THE EFFECTS OF STATIC AND DYNAMIC STRETCHING ON SPRINT SPEED OF THE PHYSICALLY ACTIVE A THESIS Submitted to the Faculty of the School of Graduate Studies and Research of California University of Pennsylvania in partial fulfillment of the requirements for the degree of Master of Science by Mark C. Webber Research Advisor, Dr. Thomas F. West California, Pennsylvania 2012 ii iii ACKNOWLEDGEMENTS First and foremost, I would like to thank my parents, Michael and Elaine, for their love and support in everything I do. They have always been there for me whether it was assisting me succeed academically or attending every single athletic event of my life. I love you and am very proud to be your son. I would also like to thank my family and friends for providing me with the strength and courage to accomplish any task, no matter the difficulty. Abby, thank you for your love and support throughout this year in Pennsylvania. I would also like to thank my committee members, Dr. Thomas West, Dr. Laura Miller, and Mr. Adam Annaccone, for their time, advice, and commitment to making this thesis a success. Dr. West, thank you for all you have done, from start to finish. Your willingness to take time to answer questions and add suggestions is greatly appreciated. I would also like to acknowledge all the staff athletic trainers and undergraduate athletic training students for their enthusiasm each and every day. Adam, thank you for lending support and advice while dealing with iv injuries and coaches. You have enhanced my development as an athletic trainer greatly. Finally, I would like to thank all my classmates at CalU. I have had a lot of fun with all of you. I wish the best for you in your future endeavors. Good Luck! I would also like to acknowledge Curt Snyder’s Mustache, which brightened my day, reminded me to laugh, and allowed me to be a free spirit and an overall better person each and every day I set foot in the athletic training room. v TABLE OF CONTENTS Page SIGNATURE PAGE . . . . . . . . . . . . . . . ii AKNOWLEDGEMENTS . . . . . . . . . . . . . . . iii TABLE OF CONTENTS LIST OF TABLES INTRODUCTION METHODS . . . . . . . . . . . . . . v . . . . . . . . . . . . . . . viii . . . . . . . . . . . . . . . . 1 . . . . . . . . . . . . . . . . . . 8 Research Design Subjects . . . . . . . . . . . . . . 8 . . . . . . . . . . . . . . . . . 9 Preliminary Research. . . . . . . . . . . . . 10 Instruments . . . . . . . . . . . . . . . . 11 Procedures . . . . . . . . . . . . . . . . 12 Hypothesis . . . . . . . . . . . . . . . . 16 Data Analysis RESULTS . . . . . . . . . . . . . . . 16 . . . . . . . . . . . . . . . . . . 17 Demographic Information Hypothesis Testing . . . . . . . . . . . 17 . . . . . . . . . . . . . 18 DISCUSSION . . . . . . . . . . . . . . . . . 21 Discussion of Results . . . . . . . . . . . . 21 Conclusions . . . . . . . . . . . . . . . . 25 Recommendations . . . . . . . . . . . . . . 27 REFERENCES . . . . . . . . . . . . . . . . . 29 APPENDICES . . . . . . . . . . . . . . . . . 31 vi APPENDIX A: Review of Literature . . . . . . . . 32 Introduction to Stretching and Flexibility . . . . 34 Mechanisms of Stretching . . . . . . . . . . 34 Injury Prevention/DOMS . . . . . . . . . . . 36 Stretching . . . . . . . . . . . . . . . . 39 Static Stretching . . . . . . . . . . . . 39 Dynamic Stretching . . . . . . . . . . . 41 Ballistic Stretching . . . . . . . . . . 42 Proprioceptive Neuromuscular Facilitation . 43 Speed . . . . . . . . . . . . . . . . . . 44 What is Sp eed and How is it Measured? . . . 44 Training Techniques Used to Impr ove Speed . 45 Stretching and Speed . . . . . . . . . . . 46 Summary . . . . . . . . . . . . . . . . . . 56 APPENDIX B: The Problem . . . . . . . . . . . . 58 Statement of the Problem . . . . . . . . . . . 59 Definition of Terms . . . . . . . . . . . . . 60 Basic Assumptions . . . . . . . . . . . . . . 60 Limitations of the Study . . . . . . . . . . . 61 Delimitations of the Study . . . . . . . . . . 61 Significance of the Study . . . . . . . . . . 62 APPENDIX C: Additional Methods . . . . . . . . . 64 Informed Consent Form (C1) . . . . . . . . . . 65 Physical Activity Readiness Questionnaire (C2) 69 vii Physical Examination Release Waiver (C3) Physical Activ ity Survey (C4) . . 71 . . . . . . . 73 Functional Instruments (C5) . . . . . . . . . . 75 Stretching Protocols (C6) . . . . . . . . . . 78 IRB: Institutional Review Board (C7) . . . . . . 84 Data Collection Sheet (C8) . . . . . . . . . . 99 REFERENCES . . . . . . . . . . . . . . . . . 101 ABSTRACT . . . . . . . . . . . . . . . . . . 104 viii LIST OF TABLES Table Title Page 1 40 Yard Sprint Descriptive Statistics . . . . 20 2 Differences in Time Between Protocols . . . . 20 1 INTRODUCTION Stretching has been widely accepted within the athletic population for decades. Static stretching was once dominant for a pre-activity warm-up. However, recent studies have shown that static stretching may lead to an increased risk of injury and also a decrease in performance. There has also been an increasing number of studies1-7 identifying the positive effects of dynamic stretching when compared to static stretching. Therefore, there has been a significant shift towards dynamic stretching as part of a pre-activity warm-up. The purpose of this study is to investigate the effect of three different stretching protocols on the sprint performance of physically active individuals. These three stretching protocols include static stretching, dynamic stretching, and a combination of static and dynamic stretching. Furthermore, this study is intended to provide statistical evidence in order to determine which stretching protocol would be most beneficial for physically active individuals. 2 Every athlete wants to perform at the highest level possible. Stretching as part of a warm-up may increase performance; however, the type of stretching performed is essential to perform at an optimal level. Static stretching before competition has been the traditional method to utilize in order to prepare the muscular system for work. Speed may be one of the most important aspects of performance. Studies have shown that dynamic stretching is appropriate to achieve optimal speed performance. Siatras et al4 investigated the acute effect of a stretching protocol, including warm-up and static and dynamic stretching exercises, on speed during vaulting in gymnastics. The results showed that the static stretching protocol significantly decreased the speed performance during vault execution. Therefore, it may not be advisable to include static stretching exercises just prior to vault execution. Similar to Siatras et al,4 Fletcher5,6 conducted two studies testing the speed of athletes after performing different stretching protocols. In the first study,5 the researchers were interested in determining the effect of different static and dynamic stretch protocols on 20-m sprint performance. The Active Dynamic Stretching group had a significant decrease in sprint time (increase in 3 performance). The decrease in performance for the two static stretch groups was attributed to an increase in the musculotendinous unit (MTU) compliance, leading to a decrease in the MTU ability to store elastic energy in its eccentric phase. Static stretching as part of a warm-up may decrease short sprint performance, while active dynamic stretching seems to increase 20-m sprint performance. Following this study, Fletcher6 investigated the effects of incorporating passive static stretching in a warm-up. The purpose of the study was to investigate the effect of manipulating the static and dynamic stretch components associated with a traditional track-and-field warm-up. The active dynamic stretch group resulted in significantly faster times compared to any other group tested. Passive static stretching in a warm-up decreases sprint performance, despite being combined with dynamic stretches, when compared to the solely dynamic stretching protocol. There are many studies suggesting the benefits of including a dynamic warm-up prior to activity.1-6 There has also been research performed to study the possible negative effects of static stretching on speed.7-9 Kistler7 found that previous research has shown static stretching has an inhibitory effect on sprinting performances up to 50 m. The 4 purpose of this study was to determine if the same effects would take place at longer distances such as those seen in competition. Results showed a significant slowing in performance with static stretching in the second 20 (20-40) m of the sprint trials. In conclusion, it seems potentially harmful to include static stretching in the warm-up protocol of collegiate male sprinters in distances up to 100 m. Winchester8 also used track-and-field athletes in his study which aimed to establish whether the deleterious effects of static stretching would diminish the performance enhancements obtained from the dynamic warm-up. The results showed that the no stretching group vs. the static stretching group was significantly faster for the entire 40 m. Similar to Kistler7, this study suggests that performing a static stretching protocol following a dynamic warm-up will inhibit sprint performance in collegiate athletes. In a study by Nelson,9 the researcher attempted to establish whether the deleterious effects of passive stretching seen in laboratory settings would manifest in a performance setting. Four different stretching protocols were performed which included no stretch of either leg, both legs stretched, forward leg in the starting position stretched, and rear leg in the starting position stretched. 5 Three stretching exercises were performed (hamstring stretch, quadriceps stretch, calf stretch) for the stretching protocols. The three stretching protocols induced a significant increase in the 20 m sprint time. They concluded, pre-event stretching may negatively impact the performance of high-power short-term exercise. This study suggests that static stretching is more detrimental to performance than no stretching at all. Many studies have shown that static stretching may be detrimental to athletic performance. However, some studies suggest that static stretching may not be detrimental to athletic performance. A study by Little10 examined the effects of different modes of stretching within a preexercise warm-up on high-speed motor capacities important to soccer performance. Eighteen professional soccer players were tested in vertical jump, stationary 10-m spring, flying 20-m spring, and agility performance after different warm-ups consisting of static stretching, dynamic stretching, or no stretching. There was no significant difference among warm-ups for the vertical jump. The dynamic stretching protocol produced significantly faster 10-m sprint times than did the no-stretching protocol. The dynamic and static stretching protocols produced faster flying 20-m sprint times as opposed to the no stretching 6 protocol. The dynamic stretching protocol also produced significantly faster agility performance than both the static and no stretching protocol. In conclusion, static stretching does not appear to be detrimental to high-speed performance when included in a warm-up for professional soccer players. However, dynamic stretching during the warm-up was most effective as preparation for high-speed performance. Similar to Little,10 Knudson11 studied the serving percentage and radar measurements of ball speed to examine the acute effect of stretching on tennis serve performance. There was no short-term effect of