Global ETD Search

71	A Study of the Relationship of Self-Reported Resistance Training to Lipid Profiles. Davis, Melissa 16 August 2005 (has links) (PDF) The primary purpose of this study was to determine the relationship of self-reported resistance training to lipid profiles. The study consisted of 10 subjects between the ages of 19 and 35. Participants were assigned to an exercise group or control group based on self-reported resistance training and according to ACSM standards. After means were determined for the data gathered, the exercise group had lower averages of weight, percent body fat, total cholesterol, low-density lipoprotein and triglycerides, as well as, a higher average of high-density lipoproteins. Two sample t-tests were performed to determine significance. It was determined that no significant difference existed between serum lipid profile levels of the control group and the self-reported exercise group. This study is important because it expands our knowledge of the relationship between resistance training (RT) and lipid profiles, relying on self-reported data and focusing on an at-risk population. Resistance Training Lipid Profile Cholesterol Kinesiology Life Sciences
72	Comparison of Muscle Physiology and Performance Outcomes from Either Relative Intensity or Repetition Maximum Training Carroll, Kevin 01 August 2018 (has links) (PDF) The main purpose of this dissertation was to compare performance and physiological outcomes of between a repetition maximum (RM) and a relative intensity using sets-and-repetitions (RISR) resistance training (RT) program in well-trained lifters. Fifteen subjects underwent RT 3 d·wk-1 for 10-weeks in either a RM group (n=8) or RISR group (n=7). The RM group achieved a relative maximum each day while the RISR group trained based on percentages. Testing included percutaneous needle biopsies of the vastus lateralis, ultrasonography, unweighted (g to assess within and between-group alterations. RISR from pre-to-post yielded statistically significant increases in Type I CSA (p=0.018), Type II CSA (p=0.012), ACSA (p=0.002), unweighted (p=0.009) and 20 kg SJ JH (p=0.012), unweighted (p=0.003) and 20kg SJ PPa (p=0.026), IPF (ppSR increased in unweighted (p=0.023) and 20kg SJ JH (p=0.014), and 20kg SJ PPa (p=0.026) from pre-to-post taper. RM yielded statistically significant increases from only pre-to-post taper for 20kg SJ JH (p=0.003) and CMJ JH (p=0.031). Additionally, RM had a statistically significant pre-to-post decrease in RFD from 0-50ms (p=0.018) and 0-100ms (p=0.014). Between-group effect sizes supported RISR for Type I CSA (g=0.48), Type II CSA (g=0.50), ACSA (g=1.03), all MYH isoforms (g=0.31-0.87), all SJ variables (g=0.64-1.07), unweighted and 20kg CMJ JH (g=0.76-0.97), unweighted CMJ PPa (g=0.35), IPFa (g=0.20), and all RFD (g=0.31-1.25) time-points except 0-200ms; with all other effects being of trivial magnitude (gSR training yielded greater improvements in vertical jump, RFD and maximal strength compared RM training. These performances results may, in part, be explained mechanistically by the superior physiological adaptations observed in the RISR group within the skeletal muscle. Taken together, these data support the use of RISR training in well-trained populations. resistance training skeletal muscle hypertrophy exercise science Sports Sciences
73	The Validity of Estimating Morphological Changes in Skeletal Muscle Using MRI in Resistance Trained Men Beeler, Matthew K. January 2020 (has links) No description available. Kinesiology Resistance Training Exercise MRI Muscle Hypertrophy Muscle Volume
74	The Cross Education of Neuromuscular Economy Beyer, Kyle 01 January 2014 (has links) Cross education is the phenomenon by which the untrained limb will experience a gain in strength following a unilateral resistance training program. However, little is known as to the underlying adaptation occurring in the untrained limb. Purpose: To examine the effect of dynamic unilateral resistance training on the strength and neuromuscular adaptations of both the trained and untrained legs. Methods: Eight previously untrained males (22.38±2.92 y, 1.73±0.08 m, 75.26±14.53 kg) completed a four-week unilateral resistance training program, while another eight untrained males (24.00±4.57 y, 1.84±0.05 m, 94.21±16.14 kg) served as controls. Isometric leg extension strength, leg press 1 repetition maximum (1RM), leg extension 1RM, root mean square of the maximal electromyographic amplitude (EMG), submaximal EMG, dynamic neuromuscular economy (NME) and the slope of NME-power output relationship were determined before and after training to assess the changes in strength and neuromuscular adaptations of the vastus lateralis (VL) and rectus femoris (RF) in both the trained and untrained legs. The unilateral resistance training program was conducted on the dominant leg (DOM) in the unilateral resistance training group (URT) and was compared to the dominant leg of the control group (CON). Cross education was measured in the nondominant leg (NON) for both groups. The unilateral resistance training program was completed three days per week for a total of twelve training sessions. Exercises included in the training program were unilateral leg press, unilateral leg extension, bilateral chest press and bilateral low row. All data was analyzed using one-way analysis of covariance of the post-testing values using the pre-testing values as the covariate. Further analysis of the EMG and NME data was performed using magnitude-based inferences. Results: The URT group improved their isometric (DOM:11.03%, NON:4.98%), leg press (DOM:77.63%, NON:64.88%) and leg extension (DOM:46.76%, NON:16.43%) strength after the four weeks of resistance training. There was no difference between the groups in isometric strength in the dominant (p=0.188) or nondominant (p=0.948) leg. For leg extension 1RM, there was a significant difference between groups in the dominant leg (p=0.018), but not the nondominant leg (p=0.482). However, there were significant group differences in both the dominant (p=0.003) and nondominant (p=0.034) leg for leg press 1RM. In terms of maximal EMG, the training groups improved in the vastus lateralis (DOM:29.81%, NON:31.44%) and rectus femoris (DOM:20.71%, NON:6.26%) individually, as well as in total EMG (DOM:24.78%, NON:17.57%). There was a Likely Positive or Very Likely Positive effect of unilateral resistance training on the changes in maximal EMG of the vastus lateralis and rectus femoris in both the dominant and nondominant legs. There was a Likely Positive effect of unilateral resistance training on the submaximal EMG of the dominant vastus lateralis at 75 and 125 watts. Conversely, in the rectus femoris, there was Unclear effects of unilateral resistance training on the submaximal EMG of the dominant leg. There was no consistent effect of unilateral resistance training on submaximal EMG values of the vastus lateralis in the nondominant leg. However, the rectus femoris in the nondominant leg experienced a Likely Positive effect of unilateral resistance training on submaximal EMG. NME improved in the URT group in the VL at 75 (DOM:9.73%, NON:13.42%), 100 (DOM:8.76%, NON:8.21%), and 125(DOM:24.26%, NON:12.8%) watts and in the RF at 75 (DOM:22.25%, NON:15.73%), 100(DOM:24.85%, NON:17.05%) and 125 (DOM:30.99%) watts. In terms of neuromuscular economy, there was a Likely Positive or Very Likely Positive effect of unilateral resistance training on most measures of NME on both the vastus lateralis and rectus femoris in both the dominant and nondominant legs. In terms of NME slope, there was only a Likely Positive effect of unilateral resistance training on the dominant vastus lateralis. Conclusion: Based on these results, it appears that the cross education of strength from unilateral resistance training is modality-specific. Furthermore, the NME of both the vastus lateralis and rectus femoris in both legs appear to improve following unilateral resistance training. However, in the nondominant leg, the improvement in NME appears to be due solely to the increase in maximal EMG, whereas the improved NME in the dominant leg is due to both an increase in maximal EMG and a decrease in submaximal EMG. Electromyography cross education neuromuscular unilateral resistance training Physiology Sports Sciences
75	The Effect of Training Status on Adaptations to 11 Weeks of Block Periodization Training Wetmore, Alexander B., Moquin, Paul A., Carroll, Kevin M., Fry, Andrew C., Hornsby, W. G., Stone, Michael H. 31 October 2020 (has links) Some controversy exists as to the most efficacious method of training to achieve enhanced levels of sport performance. Controversy concerning the efficacy of periodization and especially block periodization (BP) likely stems from the use of poorly or untrained subjects versus trained who may differ in their responses to a stimulus. The purpose of this study was to investigate the effect of training status on performance outcomes resulting from 11 weeks of BP training. Fifteen males were recruited for this study and placed into strong (age = 24.3 ± 1.9 years., body mass (BM) = 87.7 ± 8.7 kg, squat: body mass = 1.96 ± 0.16), moderate (age = 25.3 ± 2.7 years., body mass = 100.2 ± 15.5 kg, squat: body mass = 1.46 ± 0.14), or weak (age = 23.2 ± 3.9 yrs., body mass = 83.5 ± 17.1 kg, squat: body mass = 1.17 ± 0.07) groups based on relative strength. Testing was completed at baseline, and after each block which consisted of 1 repetition maximum (1RM) squat, 0 kg static jump (SJ), 0 kg countermovement jump (CMJ), 20 kg SJ, and 20 kg CMJ. Absolute and relative strength were strongly correlated with rates of improvement for absolute strength, relative strength, 0 kg, and 20 kg vertical jumps. All subjects substantially improved back squat ( < 0.001), relative