercise as fast as possible •ST exercises were performed over 4-6 seconds Equipment •Weight machines = 5 •Body weight for ST and weighted vest for PT = 1 Familiarization period 2 studies: •1 included within the treatment time •1 done prior to baseline measures •PT groups completed the exercise as fast as possible •ST exercises were performed over 4-6 seconds 5 studies used various types of exercise equipment, such as an isokinetic dynamometer, Keiser pneumatic equip., Extek resistance equip., and 1 study performed all ex. Sitting in a chair using BW or BW + Weighted Vest. A familiarization period was included by 2 studies with one being performed before baseline and the other within treatment time. All these characteristics met ACSM guidelines for PT and ST. 32 Data Analysis Results ¾ Effect sizes and 95% CI were calculated for: z PT vs ST z PT vs Control z ST vs Control ¾ For the following outcome measures: z LE strength z LE power z Chair rise function z Gait velocity As a meta- analysis was not performed due to clinical and statistical heterogeniety between the studies, hedges adjusted g effect sizes and 95% CI were calculated. Our primary comparison was PT vs. ST, however, we also performed secondary comparisons of PT vs. Control and ST vs. Control. The outcome measures of LE strength, LE power, Chair rise function, and gait velocity were selected for analysis because they were utilized in the majority of the included studies. Note, complete data was not obtained for two studies (Sayers, Bean) despite efforts to contact authors for additional data. As a result, change mean scores and standard deviations were used for data analysis where available (Bean). 33 LE Strength (PT vs ST) Figure 2. PT versus ST for LE Strength (1RM Leg Press, Kg) * Isokinetic knee extension peak torque @ 60 degrees/sec (Nm) * Our first primary comparison was ……. The outcome measure was the same for all studies except Carmel, which used isokinetic knee ext. as their outcome. To reiterate the effect size levels, a small effect = 0.2, a medium effect = 0.5, and a large effect = 0.8. For this outcome, effect sizes ranged from negligible at 0.05 to medium at 0.68. However, no clear effect was evident for PT vs. ST as shown by the inconsistent effect measures and large and variable confidence intervals. It is also important to note that No statistical significant differences were found between groups for any of the studies. Therefore, we could not conclude which training intervention was more effective at improving LE strength 34 LE Power (PT vs ST) Figure 3. PT versus ST for LE Power (Leg Press Peak Power, W) * Isokinetic knee extension average power @ 300 deg/sec (W) ** Wingate anaerobic cycle test (W) β Significant difference for PT v. ST groups * ** β β Our next comparison was……….. The outcome measure used by 2 studies was leg press peak power, whereas, the study by Bean used the Wingate anaerobic cycle test for peak power, and the Carmel study used isokinetic knee ext. average power. All measures analysed power in watts. For this outcome, effect sizes ranged from small at 0.16 to large at 2.87.Two studies were inconclusive about treatment efficacy (miz, car), as evident by small effect sizes and variable CI’s. On the otherhand, two studies clearly favored PT, as evident by large effect sizes and consistent CI’s supporting PT. Also, both studies found a statistical significant difference for PT vs. ST on this outcome. Therefore, we could conclude from this analysis that PT may be more effective at improving LE Power compared to ST. 35 Chair Rise (PT vs. ST) Figure 4. PT versus ST for Chair Rise Function (Stand up & sit down, seconds) * number of chair stands in 30 seconds β Significant difference for PT versus ST groups β *β Our next comparison was………. The outcome measure used by 3 studies was stand up & sit down measured in seconds. Whereas the study by Bottaro used the number of chair stands in 30 secs to measure this outcome. For this outcome, effect sizes ranged from small at 0.43 to large at 1.72. All studies favored the PT group with 2 studies displaying a large effect that clearly favors PT, and 2 studies having small to medium effects. However, the study by Bottaro was not as conclusive due to the variable CI. 2 studies, Bean that clearly favors PT, and Bottaro that is inconclusive, found a statistical significant difference for PT versus ST. Therefore, we could conclude from this analysis that PT may be more effective at improving chair rise function compared to ST. However caution must be taken when drawing conclusions due to the lack of statistical significance across all studies, particularly those that appear to favour PT. 36 Gait Velocity (PT vs. ST) Figure 5. PT v. ST for Gait Velocity (Gait velocity, m/s) * ** *** * Time to walk 2.4m (Gait velocity calculated from time and distance) ** Time to walk 15ft (Gait velocity calculated from time and distance) *** Time to walk 6m (seconds) Lastly, we compared………. The outcome measures used by 2 studies was Gait velocity in m/sec, whereas the study by Henwood measured time to walk 6m in seconds. Distances walked ranged from 2.4m to 6m. For this outcome, effect sizes ranged from no effect at 0.0 to medium at 0.45. The study by Carmel had an insignificant effect size with a large and variable CI, thus making the result inconclusive. And the study by Bean had a medium effect size favoring PT, however the large and