Call for Study Papers (Posters)

4th Annual ETSU, Coaches and Sport Science College.

December 18-20, 2009 – Millennium Center, ETSU, Johnson City, Tennessee

The Center for Excellence in Sports Science and Coach Education (CESSCE) will be hosting posters for its fourth annual Coaches College. The subject matter must deal directly or indirectly with the enhancement of competitive athletes.  Posters can deal with advances in coaching, coaching methods, biomechanical, psychological, physiological or sports medicine aspects.

Posters will be accepted on the basis of study summaries submitted by e-mail. The deadline for acceptance is November 15th 2009 (no exceptions).  Summaries should be concise, and contain sections dealing with: purpose/introduction, methods, results and discussion Summaries should be limited to 2-3 pages (12 pt font).  An example is provided below.  Incomplete studies without data will not be accepted.  The summaries will be published on on sportscienceed.com.

Awards will be given in the following categories:

Coaching/Coach Education

1st place - $150

2nd place - $75

Sports Science

1st place - $150

2nd place - $75

Outstanding student Poster- $150

Posters must be up by Friday morning at December 18th at 8:00 am – judging will take place during all breaks – primary authors are expected to stand with their posters during all breaks.

Posters should fit a standard size display: approximately 4 ft x 4 ft. (122 cm x 122 cm)

Judges for the competition

Coaches Education

• Chris Ayres – Physical Education ETSU/ Director of ETSU IRB, former Executive  Director of TAHPERD, Head KLSS Department, ETSU


• Dr. Andy Dotterweich– Assistant Professor, KLSS, ETSU


• Dan Wathen – Head Trainer (Emeritus) – Youngstown State University

Sports Science

• Dr. Inigo Mujika- Associate Professor of Physiology, University of the Basque Country.


• Dr. Bill Sands –Professor, Director of Exercise and sport Science at Mesa State University, Grand Junction, CO


• Clive Brewer – UKSCA, Coaches education development, SportScotland, Scotland, UK


• Travis Triplett – Master (or is it mistress) of Ceremonies at Banquet.

Example

RELATIONSHIP BETWEEN ISOMETRIC FORCE CHARACTERISTICS AND THE DIFFERENCE IN UN-WEIGHTED AND WEIGHTED VERTICAL JUMP HEIGHT

Jenna M. Kraska, Michael W. Ramsey, G. Gregory Haff, Nate Fethke, Ann M. Kinser, William A. Sands, Keith Painter, Margaret E. Stone and Michael H. Stone

Sports Performance Enhancement Consortium

East Tennessee State University

Johnson City, TN, USA, 37614

Introduction: Weighted and unweighted jumps may provide insights into both mechanistic and practical aspects of explosive performance. So, for strength and conditioning professionals, the monitoring of vertical jump height and jump height responses under various loading conditions is easy to perform and may be a practical assessment tool that is specific to the characteristics observed in sport. Therefore, the purpose of the current investigation was to examine the relationships between isometric force time-curve characteristics and markers of unloaded and loaded vertical jump performance. A primary purpose was to examine the relationships of maximal strength to these characteristics.

Methods: Forty-one female and twenty-two male USA Collegiate Division I athletes (n = 63) active in track and field, tennis, softball, soccer, and volleyball participated in the study. Athletes read and signed written informed consent documents pertaining to the long-term athlete monitoring program and all testing procedures in accordance with the guidelines of East Tennessee State University’s Institutional Review Board.