stretching in the warm-up on the tennis serve performance of adult players. So, adding stretching to the traditional five minute warm-up in tennis does not affect serve performance. These two studies suggest that static stretching may not be detrimental to the performance of either the lower or upper extremity, however it is crucial that more research be performed. The ideas of static stretching and flexibility have been around for years. Athletes have incorporated static stretching not only in their warm-up but also as part of their training programs. The thought of increasing flexibility through static stretching to improve athletic performance has been the driving factor in research on 7 stretching protocols. However, recent research suggests that static stretching may have negative results on athletic performance. Performance areas that can be negatively affected include muscle strength, power, agility, and speed. Research has shown that a different type of stretching protocol may be most beneficial. Since these studies have been published, there has been a massive shift from traditional static stretching to a dynamic warm-up before athletic activity. Athletic trainers must provide the best possible care for athletes. By reading and interpreting the recent literature, athletic trainers must adapt stretching protocols, especially if a certain type of stretching protocol could potentially be harmful towards the athlete. If dynamic stretching is more effective as a warm-up than static stretching, additional research should be performed to apply validity and reliability to the study to begin implementing a change from solely static stretching to a dynamic warm-up. 8 METHODS The primary purpose of this study was to examine the effect of three different stretching protocols on sprint speed. The three stretching protocols include: Static Stretching Protocol, Dynamic Stretching Protocol, and a Combination (both static and dynamic) Stretching Protocol. This section will serve to provide an overview of how the experiment was conducted. It will include sections dedicated to Research Design, Subjects, Instrumentation, Procedures, Hypotheses, and Data Analysis. Research Design This research utilized a quasi-experimental design, in which the subjects served as their own control. The independent variable was the stretching protocol utilized before testing. This variable had three levels, a static stretching warm-up protocol, a dynamic stretching warm-up protocol, and a combination warm-up protocol including both static and dynamic stretches. The dependent variable was 9 the time it took the subject to complete a 40 yard sprint. A strength of the study was that the subjects performed each stretching protocol in a counterbalanced order. Subjects The subjects in this study consisted of 16 physically active individuals (n=16). For this study, physically active is defined as an individual that partakes in moderate to intense physical activity such as running, biking, elliptical, stair climber, and/or lower extremity weight training at a minimum of three days a week for at least 30 minutes per session. All subjects were college students and had not sustained a lower extremity injury requiring medical care within the past six months. The volunteers were chosen as a sample of convenience. The subjects were asked about previous history of lower extremity injuries, and those who have had such injuries within the past six months were excluded from the study. All subjects in the study signed an Informed Consent Form (Appendix C1) prior to participation in the study. Along with the Informed Consent Form, each subject signed a Physical Activity Readiness Questionnaire, PAR-Q (Appendix C2) to determine if they were able to participate in this 10 study. Also, the researcher gathered information from each subject’s college entrance physical examination. First, each subject signed a waiver (Appendix C3) in order for this information to be collected. The information taken regarded each subjects physical activity recommendation, given by their physician. Also, in order to determine if each subject was physically active, they were asked to complete a Physical Activity Survey (Appendix C4) to determine their level of activity. The study was approved by the Institutional Review Board at California University of PA. Each subject’s identity remained confidential and was not included in the study. To maintain confidentiality, each subject was given a number prior to participating in the study. Preliminary Research A pilot study was conducted for this research project. Three subjects who fit the inclusion criteria were used to review the study protocols. Each pilot study subject performed all of the testing procedures. The researcher used these trials to determine the subject’s ability to understand directions and determine the amount of time it would take to complete the tasks. 11 Instruments The testing instrument that was used in this study was the Speed Trap II timing system. The Speed Trap II TimerTM (Appendix C5) is a timing system that starts timing when pressure is released from the starting pad, and stops when the subject crosses the reflective beam at the finish line. The times are recorded on the clock that sits on top of the beam. This timing system is accurate to 1/100th of a second, and is capable of timing an athlete up to 55 yards accurately.12 This piece of equipment was used to measure the speed at which each subject could run the 40 yard sprint. Speed is movement distance per unit time and is typically quantified as the time taken to cover a fixed distance. Tests of speed are not usually conducted over distances greater than 200 m because longer distances reflect aerobic capacity more than absolute ability to move the body at maximal speed.13 The 40 yard sprint is a simple way of assessing sprint speed. A starting point is marked. From this position, 40 yards are measured ending with a finish point which is also marked. The subject sprints from starting point to finish point. This test was performed in 12 the gymnasium in Hamer Hall. The subjects performed this test on a basketball court. Their attire included a tshirt, mesh shorts, and running sneakers. The 40 yard sprint was scored using the time recorded from the Speed Trap II TimerTM. The Speed Trap II TimerTM was used to measure the speed in seconds of each subject to determine how fast the subject could complete the 40 yard sprint. Procedures The study was approved by the California University of Pennsylvania Institutional Review Board (IRB) (Appendix C7) prior to any data collection. A random sample of volunteer physically active subjects, was obtained who had not sustained a lower extremity injury in the past six months. Prior to the subject’s involvement in the study, the researcher held a group meeting that each volunteer subject attended. This meeting consisted of explaining the concept of the study and everything it entailed to each of the subjects. At this meeting, each subject completed the Informed Consent Form (Appendix C1), a PAR-Q form, a Physical Activity Survey, and also a waiver allowing the researcher to gather information on their physical 13 examination. Also at this meeting, an explanation of the procedure as well as the risks involved were addressed. Each subject was informed they would be tested on three separate days with at least 48 hours separating each testing session. Each subject was assigned a time slot so only one subject was participating at a time. This was utilized to ensure proper timing for each subject to perform the given tasks. One stretching protocol was performed on each of the testing days. On each of the testing days, the subjects were randomly assigned to one of the stretching protocols in counterbalanced order; static stretching warm-up, dynamic stretching warm-up, or a combination warm-up. Each subject randomly selected one of six possible testing procedures. For example, Subject 1 performed the Static Stretching Protocol on day one, Dynamic Stretching Protocol on day two, and Combination Stretching Protocol on day three. Subject 2 performed the Dynamic Stretching Protocol on day one, Static Stretching Protocol on day two, and Combination Stretching Protocol on day three. Each stretching protocol was randomized until all six testing procedures were fulfilled. Subject 7 performed the same testing procedure as Subject 1. On testing days, each subject was first given instruction on the specific stretches that would be 14 included that day. This was done to ensure each subject performed each stretch correctly. On each of the testing days, each subject performed a 5 minute light jog warm-up at their own pace before any stretching or testing. After the warm-up, subjects were given one minute to rest. Immediately after the one minute of rest, subjects were asked to perform their randomly assigned protocol. The static stretching warm-up protocol (SS) (Appendix C6) that was used consisted of a hamstring stretch, quadriceps stretch, hip flexor stretch, adductor stretch, abductor stretch, gluteal stretch, and a gastrocnemius/soleus stretch. Each stretch was held for 25 seconds, each bilaterally. The subject was given 5 seconds to rest in between each stretch. The dynamic stretching warm-up (DS) (Appendix C6) that was used included: high knees (gluteals and hamstrings), butt kicks (quadriceps and hip flexors), lateral shuffles (abductors and adductors), Russian walks (hamstrings), walking lunges (hip flexors), figure fours (abductors), and heel to toe walks (gastrocnemius/soleus). Subjects performed each of these stretches for 40 seconds, while having 20 seconds of rest in between. Both the static and dynamic protocols took the same amount of time to complete. The dynamic stretching protocol gave the athlete more time 15 to rest because they are stretching dynamically, as the athlete should not become fatigued. The combination warm-up (CS)(Appendix 6) consisted of performing four static stretches that are most common for any physically active person to do. These four static stretches include hamstring stretch, quadriceps stretch, hip flexor stretch, and adductor stretch. Each subject was randomly assigned to perform three of the seven dynamic stretches, before testing. The time allowed for each stretch was the same as the previous two conditions, so the overall time was the same. The researcher prepared a tape recording that instructed the subjects when to change the stretch to ensure the protocols were consistent between each subject. After the subjects were finished with their assigned protocol, they were given another rest period of two minutes in order to prepare for their performance test. They then performed three trials of the 40 yard sprint with another two minutes of rest in between trials. The three trials were timed using the Speed Trap II timing system, and the best of the three trials was recorded. These results were recorded on the data collection forms (Appendix C5). This process was repeated until all subjects performed each of the protocols. 16 Hypothesis The following hypothesis is based on previous research and the researcher’s intuition based on a review of the literature. 1. There will be no significant difference for the 40 yard sprint time for sprint speed between the three stretching protocols. Data Analysis All data was analyzed by SPSS version 18.0 for Windows at an alpha level of 0.05. The research hypothesis was analyzed using a repeated measures analysis of variance. 