variable CI makes the result inconclusive again. Also, No statistical significant differences for PT vs ST were found for any of the studies. Therefore, we could not conclude which training intervention was more effective at improving Gait Velocity. Continuous Scale Physical Function Performance (CS-PFP) test, a global outcome measure for function, was used for one study. A large effect size, favoring the power training group (SMD 0.79;95% CI -0.04,1.63) was calculated for the CS-PFP total score. Statistical significance found for PT vs. ST ST vs Control for analyzed outcome measures ¾ Data was obtained from the three studies that had control groups. Large and medium effect sizes for LE strength favored strength training for all three studies. Significant difference found in 2 studies. ¾ Medium effect sizes favoring strength training were also calculated on LE power for two studies. No significant difference found in either study. ¾ Chair rise performance favored the control group for one study and strength training for the other. No significant difference found for either study. ¾ A small gait velocity effect size favored the control group for one study and a medium effect size favored strength training for the other. Significant difference found in one study in favor of control group. Conclusions: LE Strength – ST may be > Cont LE Power – ST may be > Cont, however caution as no sig. diff. and only med effect. Chair Rise – inconclusive Gait Velocity - inconclusive 37 PT vs. Control for analyzed outcome measures ¾ Of the three studies that had control groups, insignificant to large effect sizes favoring the PT group were found for LE strength. Significant difference found in one study only. ¾ Medium and large effect sizes for LE power and chair rise function favored the PT group respectively. Significant difference found for one study for chair rise function. ¾ The control group was favored for one study and PT group for one study, for measures of gait velocity. No significant differences found for either study. Conclusions: LE Strength – PT may be > Cont. LE Power – PT may be > Cont., however caution due to no significant diff and variable CI Chair Rise – PT may be > Cont. Gait Velocity – Inconclusive Comprehensive Conclusion: LE Strength – PT = ST, PT & ST may be > Cont. LE Power – PT may be > ST, PT & ST may be > Cont with Caution Chair Rise – PT may be > ST with Caution, PT may be > Cont., ST = Cont Gait Velocity – PT = ST, PT = Cont., ST = Cont. 38 DISCUSSION 40 Methodological Quality of Papers ¾ A major finding was that research conducted on the topic was generally lacking methodological quality ¾ Lack of blinding and intention to treat Due to the nature of the physiotherapy interventions in the included studies, it was only possible to blind the assessors; however, only two of the six studies did so (Be, Ca). Without blinding and intention to treat, there is an increased risk for observation bias which may influence recording and reporting of outcomes; therefore, caution is required when drawing conclusions from this data. 41 Sample Size ¾ All studies had small sample sizes, ranging from 20 to 61 participants ¾ No pre-hoc power analysis ¾ A post-hoc power analysis concluded that a sample size between 46 and 150 subjects per group would be necessary to identify differences in functional outcome measures In a post-hoc power analysis, Sayers et al concluded that a sample size between 46 and 150 subjects per group would be necessary to identify differences in functional outcome measures between power and strength training groups. Sample & Outcome Measure Characteristics ¾ The inclusion of community-dwelling older adults may account for the limited amount of change observed in the studies ¾ A ceiling effect may have limited the gains in functional performance Adverse Events ¾ Although there were no reports of serious injury associated with PT or ST, adverse events were poorly reported/defined in most of the trials ¾ This makes it difficult to come to a definite decision regarding the safety of PT and ST ¾ It is important to note that inactivity also has serious negative consequences for older people 44 Intervention Design: Familiarization ¾ Two studies utilized a familiarization period ¾ Initial gains in strength during resistance training have been attributed to neural adaptations resulting in increased muscle fiber recruitment, rather than actual increase in muscle size9 The lack of familiarization period in other studies may confound the results, with the score changes potentially being a product of motor learning versus a power or strength training effect.  