Adequate flexibility allows full joint range of motion potentially improving sports performance and daily function (2,9). Adequate flexibility subjects have less injury risk than poor flexibility subjects, and excellent flexibility subjects may have dramatically less injury risk than poor flexibility subjects (14). Adequate flexibility increases quality of life (1,2) and stretching is recommended for most populations.
Although stretching is the most popular recommendation for improving flexibility, some populations may not adhere to a stretching program (4). Resistance training increases ligament and tendon strength and may improve contractility and joint integrity. One of these traits or a combination thereof may increase joint range of motion, thereby improving flexibility (17). Although there is much that remains unknown about resistance training and flexibility, several recent studies examine resistance training's flexibility impact.
Whether resistance training flexibility gains are produced by increased connective tissue strength, increased muscle strength, greater motor learning, or neuromuscular coordination (11) is not yet clear. It appears settled that resistance training does not limit flexibility gains absent extreme strength gains (12).
Resistance training can unquestionably improve strength, power, and muscle hypertrophy across various populations. If resistance training can increase flexibility without stretching in some populations, greater training time can be devoted to resistance training and greater resistance training benefits may result (5,10).
Resistance training flexibility studies produce varied results. Although methodological limitations limit broad inferences in some cases, resistance training's flexibility impact may be partially population, protocol, and articulation specific.
To our knowledge, no previous study has examined resistance training's flexibility impact in an exclusively young sedentary women population. The study's purpose was to consider 2 moderately intense strength training protocols' impact on flexibility in sedentary young women.
Experimental Approach to the Problem
This study considered whether 8 weeks of moderately intense resistance training increases flexibility in sedentary young women. Before beginning the 8-week program, subjects were randomly assigned to 1 of 3 groups: alternated strength training (AST) group (upper and lower body), alternated agonist/antagonist (AA) group, or control group (CG). Due to the subjects' sedentary history, both training groups performed 1 week of exercise familiarization before 1 repetition maximum (1RM) testing.
Initial flexibility was assessed 48 to 72 hours after the initial 1RM testing procedure. At the end of the 8-week training period, flexibility was reassessed 48 hours after the final training session. The second 1RM test was conducted 48 hours after the second flexibility assessment. Training included 3 weekly sessions, performed every other day, for 24 total sessions. All subjects completed all sessions. Training ran for an 8-week period.
Twenty-four, young, sedentary women were divided into 3 groups as follows: AA (n = 8; age 26.8 ± 1.6 years; body mass 55.1 ± 3.3 kg; height 161 ± 2.7 cm; body mass index [BMI] 21.3 ± 1.2 kg/m2); AST (n = 8; age 24 ± 2.3 years; body mass 60.3 ± 4.5 kg; height 164.3 ± 6 cm; BMI 22.3 ± 1.1 kg/m2); CG (n = 8; age 25.4 ± 2.4 years; body mass 54.1 ± 3.5 kg; height 160 ± 4.1 cm; BMI 21.1 ± 1.3 kg/m2). For 6 months preceding the study, subjects engaged in no physical activity. During the study period, subjects engaged in no regular physical activity other than the study's strength training program. Subjects were not allowed to present any condition that could influence data collection or interpretation. All volunteers were verbally briefed on the risk associated with the study and signed a written agreement acknowledging the risk in compliance with the Castelo Branco University ethical committee. The University ethics committee approved this study.
Flexibility was assessed on 6 articular movements: shoulder flexion and extension, horizontal shoulder adduction and abduction, and trunk flexion and extension. Except for trunk movements, all assessments were collected on the right side. Trunk flexion, trunk extension, and shoulder adduction were performed in the orthostatic position. The shoulder abduction movement was performed while the subject was seated. Shoulder flexion and extension were assessed on a trolley to limit compensatory movement.