17 RESULTS The purpose of this study was to examine the effect of three different stretching protocols on sprint speed. The three protocols include: a static stretching protocol, dynamic stretching protocol, and a combination of both static and dynamic protocol. Each volunteer subject completed one stretching protocol per testing session. Each subject completed 3 trials of a 40 yard sprint after each protocol. The following results section will be divided into two sections: Demographic Information and Hypothesis Testing. Demographic Information Subjects used in this study (N=16) were volunteers from California University of Pennsylvania. The subjects included eleven males and five females. The subjects age ranged from 18-23 years. Each subject was physically active as defined by the physical activity survey. For this study, physically active means each subject must partake in 18 moderate to intense physical activity. Such activity may include running, biking, elliptical, stair climber, and/or lower extremity weight training. Subjects must participate in this type of exercise at a minimum of three days a week for at least 30 minutes per session. Hypothesis Testing Hypothesis Testing was performed on the data using SPSS software. All subjects were tested for sprint speed following each of the stretching interventions. A repeated measures analysis of variance was used with an alpha level of .05. Hypothesis 1: There will be no significant difference for the 40 yard sprint time for sprint speed between the three stretching protocols. Conclusion: To test the hypothesis, each subject’s fastest time was recorded for each of the three warm-up protocols. These include: the Static Stretching protocol, the Dynamic Stretching protocol, and the Combination Stretching protocol. A repeated measures ANOVA was used to compare the times for the subjects under each condition. 19 Table 1 illustrates the mean times for each condition. A significant effect was found (F 2,30 = .03 p < .05). Since the ANOVA results were significant, post-hoc analysis of the data was performed. In order to perform post-hoc testing, protected dependent t tests were utilized. With this testing, all three warm up conditions were compared to one another. The Static Stretching protocol was compared to the Dynamic Stretching protocol. The Static Stretching protocol was compared to the Combination Stretching protocol. Lastly, the Dynamic Stretching protocol was compared to the Combination Stretching protocol. Conducting three tests has the potential to inflate the Type I error rate, so a significance level of .017 (.05/3) was used to maintain an overall significance level of .05. Follow-up protected t tests revealed that times decreased significantly between the Static Stretching protocol (5.660s +/- .492) and the Combination Stretching protocol (5.575s +/- .496). The differences in time between all three stretching protocols are summarized in Table 2. 20 Table 1. 40 Yard Sprint Descriptive Statistics Stretching Mean(s) Std. Condition Deviation Static 5.660 .492 Dynamic 5.600 .474 Combination 5.575 .496 Table 2. Differences in Time Between Stretching Protocols Static Dynamic Combination Static 0 -0.06 -0.085 Dynamic 0.06 0 -0.025 Combination 0.085 0.025 0 21 DISCUSSION The following discussion is divided into three subsections: Discussion of Results, Conclusions, and Recommendations. Discussion of Results Stretching prior to activity has been widely accepted within the athletic population for decades. Static stretching was once dominant for a pre-activity warm-up, however, recent studies have shown that static stretching may lead to an a decrease in performance.7-9 There has also been an increasing number of studies1-7 identifying the positive effects of dynamic stretching when compared to static stretching. Therefore, there has been a significant shift towards dynamic stretching as part of a pre-activity warm-up. The purpose of this study is to investigate the effect of three different stretching protocols on the sprint performance of collegiate athletes. These three stretching 22 protocols include static stretching, dynamic stretching, and a combination of static and dynamic stretching. Furthermore, this study is intended to provide statistical evidence in order to determine which stretching protocol would be most beneficial for physically active individuals and athletes prior to performance. It was hypothesized that there would be no significant difference for the 40 yard sprint time for sprint speed between the three stretching protocols. Performance of the 40 yard sprint was measured in seconds by the Speed Trap II timing system.12 Statistical analysis revealed that there was a significant difference in performance between the three stretching protocols. As shown in Table 1, combination stretching intervention produced the fastest mean scores. During the stretching interventions, subjects were asked if they felt one of the warm ups better prepared them for participation in the study. Many of the subjects reported that dynamic stretching prepared them best for the 40 yard sprint. However, five subjects felt more prepared after the static stretching intervention. These subjects were unfamiliar with dynamic stretching, and have always performed static stretching only before exercise. These subjects also reported that they had felt minor fatigue 23 after performing the dynamic stretching intervention, which may have impacted their time. The results of this study are similar to those reported by Siatras et al,4 Fletcher,5,6 and Little10. These studies all found significant differences in sprint speed between the stretching conditions. This study is similar to the studies within the literature in that they use anaerobic measurements of performance. All the studies utilized tests that averaged under twelve seconds to complete. The study by Siatras et al,4 measured vaulting speed from the start of the runway until contact with the vault was made, which is about 7.5 seconds. The results showed that the static stretching protocol significantly decreased the speed performance. The studies by Fletcher5,6 measured the time to sprint twenty meters and fifty meters respectively. For the twenty meter test, all times were under 4 seconds. For the fifty meter test, all times were under 7.5 seconds. In a study by Little,10 the researchers measured the time to complete a 10 meter sprint and also a 20 meter flying sprint. Both of these tests took less than 5 seconds to complete. These findings support the fact that short distance anaerobic events positively benefit from dynamic stretching and do not benefit from static stretching. 24 Two studies have looked at using a combination of both static and dynamic stretching. In the first study by Winchester8, the researchers had subjects perform dynamic stretching followed by static stretching. They were interested in determining if static stretching would have deleterious effects on performance enhancement gains from dynamic stretching. Winchester found that static stretching resulted in a significantly faster forty meter time. Similar to Winchester, Wong et al14 used a combination of both static and dynamic stretching and measured their effect on a twenty meter sprint. Each subject performed one of three static stretching protocols followed by the same dynamic stretching protocol following a given static stretching protocol. This study differed from Winchester in that the subjects performed static stretching before dynamic stretching. They found that there was no significant difference between the stretching protocols. This study did not compare solely static vs. dynamic vs. combination of both. There may be a few explanations as to why the results of this study differed from the literature. According to the majority of the literature, dynamic stretching is the best method of warm-up for athletes. However, this study used physically active individuals. The subjects may not 25 have been used to dynamic stretching or stretching at all. This may have affected their ability to run a 40 yard sprint. Subjects were also unaccustomed to performing a dynamic warm-up. During this stretching protocol, some subjects became fatigued and it may have altered their performance while running the 40 yard sprint. Most athletes are very involved with stretching both before and after activity. It is possible that the subjects in this study do not stretch efficiently before they workout. Overall, the combination stretching protocol produced the fastest mean times. The static stretching part of this warm-up may have increased range of motion and elongation of the stretched muscle. Then, the dynamic stretching part of this warm-up increased blood flow to musculature and provided a stretch throughout the entire range of motion. This may be more beneficial for physically active individuals than athletes. However, more research must be done in order to determine if a combination stretching warm-up is more beneficial for athletes as well. Conclusions This study revealed that the type of stretching protocol (Static stretching, dynamic stretching, or 26 combination stretching) had a significant effect on a timed 40 yard sprint of physically active individuals. This significance is important in running a 40 yard sprint. The results showed a significant difference in times which are key in terms of sprint performance. The subjects in this study performed each stretching protocol once, followed by three trials of a 40 yard sprint. Results showed that there was a significant decrease in sprint time when preceded by a combination of static stretching followed by dynamic stretching. Although not significant, the dynamic stretching protocol did produce faster mean 40 yard sprint times as compared to the static stretching intervention. According to the literature, it is essential to incorporate dynamic stretching as part of a warm-up, however it may also be beneficial to incorporate static stretching prior to a dynamic warm-up. The results of this study suggest that performing solely static stretching should be avoided prior to physical activity. Based on the results of this study and the literature, a proper dynamic warm-up should be included prior to physical activity. Static stretching may be beneficial to increase range of motion and tissue length while a dynamic warm-up will increase blood flow and prepare musculature for activity. Further research must be performed to determine if a combination of static 27 stretching followed by dynamic stretching is more beneficial compared to just a dynamic warm-up. Recommendations It is important for Certified Athletic Trainers to remain up-to-date on the research regarding stretching in order to implement the safest and most beneficial warm-up techniques for athletes. Many studies investigating stretching and warm-up focus on short distance sprinting. It may be beneficial to incorporate a study which determines which type of stretching is beneficial for longer distances. One area from this study that could be modified is the duration of the dynamic stretching protocol. Many subjects reported that they were semi-fatigued. A shorter dynamic stretching protocol may have produced faster times than the results indicate. Another area that could be modified is to use athletes. Physically active individuals were used in this study, who may not be accustomed to sprinting for 40 yards. Using athletes who are accustomed to this type of activity may be more beneficial. Athletes who participate in sports 28 such as football, basketball, and soccer would be useful subjects. Another possibility is to incorporate different stretching protocols. It may be beneficial to have multiple static stretching protocols, dynamic stretching protocols, and combination stretching protocols. All of these suggestions could add to the current research and knowledge athletic trainers have regarding stretching protocols as part of an athlete’s warm-up. 29 REFERENCES 1. Arabaci R. Acute Effects of Differential Stretching Protocols on Physical Performance in Young Soccer Players. NWSA. 2009; 4 (2); 50-63. 