In addition, a familiarization period may potentially increase safety and thereby decrease number of adverse events. (REF ??) Intervention Design: Training Specificity ¾ Most studies employed non-functional exercises ¾ 1 study included functional exercises of sit-to- stand and step up. There was significant improvement in chair-rise time ¾ Improvement in functional performance may be enhanced by using function-specific exercises Intervention Design: Characteristics ¾ It requires 3-4 months, 2-3 times a week of training to have a 2 to 3 times increase in strength from baseline9 z 4 of 6 studies met this criteria Intervention Design: Characteristics ¾ Various workloads were used between studies with no definitive conclusion on an ideal absolute total work z With a lower workload there may be increased exercise compliance and relatively lower perceived exertion13 CONCLUSION Conclusion ¾ The results are inconclusive as to the effectiveness of PT versus ST on LE function in community- dwelling older adults ¾ Three of the six studies found that PT was significantly more effective than ST for improving LE function in older adults ¾ Three of the six studies found no significant difference between PT and ST. Conclusion ¾ Although the results were inconclusive in this review, a trend was evident that power training may be as effective or better in improving functional measures in older adults when compared to strength training ¾ The inability of this review to find a conclusive answer is partially due to the moderate to low quality of the included  studies RECOMMENDATIONS Recommendations 1. Utilize rigorous research designs that minimize bias, have an adequate sample size and carefully monitor adverse events 2. Expanded sample population to at-risk participants, such as older adults with pre- existing functional limitations and disability 3. Perform follow-up assessment to determine the long-term effects of the interventions References 1. Canada’s population future [homepage on the Internet]. Canada: Statistics Canada. 2007 [updated 2007 Sept 7; cited 2008 July 16]. Available from: 2. Iannuzzi-Sucich M, Prestwood KM, Kenny AM. Prevalence of sarcopenia and predictors of skeletal muscle mass in healthy, older men and women. J Gerontol A Biol Sci Med Sci. 2002 December 1;57(12):M772-777. 3. Carmel MP. The impact of high-speed versus low-speed isokinetic training on functional performance measures in elderly women ages 61--75 [dissertation]. University of Miami; 2000. 4. Foldvari M, Clark M, Laviolette LC, Bernstein MA, Kaliton D, Castaneda C, et al. Association of muscle power with functional status in community- dwelling elderly women. J Gerontol A Biol Sci Med Sci. 2000 April 1;55(4):M192-199. 5. Guralnik JM, Ferrucci L, Simonsick EM, Salive ME, Wallace RB. Lower-extremity function in persons over the age of 70 years as a predictor of subsequent disability. N Engl J Med. 1995 March 2;332(9):556-62. 6. Douglas E. Angus, Eden Cloutier, Terry Albert, Denis Chénard, Anita Shariatmadar, Will Pickett, Lisa Hartling; The Hygeia Group. The economic burden of unintentional injury in Canada. Canadian Report. Ontario, Canada: SMARTRISK Foundation; 1998. 7. Liu-Ambrose T, Khan KM, Eng JJ, Janssen PA, Lord SR, McKay HA. Resistance and agility training reduce fall risk in women aged 75 to 85 with low bone mass: A 6-month randomized, controlled trial. J Am Geriatr Soc. 2004 05;52(5):657-65. 8. Latham NK, Bennett DA, Stretton CM, Anderson CS. Systematic review of progressive resistance strength training in older adults. J Gerontol. 2004;59A(1):48,49-61. 9. Mazzeo RS, Tanaka H. Exercise prescription for the elderly: Current recommendations. Sports Medicine. 2001 08;31(11; 11):809-18. 10. Sayers SP. High-speed power training: A novel approach to resistance training in older men and women. A brief review and pilot study. J Strength Cond Res. 2007 May;21(2):518-26. 11. Porter MM. Power training for older adults. Appl Physiol Nutr Metab. 2006 Apr;31(2):87-94. 12. 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 A Biol Sci Med Sci. 2003 02;58A(2):171-5. 13. Sayers SP. High velocity power training in older adults. Current Aging Science. 2008;1(1):62,63-67. 14. Keysor JJ, Jette AM. Have we oversold the benefit of late-life exercise? J Gerontol A Biol Sci Med Sci. 2001 July 1;56(7):M412-423. 15. Kraemer WJ, Adams K, Cafarelli E, Dudley GA, Dooly C, Feigenbaum MS, et al. American college of sports medicine position stand. progression models in resistance training for healthy adults. Med Sci Sports Exerc. 2002 Feb;34(2):364-80. References 16. Hedges LV, Olkin I. Statistical methods for meta-analysis. Orlando, USA: Academic Press; 1985. 17. Cohen J. Statistical power analysis for the behavioral sciences. 2nd ed. Hillsdale, NJ: Lawrence Erlbaum Associates; 1988. 18. Bean JF, Herman S, Kiely DK, Frey IC, Leveille SG, Fielding RA, et al. Increased velocity exercise specific to task (InVEST) training: A pilot study exploring effects on leg power, balance, and mobility in community-dwelling older women. J Am Geriatr Soc. 2004 05;52(5):799- 804. 19. Henwood TR, Taaffe DR. Short-term resistance training and the older adult: The effect of varied programmes for the enhancement of muscle strength and functional performance. Clin Physiol Funct Imaging. 2006 09;26(5; 5):305-13. 20. Bottaro M, Machado SN, Nogueira W, Scales R, Veloso J. Effect of high versus low-velocity resistance training on muscular fitness and functional performance in older men. Eur J Appl Physiol. 2007 Feb;99(3):257-64. 21. Sayers SP, Bean J, Cuoco A, LeBrasseur NK, Jette A, Fielding RA. Changes in function and disability after resistance training: Does velocity matter?: A pilot study. Am J Phys Med Rehabil. 2003 Aug;82(8):605-13. 22. Portney LG, Watkins MP. Foundations of clinical research: Applications to practice. 2nd ed. Upper Saddle River, NJ: Prentice-Hall, Inc.; 2000. 23. Earles DR, Judge JO, Gunnarsson OT. Velocity training induces power-specific adaptations in highly functioning older adults. Arch Phys Med Rehabil. 2001 7;82(7):872-8. THANK-YOU: Teresa Liu-Ambrose Angela Busch Elizabeth Dean Susan Harris Charlotte Beck Questions?


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