Athlete height was measured using a stadiometer and recorded to the nearest 0.1 cm. Body mass was determined using an electronic scale and body composition was determined with, air displacement plethsmography (BodPod, Life Measurement Incorporated, Concord, CA). Vertical jump height was derived from flight time using a force plate. Maximum strength characteristics were measured by an isometric mid-thigh pull.  Isometric peak force (IPF), force at 50, 90 250 ms and rate of force development (IRFD) were measured by force-time curve analyses using customized signal processing software (LabView, National Instruments, Austin, TX). Reliabilities for these measures were excellent (ICCα ≥ 0.88 – 0.99)

Relationships between variables were assessed using a Pearson correlation procedure. Additionally a subgroup (n = 6) of the strongest five percent of males and females (3 males + 3 females) were compared to a subgroup (n = 6) of the weakest five percent males and females (3 males + 3 females). Athletes were placed into weak or strong groups according to their allometrically scaled isometric peak force values (IPFa). Independent samples t-Tests were used to assess differences between means (strong group IPFa = 232.4 ± 28.4 N/kg 0.67, weak IPFa = 123.18 ± 18.87 N/kg 0.67, (p ≤ 0.05). Due to the large number of pair-wise comparisons between groups, the Holm’s Sequential Bonferroni method was used to control for type I errors. Cohen’s effect sizes (d) were also calculated. The experimental design is shown in Figure 1:

Results:  Athletes (n = 63) were 19.9 ± 1.3 yrs.; 172.8 ± 7.7 cm in height and their body mass was 72.9 ±19.6 kg.  There was a very strong correlation between IPF and IRFD (r = 0.88, p ≤ 0.05) agreeing with previous literature (1, 2). IPF showed moderate to strong correlations with F50 (r = 0.85), F90 (r = 0.42) and F250 (r = 0.93). Correlations of IPF and percent decrements in jump height ranged from moderate to strong negative correlations indicating stronger athletes lost less height. Compared to weak athletes, strong athletes had greater values for all force measures and for IRFD (p < 0.5). Differences between strong and weak groups showed that stronger athletes jumped higher (SJ 0kg = 30.8 ± 9.7 vs 23.7 ± 4.9 cm, p ≤ 0.5, d = 0.92; CMJ 0 kg = 33.5 ± 10.8 vs 28.3 ± 6.3 p ≤ 0.05, d = 0.60; SJ 20 kg = 25.4 ± 8.3 vs 16.7± 4.8 cm, p ≤ 0.05, d = 1.28; CMJ 20kg = 27.6 ± 8.6 vs 18.7 ± 5.3, p ≤, d = 1.24). The strong group had smaller decrements (SJ = 17.8 ± 3.4 vs30.4 ± 7.8 %, p ≤ 0.5, d = 2.10; CMJ =17.4 % ± 4.8 vs 34.5 ± 7.8 %, p < 0.05, d = 2.65).

Discussion: Three important findings were associated with the current investigation: First, strong relationships were observed between maximum strength (IPF), IRFD and F50, F90, F250. It is unclear exactly why increased maximum strength is associated with increased RFD, but it may be related to alterations in the H-reflex. Second was the association of maximum strength characteristics (e.g. IPF, IRFD) with jump capabilities. Additionally, assuming that the isometric measures are indicative of striking, sprinting and jumping (i.e. force at 50, 90, and 250 ms) then stronger athletes measured in this manner can produce superior results in these activities.  The third important finding was the observation that stronger athletes have smaller decrements in vertical jump heights associated with weighted jumps compared to weaker athletes. There are several potential underlying reasons for these observations. Training studies have shown increases in neural drive (IRFD) associated adaptations in contractile strength of skeletal muscle (2). Furthermore, athletes that are found to be more explosive, which may be strongly related to their nervous system capabilities, are often found to possess high levels of strength. Thus maximum strength appears to be an important underlying mechanism that influences both un-weighted and weighted jumping and by extrapolation, explosive exercises.

References:

1. Aagaard P, Simonsen EB, Andersen JL, Magnusson P, Dyhre-Poulsen P. Increased rate of force development and neural drive of human skeletal muscle following resistance training. J Appl Physiol 2002 October: 93(4):1318-26.

2.. Stone MH, Sanborn K, O'Bryant HS et al. Maximum strength-power-performance relationships in collegiate throwers. J Strength Cond Res 2003 November: 17(4):739-45.