2. Faigenbaum AD, Bellucci M, Bernieri A, Bakker B, Hoorens K. Acute Effects of Different Warm-up Protocols on Fitness Performance in Children. J Strength Cond Res. 2005; 19 (2); 376-381. 3. Faigenbaum A, et al. Acute Effects of Different WarmUp Protocols on Anaerobic Performance in Teenage Athletes. Pediatr Exerc Sci. 2006; 18 (1); 64-75. 4. Siatras T, Papadopoulos G, Mameletzi D, Gerodimos V, Kellis S. Static and Synamic Acute Stretching Effect on Gymnasts’ Speed in Vaulting. Pediatr Exerc Sci. 2003; 15 (4); 383-391. 5. Fletcher IM, Jones B. The Effect of Different Warm-Up Stretch Protocols on 20 Meter Sprint Performance in Trained Rugby Union Players. J Strength Cond Res. 2004; 18 (4); 885-888. 6. Fletcher IM, Anness R. The Acute Effects of Combined Static and Dynamic Stretch Protocols on Fifty-Meter Sprint Performance in Track-and-Field Athletes. J Strength Cond Res. 2007; 21 (3); 784-787. 7. Kistler BM, Walsh MS, Horn TS, Cox RH. The Acute Effects of Static Stretching on the Sprint Performance of Collegiate Men in the 60- and 100- m Dash after a Dynamic Warm-Up. J Strength Cond Res. 2010; 24 (9); 2280-2284. 8. Winchester JB, Nelson AG, Landin D, Young MA, Schexnayder IC. Static Stretching Impairs Sprint Performance in Collegiate Track-and-Field Athletes. J Strength Cond Res. 2008; 22 (1); 13-18. 9. Nelson AG, Driscoll NM, Landin DK, Young MA, Schexnayder IC. Acute Effects of Passive Muscle 30 Stretching on Sprint Performance. J Sprt Sci. 2005; 23 (5); 449-454. 10. Little T, Williams AG. Effects of Differential Stretching Protocols During Warm-Ups on High-Speed Motor Capacities in Professional Soccer Players. J Strength Cond Res. 2006; 20 (1); 203-207. 11. Knudson DV, Noffal GJ, Bahamonde RE, Bauer JA, Blackwell JR. Stretching Has No Effect on Tennis Serve Performance. J Strength Cond Res. 2004; 18 (3); 654656. 12. Brower Timings Systems. http://www.browertiming.com. Accessed November 11, 2011. 13. Baechle T, Earle R. Essentials of Strength Training and Conditioning. National Strength and Conditioning Association; 2008. 14. Wong DP, Chauuachi A, Lau PWC, Behm D. Short durations of static stretching when combined with dynamic stretching do not impair repeated sprints and agility. J Sci Med Sport. 2011; 10; 408-416 31 APPENDICES 32 APPENDIX A Review of Literature 33 REVIEW OF LITERATURE This review of the literature will examine the effects of static and dynamic stretching techniques on athletic performance. There has been much debate about the effectiveness of static and dynamic stretching as part of an athlete’s warm-up before athletic activity. There has been a shift in the thought of which stretching technique is more beneficial for the athlete. For many years, static stretching was thought to be the most effective part of the warm-up, the act of moving a muscle into a stretch position and holding it for a number of seconds. However, there has been a recent shift, accompanied by supporting research, which encourage the utilization of a dynamic warm-up before athletic activity. Thus, the purpose of this literature review is to examine different types of warm-up protocols and determine their overall effect on athletic performance. This review of the literature will be separated into three sections: 1) Introduction to Stretching and Flexibility 2) Speed 3) Stretching and Speed. Finally, a summary will draw conclusions from the literature reviewed. 34 Introduction to Stretching and Flexibility Stretching has always been an important tool that athletes use as part of a warm-up before athletic activity. From youth athletics to professional athletics, stretching has been at the forefront as part of the warm-up. However, the evolution of different stretching protocols in the literature has left many athletes, as well as athletic trainers, contemplating which type of stretching is most beneficial before athletic activity. There is the potential that some types of stretching may have many benefits, however there is also the potential that stretching may have detrimental effects. In order to understand the literature concerning the effect of stretching on performance, it is crucial that one understands the neurophysiologic basis of stretching. Mechanisms of Stretching Stretching is defined as movement applied by an external and/or internal force in order to increase muscle flexibility and/or joint range of motion. The aim of stretching before exercise is to increase muscle-tendon unit (MTU) length and flexibility.1 Stretching results in 35 elongation of muscles and soft tissues through mechanical and neurological mechanisms.1,5 MTUs can be lengthened in two ways; muscle contraction and passive stretching. When a muscle contracts, the contractile elements are shortened, and the passive elements are thus lengthened. When muscle tissue is lengthening, the muscle fibers and connective tissues are elongated because of the application of external force.2 Stretching increases MTU length by affecting the biomechanical properties of muscle (range of motion and viscoelastic properties of the MTU).1-4 Two sensory organs of MTUs, the muscle spindle and the Golgi tendon organ (GTO), are mechanoreceptors that convey information to the central nervous system (CNS) about what is occurring in a MTU and affect a muscle’s response to stretch.3 Muscle spindles are the major sensory organ of muscle and are sensitive to quick and sustained stretch. Muscle spindles are small, encapsulated receptors composed of afferent sensory fiber endings, efferent motor fiber endings, and specialized muscle fibers. The main function of muscle spindles is to receive and convey information about changes in the length of a muscle. When muscle spindles are stimulated, a reflexive response is created which causes a muscle to contract.2-3 When a muscle is put 36 in a stretch position, the muscle contracts preventing an overstretching of the muscle. This act is known as the stretch reflex. The other sensory organs of MTUs are known as Golgi tendon organs. The GTO functions to monitor changes in tension of the MTU. These sensory organs are sensitive to slight changes of tension on a MTU as the result of passive stretch of a muscle or with active muscle contractions during normal movement.3 When tension within a muscle develops, the GTO fires causing a decrease in tension in the MTU being stretched. Originally, the GTO was thought to fire and inhibit muscle activation only in the presence of high levels of muscle tension as a protective mechanism. However, the GTO has a low threshold for firing, so it can continuously monitor and adjust the force of active muscle contractions during movement or the tension in muscle during a passive stretch.3,4-5 Injury Prevention/DOMS One of the main reasons why athletes stretch before participating in athletics is to avoid injury. The thought is, lengthening muscle groups by stretching will prepare the muscular system to perform. The literature relating to this idea of stretching to prevent injury needs to be 37 further researched. However, some studies have suggested that injury may be related to either too little or too much flexibility.6-8 A study by Johannson et al6 investigated the effects of pre-exercise stretching on delayed onset muscle soreness. Ten female volunteers performed 10 sets of 10 maximal isokinetic eccentric contractions for knee flexion with both legs after a 5 minutes cycle ergometer warm-up. Prior to the exercise for one leg, 4 X 20 sec of static stretching for the hamstring muscle group was implemented. No differences were found when comparing stretched and nonstretched legs. In conclusion, the study suggests that preexercise static stretching has no preventative effect on muscle soreness, tenderness and force loss that follows heavy eccentric exercise. In a study by Lund et al,7 the researchers found that passive stretching did not have any significant influence on muscle pain and muscle strength. In this study, the purpose was to measure if passive stretching would influence delayed onset muscle soreness and dynamic muscle strength following eccentric exercise. Seven women (28-46 years) performed eccentric exercise with right quadriceps in an isokinetic dynamometer until exhaustion. Two separate experiments were performed. In the first experiment, no 38 stretching was implemented. The second experiment, roughly 13-23 months later, incorporated passive stretching (3 X 30 sec) of the quadriceps. Stretching was performed before and immediately after the eccentric exercise. There was no difference in the reported variables between experiments one and two. The researchers suggest that passive stretching after eccentric exercise does prevent delayed onset muscle soreness. Witvrouw et al8 researched the relationship between the type of sports activity, stretching, and injury prevention. In this review, the researchers provided insight to the relationship between stretching and injury prevention. Several authors have suggested that stretching has a beneficial effect on injury prevention. However, clinical evidence has reported that stretching before exercise does not prevent injuries. The researchers believe that the contradictions between theories can be explained by considering the type of sports activity and individual participates in. Sports that require high intensity stretch-shortening cycles require a muscle-tendon unit that is compliant enough to store and release high amounts of elastic energy. If participants in these types of sports activities have insufficient compliant muscle-tendon unit, the demands in energy absorption and release may exceed the 39 capacity of the muscle-tendon unit, thus causing injury. On the other hand, sports activities that are low-intensity, there is no need for a compliant muscle-tendon unit. So, stretching may not be as advantageous. Stretching For years, stretching has been the most important component of an athlete’s warm-up. Athletes have always known that stretching their muscles before activity is important for injury prevention and performance. It is important to understand the different types of stretching. Different methods of stretching include: Static Stretching, Dynamic Stretching, Ballistic Stretching, and Proprioceptive Neuromuscular Facilitation. The importance of two of these techniques will be examined in the following sections. Static Stretching Static stretching is a commonly used method of stretching in which soft tissues are elongated just past the point of tissue resistance and then held in the lengthened position with a sustained stretch force over a period of time, usually around 30 seconds.1 Static 40 stretching is an effective form of stretching to increase flexibility, and is considered a safer form of stretching when compared to ballistic stretching.1,4-5 Despite utilizing static stretching as a means to increase flexibility, there is some research that suggests that static stretching may not be the most beneficial method and may even be detrimental to