back squat ( < 0.001) with large-very large effect sizes between groups for percent change favoring the weak group over the moderate and strong group for all performance variables. All subjects showed statistically significant improvements in 0 kg SJ ( < 0.001), 0 kg CMJ ( < 0.001), 20 kg SJ ( = 0.002), and 20 kg CMJ ( < 0.001). Statistically significant between group differences were noted for both 20 kg SJ ( = 0.01) and 20 kg CMJ ( = 0.043) with the strong group statistically greater jump heights than the weak group. The results of this study indicate BP training is effective in improving strength and explosive ability. Additionally, training status may substantially alter the response to a resistance training program. relative strength resistance training strength
76	Reliability of the Brzycki Formula to Estimate 1RM Bench Press and Half-Squat Between Collegiate Men and Women Gonzalez-Rave, Jose M., Santos-Garcia, Daniel Juarez, Stone, Michael H. 01 December 2021 (has links) BACKGROUND: The determination of the 1-repetition maximum (1RM) is one of the most frequently performed evaluations to assess maximal dynamic strength in athletes. Several formulas have been proposed to estimate the 1RM. The objective of this study was to compare 1RM measurement with a 1RM estimate obtained from the Brzycki formula to estimate 1RM bench press and half-squat between young men and women. METHODS: Forty-six male and 15 female sport sciences undergraduates performed 3RM in bench press and 3RM in half-squat. in two sessions. In different days, participants performed the 1RM test of each exercise. A two-way (gender x exercise) ANOVA was applied to analyze the difference between the estimate and the actual 1RM. The level of significance set for the study was P<0.05. RESULTS: Differences (P<0.001) between the estimate and the 1RM was found both in half-squat (9.3±11.1 kg) and bench press (4.6±6.2 kg) for both the whole group. No significant differences were found in the interaction gender x exercise, not in absolute terms (P=0.23; partial η2=0.01) or in percentage (P=0.34; partial η2=0.007). CONCLUSIONS: Estimating 1RM by Brzycki formula according to how it has been conducted in this study is not different in young men and women in relation to the exercise performed: half-squat and bench press. However, the estimate was different from the actual 1RM for both exercises. exercise muscle strength resistance training sex
77	Effects of a dietary milk or carbohydrate supplement with resistance training on body composition, muscle strength and anabolic hormones in untrained men Goldman, Lauren Paige 08 January 2002 (has links) Twenty untrained men (18-25 y) were assigned to consume either a milk supplement (MILK) or a carbohydrate-electrolyte supplement (CHO) immediately following each resistance workout during a 10 wk resistance training program. Subjects trained 3 d/wk beginning with an intensity of 55% 1-RM and progressing to 97% 1-RM by wk 10. Muscle strength (1-RM), body composition (DEXA) and resting, fasted serum concentrations of total and free testosterone and IGF-1 were measured pre- and post-training. CHO tended to reduce, while MILK increased body weight (P = 0.10). All subjects significantly reduced percent body fat (1.1%) and significantly increased lean body mass (1.21 kg) as a result of the resistance training with no significant differences between treatments. However, MILK tended to increase lean body mass (P = 0.1) more than CHO (1.6 and 0.8 kg, respectively). About 39% of lean mass gain for all subjects was in the leg region, while the arms accounted for about 28% of lean gain. Resistance training also caused a similar significant 44% increase in muscle strength for the seven exercises combined for both groups. Resting total and free testosterone concentrations significantly decreased from baseline values in both groups of subjects (16.7% and 11%, respectively), while resting insulin concentrations significantly increased in all subjects (P<0.01). There were no significant changes in resting, fasted IGF-1 concentrations. In summary, dietary supplementation with a MILK or CHO beverage immediately following resistance exercise resulted in similar changes in muscle strength and hormone concentrations following a 10 wk periodized resistance training program. MILK tended to increase body weight and lean body mass more so than CHO. / Master of Science IGF-1 insulin testosterone periodized resistance training carbohydrate
78	Effects of Supersets Versus Traditional Strength Training Methods on Muscle Adaptations, Recovery, and Selected Anthropometric Measures White, Jason B. 26 July 2011 (has links) No description available. Health Sciences Physiology supersets muscle strength muscle hypertrophy resistance training