To assess flexibility, the evaluator adjusted the subject's body to the point of pain or anatomical limitation. The measurements were taken using a Lafayette Goniometer (Sammons Preston Rolyan 7514), following the procedures described by Norkin and White (13). Initial collected data were not available to the evaluator during subsequent assessment. Excellent day-to-day flexibility reliability was shown before and after strength training for each exercise in each group.
Repetition Maximum Testing
One repetition maximum machine bench press (BP) tests were performed on 2 non-consecutive days (Life Fitness, Inc., Franklin Park, IL). The 1RM testing protocol has been previously described (16). The heaviest load achieved was recorded as 1RM. The first 1RM test was repeated 48 to 72 hours after initial assessment to determine test-retest reliability.
Several strategies minimized error risk during 1RM testing. Standardized instructions concerning testing procedure and exercise technique were provided before the test. Verbal encouragement was provided during the 1RM testing process. The 1RM was determined in fewer than 5 attempts. Five-minute rest interval was allowed between 1RM attempts to allow full recovery.
Training included 3 weekly sessions, performed every other day, for 24 total sessions. All subjects participated in and completed all organized sessions. Before each training session, subjects performed a specific warm-up. Warm-up included 20 repetitions with 50% of the weight used in the first training exercise.
Both training groups performed 3 sets with 10 to 12 repetitions per set in all exercises except the abdominal exercise. In the abdominal exercise, subjects performed 3 sets of 15 to 20 repetitions. When subjects could exceed 12 repetitions, the amount of weight was increased to keep the repetition capacity at 10 to 12 repetitions per set. During the exercise sessions, participants received verbal encouragement to exercise to concentric failure. One repetition maximum range of motion standards were used to assess a successful repetition.
The exercise order for AST group was machine seated row (MSR), leg extension (LE), machine BP, seated leg curl (LC), machine seated arm curl (BC), abdominals (ABS), machine triceps extension (TE), and trunk extension machine (TEM). In the AST program, subjects performed 2 consecutive paired exercises followed by 2 minutes of rest. Subjects then moved to the next 2 paired exercises followed by 2 minutes of rest and continued until all exercises were completed.
The AA group exercise order was MSR-BP, TE-BC, ABS-TEM, LE-LC. Exercises were paired in AA groups (e.g., MSR-BP) and executed sequentially. On completing 3 sets of one exercise pairing, subjects rested 2 minutes before proceeding to the next exercise pairing. The CG performed no strength training intervention.
Total work was determined by multiplying the number of sessions, the number of sets, and repetitions and resistance load (session × sets × load). Intraclass correlation coefficients (ICCs) were used to determine 1RM and flexibility measurement test-retest reliability. The ICC method was based on a repeated measurement of maximal strength and flexibility. The statistical analysis was initially done by the Shapiro-Wilk normality test and by the homoscedasticity test (Bartlett's criterion). All variables presented normal distribution and homoscedasticity. A 2 (pre-post) by 3 (groups) way analysis of variance (time [baseline vs. 8-week training] × group [AST vs. AA vs. control]) was used to analyze group 1RM and flexibility differences. Strength and flexibility effect size were calculated using Rhea's proposed scale (15). When appropriate, follow-up analyses were performed using Tukey's post hoc tests. Student's t-tests were used to analyze differences between pre- and post-training 1RM tests and for total work. The same procedure was applied to flexibility measurements (test and retest) pre and post training. An alpha level of p ≤ 0.05 was considered statistically significant for all comparisons. Statistica version 7.0 (Statsoft, Inc., Tulsa, OK) software was used for all statistical analyses.
Both training groups showed moderate or large flexibility gains at all measured articulations, whereas the CG showed trivial gains or lost flexibility at all articulations. Moderate intensity strength training can increase flexibility in young sedentary women in a short time.
All pre- and post-test flexibility measures showed excellent day-to-day test reliability, with ICCs ranging between 0.90 and 0.98. Additionally, a paired Student's t-test indicated no significant differences between training group flexibility assessments. There were no differences (p > 0.05) in baseline flexibility measurements between groups on 6 articular movements (Tables 1 and 2). In both trained groups, flexibility increased significantly for 6 articular movements (Tables 1 and 2). Effect size data (Tables 1 and 2) demonstrated differences between the training groups in all measurements except shoulder abduction.