an athlete’s performance.20-23 Static stretching may not be the most beneficial method of warm-up because it fails to stretch a muscle group throughout the full range of motion. During sports activity, the body is constantly moving and changing direction. In order to prepare the body for these movements, an athlete should warm-up their muscles in similar fashion. Incorporating static stretching as part of a warm-up for athletics may not prepare the muscles as well as stretching that incorporates functional movements. However, static stretching may be beneficial to use after competition to increase range of motion.10 Although static stretching may not be beneficial for warming-up before athletic activity, it may be valuable after exercise to decrease delayed muscle onset soreness. Lucas and Koslow9 performed a study looking at static, dynamic, and proprioceptive neuromuscular facilitation stretching techniques on flexibility. Sixty-three college 41 women were the subjects in a 7-week study. Subjects were assigned to one of three treatment groups. There was a pretest, a midtest (after 11 days of treatment), and a posttest (after 21 days of treatment). By comparing the pretest and posttest means, they found that all three methods of stretching produced significant improvements in flexibility. Dynamic Stretching Dynamic stretching is a type of functionally based stretching that uses sports-specific movements to prepare the body for activity.11 Dynamic stretching places an emphasis on the movement requirements of the sport or activity rather than on individual muscles.11 The ability to actively move a joint throughout a range of motion is generally far more sport specific than the ability to statically hold a stretch.11 The use of dynamic stretches during a specific part of the warm-up provides numerous advantages: 1. Dynamic stretching helps promote the temperature-related benefits of the warm-up, 2. A number of joints can be integrated into a single stretch, 3. The muscle does not relax during the stretch but instead is active throughout the range of motion.11 42 One study by Mann12 examined the benefits and guidelines for implementing a dynamic stretching program and to further examine static, ballistic, and proprioceptive neuromuscular facilitation (PNF) stretching techniques. The researchers concluded dynamic stretching should be implemented before sport activity. Static stretching should be utilized immediately following sport activity to increase range of motion. Ballistic Stretching Ballistic stretching is one stretching technique that is not utilized as often as static or dynamic stretching. Ballistic stretching is defined as a rapid, forceful intermittent stretch that is a high speed and high intensity stretch.3 It is characterized by the use of quick, bouncing-type movements that in which the end position is not held.3,11 Ballistic stretching may be used as a preexercise warm-up; however, it may injure muscles or connective tissues, especially when there has been a previous injury. Ballistic stretching usually triggers the stretch reflex that does not allow the involved muscles to relax and defeats the purpose of stretching.11 43 Proprioceptive Neuromuscular Facilitation Proprioceptive Neuromuscular Facilitation (PNF) is a method of stretching, mainly in order to increase flexibility.3,11 PNF techniques involve both passive movement as well as active (concentric and isometric) muscle actions. PNF may be superior to other stretching methods, however it is often impractical to use as part of a warm-up because most of the stretches require a partner with some expertise.11 There are three basic types of PNF stretching techniques which include: hold-relax, contract-relax, and hold-relax with agonist contraction.3,11 The hold-relax technique begins with a passive pre-stretch that is held at the point of mild discomfort for 10 seconds. The clinician then applies a hip flexion force and instructs the athlete to hold that position against resistance for 6 seconds. The athlete then relaxes and a passive stretch is performed and held for 30 seconds. The second technique, contract-relax, also begins with a passive pre-stretch that is held at the point of mild discomfort for 10 seconds. The athlete then extends the hip against resistance provided by the clinician so that a concentric muscle action through the full range of motion occurs. The athlete then relaxes, and a passive hip flexion stretch is applied and held for 30 seconds. Lastly, the hold-relax with agonist contraction 44 technique is identical to the hold-relax in the first two phases. During the third phase, a concentric action of the agonist is used in addition to the passive stretch to add to the stretch force.3,11 These three techniques may provide an increase in flexibility. However, it may not be appropriate to utilize this technique as part of a warm-up due to the need for an experienced clinician to instruct and execute each stretch correctly. Speed Most athletes are always trying to improve their athletic performance. Some areas of interest are strength, power, agility, and speed. Speed is often difficult to define and can also be difficult to improve. It is important to understand what speed is, how it is measured, muscle physiology of speed, and training techniques to improve speed. What is Speed and How is it Measured? One aspect of performance that many athletes try to improve is speed. Speed is movement distance per unit time and is typically quantified as the time taken to cover a fixed distance.11 More specifically, running speed is a 45 ballistic mode of locomotion with an alternating flight phase and single leg support phase. Sprinting is a series of running strides that repeatedly launch the athlete’s body as a projectile at maximal acceleration or velocity (or both), usually over brief distances.11 There are many tests that measure speed, the most popular being the 40 yard sprint. This test is utilized in many sports to determine the athlete’s performance level. Tests of speed are not usually conducted over distances greater than 200m because longer distances reflect anaerobic or aerobic capacity more than absolute ability to move the body at a maximal speed.11 Training Techniques Used to Improve Speed Improving an athlete’s speed can often be a difficult task. The implementation of certain speed drills is essential in increasing an athlete’s speed. As seen in an article by Cissik13, many aspects of speed are examined, including flexibility, fatigue, technique, stride length, and frequency. These are all areas that must be improved in order to increase an athlete’s speed. This article also provides a series of exercise drills designed to improve training technique. Studying sprint technique more in depth was Cronin14. In this study, the biomechanical differences 46 between the acceleration phase and the maximum velocity phase of sprinting are considered. Research on the various resisted sprinting techniques are examined, linking these techniques to the biomechanics of the acceleration phase. Lastly, suggestions are made regarding the application of these findings to the training of athletes. In a study by Harrison,15 the researchers investigated whether a resistance sprint training intervention would enhance the running speed and dynamic strength measures in male rugby players. Fifteen male rugby players (mean age 20.5) were randomly assigned to either a control or resistance sprint groups. The resistance sprint group performed two sessions per week for six weeks, while the control group did no training. The results show a significant decrease in time to 5 m for the 30- m sprint for the resistance sprint group. In conclusion, the study suggests that it may be beneficial to employ a resistance sprint training program with the aim of increasing initial acceleration from a static start for sprinting. Stretching and Speed Every athlete wants to perform at the highest level possible. Stretching as part of a warm-up may increase 47 performance, however, the type of stretching performed is essential to perform at an optimal level. Static stretching before competition has been the traditional method to utilize in order to prepare the muscular system for work. However, there has been much research to suggest that static stretching is not the most beneficial means of warmup.16-23 McMillian et al16 compared the effect of a dynamic warm up with a static-stretching warm up on different measures of power and agility. Thirty subjects completed the study (16 men, 14 women, 18-24 years). On three consecutive days, subjects performed 1 of 2 warm up routines or performed no warm up. The warm up protocols lasted 10 minutes. The tests included a T-shuttle run, underhand medicine ball throw for distance, and 5-step jump. The results showed there were better performance scores after the dynamic warm up for all three tests. Warm up routines that use static stretching as the stand-alone activity should be reevaluated and/or replaced with a dynamic warm up. In a similar study Arabaci17 examined the acute effects of dynamic, static, and no stretching within a warm-up on vertical jump, agility, maximal speed, anaerobic power, and reaction time of young elite soccer players. The results showed that the dynamic stretching results were better than 48 the results of static stretching and no stretching. There was a significant difference between the results of the dynamic warm-up as compared to static or no stretching. Dynamic stretching should be the preferred warm-up for young elite soccer players. Faigenbaum et al18,19 conducted two studies which are very similar. In the first study, Faigenbaum18 compared the acute effects on youth fitness of three different warm-up protocols utilizing static stretching or dynamic exercise performance. Sixty children (mean age 11.3 years) performed three different warm-up routines in random order on nonconsecutive days. The warm-up consisted of 5 minutes of walking and 5 minutes of static stretching, 10 minutes of dynamic stretching, or 10 minutes of dynamic exercise plus 3 drop jumps from 15-cm boxes. After each warm-up, subjects were tested on the vertical jump, long jump, shuttle run, and v-sit flexibility. Results showed that vertical jump and shuttle run performance declined significantly following the static stretch warm-up compared to the two dynamic warm-ups. There were no significant differences in flexibility following the three warm-up treatments. In conclusion, children should perform moderate to high intensity dynamic exercise prior to sport activities that require a high power output. 