79	THE EFFECTS OF TAGteach™ ON THE EXECUTION OF RESISTANCE TRAINING MOVEMENTS Doyle, Alexa January 2020 (has links) Exercise programs that utilize resistance training, a specialized type of conditioning that provides stress (resistive loads) to the muscles, have appealed to athletes and recreational participants alike, due to its documented benefits for performance and overall health. Teaching the correct form for these skills is imperative for a safe and proficient execution of these movements. TAGteach™, a form of behavioral coaching, is a procedure that utilizes immediate acoustical feedback in the form of a clicker as a reinforcer for the desired behavior. TAGteach has been successfully used to teach novel or enhance existing athletic skills in many domains such as football, dance, yoga, pitching, golf and even surgical techniques (TAGteach International, 2012). The present study employed a multiple probe across behaviors design to evaluate the effectiveness of the TAGteach method to train three resistance training movements (deadlift, overhead press, and front squat) for adult novice participants. Results demonstrated an improvement in performance of each skill from baseline probes following training. Improved performance also generalized to heavier weight than those utilized during training. This generalization is a key to achieving progressive overload as a part of the typical practice in resistance training programs. / Applied Behavioral Analysis Behavioral Sciences Psychology, Behavioral Athletics Behavioral Coaching Resistance Training Tagteach
80	The Effect of Velocity on Muscle Morphology Following Eccentric High-Resistance Training in Young Males Shepstone, Timothy N. 05 1900 (has links) <p> It is known that high-resistance training induces morphological changes in skeletal muscle. Following a resistance training program, increases in maximum torque generating capacity are observed due to both neural adaptations and hypertrophic gains within the trained muscle. Although it has been established that a muscle hypertrophies due to the addition of myofibrillar proteins through increased protein synthesis, the exact mechanism which stimulates the hypertrophic response is unknown.</p> <p> Previous reports have shown that training in the absence of eccentric contractions generally produces less muscle growth and strength gains, as well as inflicting less damage to the muscle ultrastructure. Likewise, fast eccentric contractions have been shown to increase muscular strength to a greater extent than slow contractions. It has been hypothesized that fast eccentric contractions may maximize muscular damage, thus invoking a greater response of repair mechanisms, including satellite cell recruitment, which would allow an increased addition of contractile proteins to be added to the injured muscle, increasing muscle size and strength to a greater degree.</p> <p> The effect of fast and slow eccentric training was investigated using a bilateral, within subject model. Twelve men trained one arm fast (3.66 rad/s) and one arm slow (0.52 rad/s) for 8 weeks on an isokinetic training apparatus. Type I muscle fibre size increased with training by an average of 9.3±12.0% (P<0.05, main effect for time). Type II muscle fibres increased more in the subjects' fast trained arm when compared to the slow trained arm according to ATPase histochemical analysis (P<0.05, time x condition interaction). Likewise, whole arm cross-sectional area showed that the fast trained arms had an average increase of 6.8±5.5 % whereas the slow arms only had an average increase CSA of 5.1±5.7% (P=0.065, time x condition interaction). Maximum torque generating capacity was also increased to a greater degree (P<0.05, time x condition interaction) in the fast trained arm with an average of 10.3±16.4 Nm, whereas the slow trained arm increased only 7.3±15.0 Nm, across testing speeds. A decrease in the percentage of type IIx fibres was seen in both arms after training according to both ATPase histochemical staining and MHC gel electrophoresis; however, the percentage of type IIa fibre area increased in the fast trained arms (8.4±8.6%) more significantly (P<0.05, time x condition interaction) than the slow trained arms (1.7±10.9%).</p> <p> Seven males were trained in a similar manner to determine the extent of muscle damage which was evaluated by both Z-band streaming and force production decrements. After a single exercise bout of fast eccentric training in one arm and slow eccentric training in the other, it was determined that a 1.97±0.74 areas of moderate Z-band streaming per mm^2 of muscle in the fast exercised arm compared to 0.89±0.79 areas of moderate Z-band streaming per mm^2 of muscle in the slow trained arm (P<0.05). In conclusion, training using fast (3.66 rad/s) eccentric contractions causes a greater degree of muscle damage, hypertrophy, and strength gains than does training with slow (0.52 rad/s) eccentric contractions.</p> / Thesis / Master of Science (MSc)

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