Total Volume and Total Work
There was no difference between training groups in total volume (repetitions × sets). However, the AST group performed a higher amount of work than the AA group although the difference was not significant (349933.5 ± 102052.4 kg).
One Repetition Maximum Tests
The 1RM test-retest reliability showed high ICC at baseline (BP, r = 0.90) and after 8 weeks of training (BP, r = 0.92). The T-tests showed no significant differences between 1RM tests. There were no differences (p > 0.05) between groups in 1RM tests at baseline. After 8 weeks, both trained groups showed a significant 1RM BP improvement when compared with CG (Table 3). There was no significant 1RM BP gain difference between the trained groups. However, effect size data (Table 3) showed differences between trained groups.
The present study considered two 8-week, moderately intense, resistance training programs' impact on sedentary young women's flexibility. Both training groups increased flexibility significantly from baseline and when compared with CG. The AST group increased both strength and flexibility more than the AA group.
Several recent studies considering resistance training's flexibility impact have produced mixed results. Some populations can apparently improve flexibility through resistance training, whereas some may not be able to do so.
Age and gender apparently impact strength training's flexibility. Low (60%) strength training intensity may increase older adult flexibility although higher intensity training may produce greater flexibility gains (5). Younger subjects may need greater intensity to produce the same relative benefit (6).
Strength training improves elderly women flexibility for some joint movements (3,6,7). Flexibility exercises alone were more effective than strength training combined with flexibility exercises for improving hip flexion, shoulder flexion, and shoulder abduction in elderly men (8). However, some limitations should be considered. Shoulder abduction was the only articulation where the flexibility-only group showed significantly better gains than the strength plus flexibility group. Furthermore, shoulder abduction was not resistance trained. Some resistance training protocols may not sufficiently train the respective articulations that are being assessed for flexibility. This issue has been previously noted as a potential program design limitation when attempting flexibility increase through resistance training (5).
Middle-aged women (±37 years) increased flexibility at some joints after performing circuit strength training (10). The 8 to 12 RM circuit training routine increased flexibility at some but not all joints.
Strength training did not improve young adult flexibility (12). However, gender differences were not considered. Furthermore, 28 men and 15 women (65% men and 35% women) participated. The resistance training group was even more gender skewed: 69% men and 31% women. The authors listed gender specificity as a potential study limitation. The authors also noted that the results may be protocol specific, and another resistance protocol may produce a different flexibility outcome. Other commentators have noted the impact of varying resistance protocols on flexibility (10).
A brief review of recent resistance training for flexibility gains indicated multiple set training between 6 and 12 repetitions, which can increase flexibility in sedentary middle-aged and older men and women in a short period (10). Our findings applied a similar resistance protocol to young sedentary women and also increased flexibility.
Considering the total literature support for resistance training's capacity to increase flexibility, particularly in women, and in light of the Nóbrega et al. (12) limitations, the present study's flexibility gains provide more support for resistance training as an effective method to increase flexibility in many populations.
Our study supports the hypothesis that moderate intensity strength training increases strength and flexibility during initial training stages in young sedentary women. Specificity of population (age and gender), gender, and training protocol may limit conclusions about the present findings to the present population and protocol.
Given exercise's time cost and the universal desire to achieve maximal physical results in minimal time, enhanced exercise efficiency serves fitness professionals, athletes, and the general population. This may be particularly true with a sedentary population. Exercise professionals working with young sedentary women may use limited training time for strength training exercises knowing that moderate intensity strength training improves both strength and flexibility. As the first study to show increased flexibility through resistance training with an exclusively young sedentary women population, this study contributes to the evidence that appropriate intensity resistance training increases flexibility in some populations and at some articulations. Two resistance protocols that increase strength and flexibility in young women are also provided. Therefore, this study provides important programming information for the exercise professional.