49 In the second study conducted by Faigenbaum19, the researchers examined the acute effects of pre-event static stretching, dynamic stretching, and combined static and dynamic stretching on vertical jump, medicine ball toss, 10-yard sprint, and pro-agility shuttle run. Thirty teenage athletes (mean age 15.5 years) participated in three testing sessions in random order on three nonconsecutive days. Before testing, subjects performed 5 mm of walking/jogging followed by one of three warm-up protocols. Results showed an increase of performance for all performance areas except agility after the dynamic and combined warm-ups as compared to just the static warm-up. The study indicates that pre-event dynamic exercise or static stretching followed by dynamic exercise may be more beneficial than static stretching alone in teenage athletes who perform power activities. These studies suggest that dynamic stretching may be more beneficial than static stretching. The results show that dynamic stretching increases important aspects of performance including power, agility, and speed. Speed may be one of the most important aspects of performance. Studies have shown that dynamic stretching is appropriate to achieve optimal speed performance. Siatras et al20 investigated the acute effect of a protocol, 50 including warm-up and static and dynamic stretching exercises, on speed during vaulting in gymnastics. Eleven boys were asked to perform three different protocols consisting of warm-up, warm-up and static stretching, and warm-up and dynamic stretching on three nonconsecutive days. The results showed that the static stretching protocol significantly decreased the speed performance during a run of vault. Therefore, it is not advisable to include static stretching exercises just prior to vault execution. Fletcher21,22 conducted two studies testing the speed of different athletes after different stretching protocols. In the first study by Fletcher21, the researchers were interested in determining the effect of different static and dynamic stretch protocols on 20-m sprint performance. Ninety-seven male rugby players were randomly assigned to four groups: passive static stretch (PSS), active dynamic stretch (ADS), active static stretch (ASST), and static dynamic stretch (SDS). All groups performed a standard 10minute jog warm-up, followed by two 20-m sprints. The 20-m sprints were then repeated after subjects had performed their assigned stretch protocol. The PSS and ASST groups had a significant increase in sprint time, while the ADS group had a significant decrease in sprint time. The 51 decrease in performance for the two static stretch groups was attributed to an increase in the musculotendinous unit (MTU) compliance, leading to a decrease in the MTU ability to store elastic energy in its eccentric phase. In conclusion, static stretching as part of a warm-up may decrease short sprint performance, while active dynamic stretching seems to increase 20-m sprint performance. Following this study, Fletcher22 investigated the effects of incorporating passive static stretching in a warm-up. The purpose of the study was to investigate the effect of manipulating the static and dynamic stretch components associated with a traditional track-and-field warm-up. Eighteen experienced sprinters were randomly assigned in a repeated-measures, within-subject design study with three interventions: active dynamic stretch (ADS), static passive stretch combined with ADS (SADS), and static dynamic stretch combined with ADS (DADS). A standardized 800-m jogged warm-up was performed before each different stretch protocol, followed by two 50-m sprints. Results showed that the SADS intervention yielded significantly slow 50-m sprint times then either the ADS or DADS protocols. It was concluded that passive static stretching in a warm-up decreases sprint performance, 52 despite being combined with dynamic stretches, when compared to the solely dynamic stretching protocol. Kistler23 found that previous research has shown that static stretching has an inhibitory effect on sprinting performances up to 50 m. The purpose of this study was to see what would happen to these effects at longer distances such as those seen in competition. Eighteen male subjects completed both static stretching and no stretching conditions across two days of testing. On each day, all subjects first completed a generalized dynamic warm-up routine that included a self-paced 800-m run, followed by a series of dynamic movements, sprints, and hurdle drills. After this warm-up subjects were assigned to either a static stretching or a no-stretching condition. They then immediately performed 2 100-m trials with timing gates set up at 20, 40, 60, and 100 m. Results showed a significant slowing in performance with static stretching in the second 20 (20-40) m of the sprint trials. In conclusion, it seems harmful to include static stretching in the warm-up protocol of collegiate male sprinters in distances up to 100 m. Winchester24 also used track-and-field athletes in his study which aimed to establish whether the deleterious effects of static stretching would wash out the performance 53 enhancements obtained from the dynamic warm-up. Eleven males and eleven females, who were athletes of a NCAA Division 1 track team, performed a dynamic warm-up followed with either static stretching or rest. After the warm-up was completed, three 40 m sprints were performed to investigate the effects of the static stretching condition on sprint performance when preceded by a dynamic warm-up. The results showed that the no stretching group vs. the static stretching group was significantly faster for the entire 40 m. Similar to Kistler23, this study suggests that performing a static stretching protocol following a dynamic warm-up will inhibit sprint performance in collegiate athletes. In a study by Nelson25, the researchers wanted to establish whether the deleterious effects of passive stretching seen in laboratory settings would manifest in a performance setting. Sixteen subjects (11 males, 5 females) on a Division I NCAA track athletics team performed electronically timed 20m sprint with and without prior stretching of the legs. Four different stretching protocols were performed which included no stretch of either leg, both legs stretched, forward led in the starting position stretched, and rear leg in the starting position stretched. Three stretching exercises were performed (hamstring 54 stretch, quadriceps stretch, calf stretch) for the stretching protocols. The three stretching protocols induced a significant increase in the 20 m time. In conclusion, pre-event stretching may negatively impact the performance of high-power short-term exercise. This study suggests that static stretching is more detrimental to performance than no stretching at all. Many studies have shown that static stretching is detrimental to athletic performance. However, some studies suggest that static stretching may not be detrimental to athletic performance. A study by Little26 examined the effects of different modes of stretching within a preexercise warm-up on high-speed motor capacities important to soccer performance. Eighteen professional soccer players were tested in vertical jump, stationary 10-m spring, flying 20-m spring, and agility performance after different warm-ups consisting of static stretching, dynamic stretching, or no stretching. There was no significant difference among warm-ups for the vertical jump. The dynamic stretching protocol produced significantly faster 10-m sprint times than did the no- stretching protocol. The dynamic and static stretching protocols produced faster flying 20-m sprint times as opposed to the no stretching protocol. The dynamic stretching protocol also produced 55 significantly faster agility performance than both the static and no stretching protocol. In conclusion, static stretching does not appear to be detrimental to high-speed performance when included in a warm-up for professional soccer players. However, dynamic stretching during the warm-up was most effective as preparation for high-speed performance. In a study by Knudson27, the researchers studied the serving percentage and radar measurements of ball speed to examine the acute effect of stretching on tennis serve performance. Eighty-three tennis players from beginning to advanced level volunteered to serve following traditional warm-up and traditional plus stretching conditions. There was no short-term effect of stretching in the warm-up on the tennis serve performance of adult players, so adding stretching to the traditional 5- minute warm-up in tennis does not affect serve performance. These two studies suggest that static stretching may not be detrimental to performance, so it is crucial that further research be conducted. 56 Summary Before any type of athletic activity, athletes stretch their muscles. As an athletic trainer, it is important to educate athletes about stretching. Through an understanding of the physiology of the musculotendinous unit as well as by reading up to date literature on the matter, athletic trainers will be able to choose a stretching protocol that will be most beneficial to the athlete. It is important that athletic trainers educate athletes not only about how stretching can improve performance, but also that stretching may prevent injury and increase flexibility. However, more research must be done to determine whether different stretching protocols are advantageous in reducing injury rates. Overall, the majority of the studies that compare different stretching protocols reveal the same conclusions. Almost all the studies examined found dynamic stretching to be most beneficial. There was no literature found suggesting that dynamic stretching is detrimental to performance. Some studies have found static stretching to be detrimental to the performance of athletes in various areas. Other studies conclude that dynamic stretching is more beneficial than static stretching. These results have 57 caught the interest of athletes, coaches, and sports medicine professionals. Through observation, many athletes are beginning to stray away from the traditional static stretching protocol and switch to an active dynamic warmup. 58 APPENDIX B The Problem 59 STATEMENT OF THE PROBLEM Statement of the Problem Stretching has been widely accepted within the athletic population for decades. Static stretching was once dominant for a pre-activity warm-up. However, recent studies have shown that static stretching may lead to an increase risk of injury and also a decrease in performance. There have also been more studies on the positive effects of dynamic stretching. So, there has been a massive shift towards dynamic stretching as part of a pre-activity warmup. The purpose of this study is to investigate the effect of different stretching protocols on the sprint performance of physically active adults. The purpose of this study is to investigate the effect of three different stretching protocols on the sprint performance of physically active adults. These three stretching protocols include static stretching, dynamic stretching, and a combination of static and dynamic stretching. Furthermore, this study is intended to provide statistical evidence in order to determine which stretching protocol would be most beneficial for a collegiate athlete. 60 Definition of Terms The following definitions of terms will be defined for this study: 1) Flexibility – The ability to move a single joint or series of joints smoothly and easily through an unrestricted, pain-free ROM.3 2) Stretching - Movement applied by an external or internal force in order to increase muscle flexibility and/or joint range of motion.1 3) Static Stretching – Holding a stretch for a period of time with little or no movement.1,3 4) Dynamic Stretching – Controlled movement through the active range of motion.1 5) Golgi Tendon Organ (GTO) – Sensory nerve endings located in tendons that sense change in muscle tension.3 6) Muscle Spindles – Proprioceptors found in skeletal muscle that are sensitive to stretch, and signals muscle length and rate of change in muscle length.3 Basic Assumptions The following are basic assumptions of this study: 61 1) The subjects did not perform any other stretching other than the stretching asked of them in this study. 2) The subjects performed the 40-yard sprint to the best of their ability. 3) The equipment was calibrated and utilized properly during the course of this study. 4) The 40-yard sprint is a valid test for assessing sprint speed. 5) The subjects were “physically active” according to the physical activity survey Limitations of the Study The following are possible limitations of the study: 1) Subjects may not put forth maximal effort. 2) Some subjects may be in better shape than others. Delimitations of the Study The following are possible delimitations of the study: 1) The same person serves as the researcher, the data collector, and the Athletic Trainer. 2) The subjects were volunteers by a convenience sample. 3) The results can only be generalized to physically active adults. 62 Significance of the Study The ideas of static stretching and flexibility have been around for years. Athletes have incorporated static stretching in not only their warm-up but also as part of their training programs. The thought of increasing flexibility by static stretching will improve athletic performance has been the driving factor in research on stretching protocols. However, recent research suggests that static stretching may have negative results on athletic performance. Performance areas that can be negatively affected include muscle strength, power, agility, and speed. Research has shown that a different type of stretching protocol may be most beneficial. Since these studies have been published, there has been a massive shift from traditional static stretching to a dynamic warm-up before athletic activity. Athletic trainers must provide the best possible care for athletes. By reading and interpreting the recent literature, athletic trainers must adapt stretching protocols, especially if a certain type of stretching protocol could potentially be harmful towards the athlete. If dynamic stretching is more effective as a warm-up than static stretching, additional research should be performed to apply validity and reliability to the study to begin 63 implementing a change from solely static stretching to a dynamic warm-up. 64 APPENDIX C Additional Methods 65 APPENDIX C1 Informed Consent Form 66 Informed Consent Form 1. Mark Webber, who is a Graduate Athletic Training Student at California University of Pennsylvania, has requested my participation in a research study at California University of Pennsylvania. The title of the research is, The Effect of Static vs. Dynamic Stretching on Sprint Speed. 2. I have been informed that the purpose of this study is to study the effects of static stretching, dynamic stretching, and a combination of both stretches on sprint speed of physically active individuals. I understand that I must be 18 years of age or older to participate. I understand that I have been asked to participate along with 29 other individuals because I have not sustained a lower extremity injury within the last 6 months, nor do I have any other health conditions that would prevent me from participating in this study. I am also physically active, as defined as participating in moderate to intense exercise at least 3 times a week. I understand that I will be asked to complete a survey related to my physical activity to determine if I meet the definition of physically active for this study. 3. I have been invited to participate in this research project. My participation is voluntary and I can choose to discontinue my participation at any time without penalty or loss of benefits. My participation will involve completing this informed consent form before beginning this study. For the experimental portion of this study, I will be asked to complete three different stretching protocols on three separate days with at least 48 hours separating each test day. I will perform a 5 minute jog at my own pace, then I will be instructed to perform either a static stretching protocol, a dynamic stretching protocol, or a combination of static and dynamic stretching protocol. Following the stretching protocol, I will complete 3 trials of a timed 40 yard sprint. 4. I understand there are foreseeable risks or discomforts to me if I agree to participate in the study. With participation in a research program such as this there is always the potential for unforeseeable risks as well. The possible risks and/or discomforts include possible soreness due to activity. With any intense physical activity, there is a risk of cardiovascular incidents such as cardiac arrest and exacerbation of other health issues. To minimize these health risks I will complete a physical activity readiness questionnaire (PAR-Q) and allow the researchers to obtain information from my CalU physical on file with the Student Health Center. To minimize risks of muscle and joint injury and discomfort the researcher has included a proper warm-up consisting of a 5 minute jog before participating in the performance testing. 5. I understand that, in case of injury, I can expect to receive treatment or care in Hamer Hall’s Athletic Training Facility. This treatment will be provided by the researcher, Mark Webber, under the supervision of the CalU athletic training faculty, all of which can 67 administer emergency care. Additional services needed for prolonged care will be referred to the attending staff at the Downey Garofola Health Services located on campus. 6. There are no feasible alternative procedures available for this study. 7. I understand that the possible benefits of my participation in the research will provide more current research, adding to the existing research, which will contribute to which type of stretching protocol will be the most effective in terms of improving performance as well as decreasing injury in athletics. 8. I understand that the results of the research study may be published but my name or identity will not be revealed. Only aggregate data will be reported. In order to maintain confidentially of my records, Mark Webber will maintain all documents in a secure location on campus and password protect all electronic files so that only the student researcher and research advisor can access the data. Each subject will be given a specific subject number to represent his or her name so as to protect the anonymity of each subject. 9. I have been informed that I will not be compensated for my participation. 10. I have been informed that any questions I have concerning the research study or my participation in it, before or after my consent, will be answered by: Mark C. Webber, ATC STUDENT/PRIMARY RESEARCHER Web2404@calu.edu 774-266-6383 Dr. Thomas West Ph.D., ATC RESEARCH ADVISOR West_t@calu.edu 724-938-5933 11. I understand that written responses may be used in quotations for publication but my identity will remain anonymous. 12. I have read the above information and am electing to participate in this study. The nature, demands, risks, and benefits of the project have been explained to me. I knowingly assume the risks involved, and understand that I may withdraw my consent and discontinue participation at any time without penalty or loss of benefit to myself. In signing this consent form, I am not waiving any legal claims, rights, or remedies. A copy of this consent form will be given to me upon request. 13. This study has been approved by the California University of Pennsylvania Institutional Review Board. 68 14. The IRB approval dates for this project are from: 01/01/12 to 12/31/12. Subject's signature:________________________________ Date:________________ Witness signature:_________________________________ Date:________________ 69 APPENDIX C2 Physical Activity Readiness Questionnaire (PAR-Q) 70 71 Appendix C3 Physical Examination Release Waiver 72 Physical Examination Release Waiver I ______________________________ give the University Health Center permission to provide the researcher (Mark C. Webber) and research advisor (Dr. Thomas West) my physical. I understand that the information gathered by the researcher will be used to determine recommendations my physician has given regarding my physical activity. Student Signature__________________________________ Date: _________ 73 Appendix C4 Physical Activity Survey 74 Physical Activity Survey 1. How many days per week do you partake in moderate to intense exercise? ___days 2. For each of the following activities, please indicate how much time you spend per week. (Note: each activity must be done at a moderate to intense level of exertion) a. Running (road, track, treadmill): _________________ b. Biking _________________ c. Elliptical _________________ d. Stair Climber _________________ e. Weight Training _________________ 75 Appendix C5 Functional Instruments 76 http://nats.us/cm-combines/cm-drills/cm-drills-speed.html 77 Speed Trap II Timer™ http://www.powersystems.com/nav/closeup.aspx?c=19&g=1354# 78 Appendix C6 Stretching Protocols 79 Static Stretching Protocol Stretch Muscles Sets Repetitions Rest Hamstring Stretch Quad Stretch Hamstrings 1 Quadriceps 1 25 s, bilaterally 25 s, bilaterally 25 s, bilaterally 25 s, bilaterally 25 s, bilaterally 25 s, bilaterally 25 s, bilaterally 5 s, bilaterally 5 s, bilaterally 5 s, bilaterally 5 s, bilaterally 5 s, bilaterally 5 s, bilaterally 5 s, bilaterally Hip Flexor Hip Flexors Stretch Adductor Adductors Stretch Abductor Abductors Stretch Gluteal Gluteals Stretch Gastroc/Soleus Gastrocnemius Stretch and Soleus A) B) 1 1 1 1 1 80 C) D) E) F) G) KEY: A) B) C) D) E) F) G) Hamstring Stretch Quadriceps Stretch Adductor Stretch Hip Flexor Stretch Abductor Stretch Gluteal Stretch Gastroc/Soleus Stretch 81 Dynamic Stretching Protocol Stretch High Knees Butt Kicks Lateral Shuffles Russian Walks Walking Lunges Figure Fours Heel to Toe Walks ) C) Muscles Gluteals/Hamstrings Sets 1 Repetitions 40 s. Rest 20 s. Quadriceps/Hip Flexors Abductors/Adductors 1 40 s. 20 s. 1 40 s. 20 s. Hamstrings 1 40 s. 20 s. Hip Flexors 1 40 s. 20 s. Abductors 1 40 s. 20 s. Gastrocnemius/Soleus 1 40 s. 20 s. B) D) 82 E) G) KEY: A) High Knees B) Butt Kicks C) Lateral Shuffles D) Russian Walks E) Walking Lunge F) Figure Four G) Heel to Toe Walk F) 83 Combination Stretching Protocol Stretch Muscles Hamstrin g Stretch Quad Stretch Hamstrings Hip Flexor Stretch Adductor Stretch Hip Flexors High Knees Butt Kicks Lateral Shuffles Gluteals/Hamstring s Quadriceps/Hip Flexors Adductors/Abductor s Quadriceps Adductors Sets Repetition s 1 25 s, bilaterall y 1 25 s, bilaterall y 1 25 s, bilaterall y 1 25 s, bilaterall y 1 40 s. Rest 1 40 s. 20 s. 1 40 s. 20 s. 5 s, bilaterall y 5 s, bilaterall y 5 s, bilaterall y 5 s, bilaterall y 20 s. 84 Appendix C7 Institutional Review Board California University of Pennsylvania 85 86 87 88 89 90 91 92 93 94 95 96 Below are my responses to issues that arose during the IRB review of my proposal(#11032) titled “the effects of static and dynamic stretching on sprint speed.” These changes resulted in a modification of the Informed Consent so it is also attached to this email. Please let me know if any additional information is needed. --Criteria for inclusion in the study are somewhat nonspecific (“physically active” and “moderate to intense lower extremity activity”). Because the research activity (running 40m at maximum speed) is strenuous, a clearer, objective level of physical activity must be defined. Subjects participating in this study must partake in moderate to intense physical activity. Such activity may include running, biking, elliptical, stair climber, and/or weight training. Subjects must participate in this type of exercise at a minimum of three days a week for at least 30 minutes per session. Subjects will complete the attached survey in regards to their physical activity. They must indicate that they engage in one or more of the listed exercises for a minimum total of 30 minutes per session with at least 3 sessions per week to be included in the study. (Physical Activity Survey, attached) The intention is to include individuals that regularly perform moderate to intense exercise that utilizes the lower extremity. These activities would tax the body in ways that would train aerobic and anaerobic systems and result a reduced risk of injury. --As running 40m is an intense anaerobic activity (done 3x) this could be a significant stress on the cardiovascular and musculoskeletal system, along with other potential health implication (e.g. sickling in pts with sickle cell). The sole screening criterion (a question regarding Lower Extremity injury) appears insufficient to minimize risks. A more detailed screening is required (e.g. PARQ – physical activity readiness questionnaire could be a starting point–it is the researcher’s responsibility to decide on an appropriate protocol) along with additional evidence-based information on potential risks given to participants (e.g. risk of cardiovascular incident)—peer reviewed references are needed for this response. I have included a PAR-Q form (attached) for each potential subject to complete to minimize any potential cardiovascular risks. Also, each student must have a physical performed by a physician on file prior to their enrollment at the University. On page four of the physical, there is a question that reads “Recommendations for physical activity (Physical Education, Athletics, etc.)”