1. American College of Sports Medicine. ACSM Position Stand: The recommended quantity and quality of exercise for developing and maintaining cardiorespiratory and muscular fitness, and flexibility in healthy adults. Med Sci Sports Exerc
30: 975-991, 1998.
2. Araújo, CGS. Flexitest: An Innovative Flexibility Assessment Method
. Champaign, IL: Human Kinetics, 2004.
3. Barbosa, AR, Santarém, JM, Filho, WJ, and Marucci, MF. Effects of resistance training on the sit-and-reach test in elderly women. J Strength Cond Res
16: 14-18, 2002.
4. Dobkin, PL, Da Costa, D, Abrahamowicz, M, Dritsa, M, Du Berger, R, Fitzcharles, MA, and Lowensteyn, I. Adherence during an individualized home based 12-week exercise program in women with fibromyalgia. J Rheumatol
33: 333-341, 2006.
5. Fatouros, IG, Kambas, A, Katrabasas, I, Leontsini, D, Chatzinikolaou, A, Jamurtas, AZ, Douroudos, I, Aggelousis, N, and Taxildaris, K. Resistance training and detraining effects on flexibility performance in the elderly are intensity-dependent. J Strength Cond Res
20: 634-642, 2006.
6. Fatouros, IG, Kambas, A, Katrabasas, I, Nikolaidis, K, Chatzinikolaou, A, Leontsini, D, and Taxildaris, K. Strength training and detraining effects on muscular strength, anaerobic power, and mobility of inactive older men are intensity dependent. Br J Sports Med
39: 776-780, 2005.
7. Fatouros, IG, Taxildaris, K, Tokmakidis, SP, Kalapotharakos, V, Aggelousis, N, Athanasopoulos, S, Zeeris, I, and Katrabasas, I. The effects of strength training, cardiovascular training and their combination on flexibility of inactive older adults. Int J Sports Med
23: 112-119, 2002.
8. Girouard, CK and Hurley, BF. Does strength training inhibits gains in range of motion from flexibility training in older adults? Med Sci Sports Exerc
27: 1444-1449, 1995.
9. Holcomb, WR. Stretching and warm-up. In: Essentials of Strength Training and Conditioning
(2nd ed.). Baechle, T and Earle, R, eds. Champaign, IL: Human Kinetics, 2000. pp. 322-325.
10. Monteiro, WD, Simão, R, Polito, MD, Santana, CA, Chaves, RB, Bezerra, E, and Fleck, SJ. Influence of strength training on adults women's flexibility. J Strength Cond Res
22: 672-677, 2008.
11. Mookerjee, S and Ratamass, N. Comparison of strength differences and joint action durations between full and partial range-of-motion bench press exercise. J Strength Cond Res
13: 76-81, 1999.
12. Nóbrega, ACL, Paula, KC, and Carvalho, ACG. Interaction between resistance training and flexibility training in healthy young adults. J Strength Cond Res
19: 842-846, 2005.
13. Norkin, CC and White, DJ. Measurement of Joint Motion: A Guide to Goniometry
. Philadelphia, PA: F.A. Davis Company, 1985.
14. Pope, RP, Herbert, RD, and Kirwan, JD. Effects of ankle dorsiflexion range and pre-exercise calf muscle stretching on injury risk in army recruits. Aust J Physiother
44: 165-177, 1998.
15. Rhea, MR. Determining the magnitude of treatment effects in strength training research through the use of the effect size. J Strength Cond Res
18: 918-920, 2004.
16. Simão, R, Farinatti, PTV, Polito, MD, Viveiros, L, and Fleck, SJ. Influence of exercise order on the number of repetitions performed and perceived exertion during resistance exercise in women. J Strength Cond Res
21: 23-28, 2007.
17. Spirduso, WW. Physical Dimension of Aging
. Champaign, IL: Human Kinetics, 1995.