. The physician checks either unlimited or limited. Any potential subject with “Limited” checked off will be excluded from the study. 97 Subjects will sign a waiver (attached) to allow the University Health Center to provide the researcher with this information. This physical should also be an effective screen for other potential health implications and in combination with the PARQ should adequately screen for cardiovascular risk factors. In relation to the potential risks of a CV incident, Van Camp1 states, “it is estimated an absolute rate of exercise-related death among high school and college athletes of only 1 per 133,000 men and 1 per 769,000 women.” Another study by Borjesson and Pelliccia2 states “The incidence of sudden cardiac death (SCD) among young athletes is estimated to be 1-3 per 100,000 person years, and may be underestimated. The risk of SCD in athletes is higher than in non-athletes because of several factors associated with sports activity that increase the risk in people with an underlying cardiovascular abnormality.” Overall the risks of CV incident is very small, and the stresses of this type of test may create risks lower than those seen in athletes. Still, the researcher will watch the subjects for signs of CV distress throughout the testing session. References: 1. Van Camp, S.P., C.M. Bloor, F.O. Mueller, R.C. Cantu, and H.G. Olson. Nontraumatic sports death in high school and college athletes. Med. Sci. Exerc. 27:641-647, 1995. 2. Borjesson, M., Pelliccia, A. Incidence and etiology of sudden cardiac death in young athletes: an international perspective. British Journal of Sports Medicine. 43(9): 644-648, 2009. --Where will the 40m runs be done (indoors/outdoors). Is there deceleration room? Will weather conditions be a factor? The runs will take place indoors in the Hamer gymnasium. The runs will be run diagonally across the entire gymnasium. The length of the gym is 150 ft and the width is 110 ft. Diagonally, the test will take 120 ft (40 yards) and there is 66 ft for deceleration (roughly 20 yards).There is ample deceleration room. A diagram is provided. --It is not clear what parameters will be measured. A sample data collection sheet should be included in the response. A sample data collection sheet is provided. Each subject’s time, in seconds, will be recorded. The best time will be used for data analysis. 98 Institutional Review Board California University of Pennsylvania Morgan Hall, Room 310 250 University Avenue California, PA 15419 instreviewboard@calu.edu Robert Skwarecki, Ph.D., CCC-SLP,Chair Dear Mark Christopher Webber: Please consider this email as official notification that your proposal titled "The effects of static and dynamic stretching on sprint speed” (Proposal #11-032) has been approved by the California University of Pennsylvania Institutional Review Board as amended. The effective date of the approval is 2-23-2012 and the expiration date is 222-2013. These dates must appear on the consent form . Please note that Federal Policy requires that you notify the IRB promptly regarding any of the following: (1) Any additions or changes in procedures you might wish for your study (additions or changes must be approved by the IRB before they are implemented) (2) Any events that affect the safety or well-being of subjects (3) Any modifications of your study or other responses that are necessitated by any events reported in (2). (4) To continue your research beyond the approval expiration date of 2-22-2013 you must file additional information to be considered for continuing review. Please contact instreviewboard@calu.edu Please notify the Board when data collection is complete. Regards, Robert Skwarecki, Ph.D., CCC-SLP Chair, Institutional Review Board 99 Appendix C8 Data Collection Sheet 100 Sprint Times for the 40 Yard Sprint Subject Static T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. Dynamic T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. Combo T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. T1. T2. T3. 101 REFERENCES 1. Weerapong P, Hume PA, Kolt GS. Stretching: Mechanisms and Benefits for Sport Performance and Injury Prevention. Physical Therapy Reviews. 2004; 9; 189206. 2. Taylor D, Brooks D, Ryan J. Viscoelastic Characteristics of Muscle: Passive Stretching Versus Muscular Contractions. Med Sci Sports Exerc. 1997; 29; 1619-24 3. Kisner C, Colby L. Therapeutic Exercise: Foundations and Techniques. Philadelphia, PA; F.A. Davis Company; 2007. 4. Anderson B, Burke ER. Scientific, Medical and Practical Aspects of Stretching. Clinics in Sports Medicine. 1991; 10; 63-86. 5. Janot JM, Dalleck LC, Reyment C. Pre-Exercise Stretching and Performance. IDEA Fitness Journal. 2007; 4 (2); 44-51. 6. Johansson PH, Lindstrom L, Sundelin G, Lindstrom B. The Effects of Pre-Exercise Stretching on Muscular Soreness, Tenderness and Force Loss Following Heavy Eccentric Exercise. 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Means and Methods of Speed Training, Part I. J Strength Cond Res. 2004; 26 (4); 24-29. 14. Cronin J, Hansen KT. Resisted Sprint Training for the Acceleration Phase of Sprinting. J Strength Cond Res. 2006; 28 (4); 42-51. 15. Harrison AJ, Bourke G. The Effect of Resisted Sprint Training on Speed and Strength Performance in Male Rugby Players. J Strength Cond Res. 2009; 23 (1); 275283. 16. McMillian DJ, Moore JH, Hatler BS, Talor DC. Dynamic vs. Static-Stretching Warm-Up: The Effect on Power and Agility Performance. J Strength Cond Res. 2006; 20 (3); 492-499. 17. Arabaci R. Acute Effects of Differential Stretching Protocols on Physical Performance in Young Soccer Players. NWSA. 2009; 4 (2); 50-63. 18. Faigenbaum AD, Bellucci M, Bernieri A, Bakker B, Hoorens K. Acute Effects of Different Warm-up Protocols on Fitness Performance in Children. J Strength Cond Res. 2005; 19 (2); 376-381. 103 19. Faigenbaum A, et al. Acute Effects of Different WarmUp Protocols on Anaerobic Performance in Teenage Athletes. Pediatr Exerc Sci. 2006; 18 (1); 64-75. 20. Siatras T, Papadopoulos G, Mameletzi D, Gerodimos V, Kellis S. Static and Synamic Acute Stretching Effect on Gymnasts’ Speed in Vaulting. Pediatr Exerc Sci. 2003; 15 (4); 383-391. 21. Fletcher IM, Jones B. The Effect of Different Warm-Up Stretch Protocols on 20 Meter Sprint Performance in Trained Rugby Union Players. J Strength Cond Res. 2004; 18 (4); 885-888. 22. Fletcher IM, Anness R. The Acute Effects of Combined Static and Dynamic Stretch Protocols on Fifty-Meter Sprint Performance in Track-and-Field Athletes. J Strength Cond Res. 2007; 21 (3); 784-787. 23. Kistler BM, Walsh MS, Horn TS, Cox RH. The Acute Effects of Static Stretching on the Sprint Performance of Collegiate Men in the 60- and 100- m Dash after a Dynamic Warm-Up. J Strength Cond Res. 2010; 24 (9); 2280-2284. 24. Winchester JB, Nelson AG, Landin D, Young MA, Schexnayder IC. Static Stretching Impairs Sprint Performance in Collegiate Track-and-Field Athletes. J Strength Cond Res. 2008; 22 (1); 13-18. 25. Nelson AG, Driscoll NM, Landin DK, Young MA, Schexnayder IC. Acute Effects of Passive Muscle Stretching on Sprint Performance. J Sprt Sci. 2005; 23 (5); 449-454. 26. Little T, Williams AG. Effects of Differential Stretching Protocols During Warm-Ups on High-Speed Motor Capacities in Professional Soccer Players. J Strength Cond Res. 2006; 20 (1); 203-207. 27. Knudson DV, Noffal GJ, Bahamonde RE, Bauer JA, Blackwell JR. Stretching Has No Effect on Tennis Serve Performance. J Strength Cond Res. 2004; 18 (3); 654656. 104 ABSTRACT Title: THE EFFECT OF STATIC AND DYNAMIC STRETCHING ON SPRINT SPEED OF THE PHYSICALLY ACTIVE Researcher: Mark C. Webber Advisor: Dr. Thomas F. West Date: May 2012 Research Type: Master’s Thesis Context: Stretching has been widely accepted within the athletic population for decades. Static stretching was once dominant for a preactivity warm-up. However, recent studies have shown that static stretching may lead to an increased risk of injury and also a decrease in performance. There have also been an increasing number of studies identifying the positive effects of dynamic stretching when compared to static stretching. Therefore, there has been a significant shift towards dynamic stretching as part of a pre-activity warm-up. Objective: The purpose of this study was to investigate the effect of three different stretching protocols on the sprint performance of physically active individuals. These three stretching protocols include static stretching, dynamic stretching, and a combination of static and dynamic stretching. Setting: The testing was done in the Hamer Gymnasium on the campus of California University of Pennsylvania. Participants: Sixteen physically active individuals volunteered for this study (11 males, 5 females). Interventions: Each subject completed each of the three stretching protocols on three separate days 105 with 48 hours in between each testing session. Each subject then completed three trials of a 40 yard sprint. Main Outcome Measures: A within subjects repeated measures ANOVA was conducted to analyze the data. The independent variable was the stretching protocol used, which had three levels (Static Stretching Warm-Up Protocol, Dynamic Stretching Warm-Up Protocol, and Combination of Static and Dynamic Stretching Warm-Up Protocol). Results: The repeated measures ANOVA revealed there was a significant effect of warm-up on performance (F 2,30 = .03 p < .05). Follow-up post-hoc testing using protected dependent t tests was utilized. There was a significant difference between the Combination Stretching Protocol (5.575s +/- .496) and the Static Stretching Protocol (5.660s +/.492). Conclusion: According to the literature, it is beneficial to include dynamic stretching prior to physical activity, while static stretching should be avoided. However, the results of this study show that a combination of both static and dynamic stretching is most beneficial for physically active individuals.