Ignite Creation Date:
2024-07-17 @ 11:18 AM
Last Modification Date:
2024-10-26 @ 3:32 PM
Study NCT ID:
NCT06464120
Status:
COMPLETED
Last Update Posted:
2024-06-18
First Post:
2024-06-12
Brief Title:
Investigating the Post-Activation Performance Enhancement Effects on Skeletal Muscles Under Varied Loading Conditions
Sponsor:
Universiti Putra Malaysia
Organization:
Universiti Putra Malaysia
Study Overview
Official Title:
Investigating the Post-Activation Performance Enhancement Effects on Strength-trained Athletes Under Varied Loading Conditions A Time-domain Features Perspective
Status:
COMPLETED
Status Verified Date:
2024-07
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
With the advancement of sports science Post-Activation Potentiation PAP has become a focal point of research garnering significant attention for its underlying physiological mechanisms Current studies suggest three primary mechanisms 1 phosphorylation of myosin regulatory light chains RLCs 2 increased recruitment of high-threshold motor units and 3 a reduction in sarcomere length heterogeneity within muscle fibers due to pre-stimulation Liu Li 2017 These mechanisms collectively contribute to an effect known as Post-Activation Performance Enhancement PAPE which significantly enhances muscle strength and explosiveness shortly after activation Blazevich Babault 2019
During the activation process of motor units with increasing loads low-threshold motor units are recruited first followed by high-threshold motor units As the load increases the root mean square RMS value increases linearly further promoting the overlap of motor unit potentials and the rise in RMS values This overlap in activation timing among adjacent motor units results in greater overall muscle force output Liu 2008 Tian 2009 The significance of this lies in the fact that as the degree of muscle activation increases especially under incremental loads the muscles ability to adapt to subsequent strength or explosive tasks may be enhanced
In competitive sports optimizing the relationship between warm-up and performance is crucial Research indicates that the duration of PAPE varies with individual differences training type intensity and recovery intervals The characteristics of the PAPE effect also differ Additionally following constant loads the enhancement and decay rates of performance in PAPE show varying rates at different times and these rates do not exhibit a symmetrical linear change in absolute value Liang M 2020 Guo W et al 2018 Liu R and Li Q 2017 The competition pace in sports demands precise modulation of performance enhancement rates after activation and athletes can leverage these characteristics by selecting appropriate loading forms to trigger PAPE at critical moments in competition To explore the enhancement or decay rates of performance over different time domains our research team designed a protocol consisting of incremental loads
During the activation process of motor units with increasing loads low-threshold motor units are recruited first followed by high-threshold motor units As the load increases the root mean square RMS value increases linearly further promoting the overlap of motor unit potentials and the rise in RMS values This overlap in activation timing among adjacent motor units results in greater overall muscle force output Liu 2008 Tian 2009 The significance of this lies in the fact that as the degree of muscle activation increases especially under incremental loads the muscles ability to adapt to subsequent strength or explosive tasks may be enhanced
In competitive sports optimizing the relationship between warm-up and performance is crucial Research indicates that the duration of PAPE varies with individual differences training type intensity and recovery intervals The characteristics of the PAPE effect also differ Additionally following constant loads the enhancement and decay rates of performance in PAPE show varying rates at different times and these rates do not exhibit a symmetrical linear change in absolute value Liang M 2020 Guo W et al 2018 Liu R and Li Q 2017 The competition pace in sports demands precise modulation of performance enhancement rates after activation and athletes can leverage these characteristics by selecting appropriate loading forms to trigger PAPE at critical moments in competition To explore the enhancement or decay rates of performance over different time domains our research team designed a protocol consisting of incremental loads
Detailed Description:
First participants underwent a squat 1-RM test using the NSCA testing protocol The induction exercise was barbell-loaded squats In the constant load group the stimulation intensity was set at 90 of the 1-RM with one set of four repetitions of barbell half-squat jumps In the incremental load group the stimulation intensities were set at 5RM 4RM 3RM and 2RM with one set of one repetition of barbell half-squat jumps for each load intensity Both the 1-RM test and squat induction exercises were conducted using a Smith machine and protective personnel were present on both sides The testing movement involved static half-squat jumps that aimed to enhance the stability of the test and reduce interference from arm swinging The static half-squat jump required participants to stand with their feet shoulder-width apart on the force plate hands on hips and knees flexed to a semi-movement range and they had to maintain the position for one to two seconds Following this participants exerted maximal effort to jump upward with no visually noticeable downward squatting during takeoff before naturally descending and maintaining the position for another one to two seconds Throughout the entire process both feet were to remain within the force plate area
Experimental procedure The participants began with a 10-minute slow jog and dynamic lower-limb stretches As a baseline the participants dynamic data for unloaded static half-squat jumps were collected after a 5-minute rest Following another 5-minute rest the constant load group underwent one set of four half-squat jump inductions at an intensity of 90 1-RM The incremental load group underwent inductions at each load intensity with one set of barbell half-squat jump exercises for each intensity The participants received verbal cues and encouragement for each repetition Dynamic data for static half-squat jumps were collected at 15 seconds 3 minutes 6 minutes 9 minutes and 12 minutes after the end of each exercise session At each time point two valid repetitions were collected with verbal cues and encouragement provided to the participants for each repetition Each set of two half-squat jumps did not exceed 10 seconds The interval between static half-squat jump testing and 1-RM testing was greater than 48 hours
Experimental procedure The participants began with a 10-minute slow jog and dynamic lower-limb stretches As a baseline the participants dynamic data for unloaded static half-squat jumps were collected after a 5-minute rest Following another 5-minute rest the constant load group underwent one set of four half-squat jump inductions at an intensity of 90 1-RM The incremental load group underwent inductions at each load intensity with one set of barbell half-squat jump exercises for each intensity The participants received verbal cues and encouragement for each repetition Dynamic data for static half-squat jumps were collected at 15 seconds 3 minutes 6 minutes 9 minutes and 12 minutes after the end of each exercise session At each time point two valid repetitions were collected with verbal cues and encouragement provided to the participants for each repetition Each set of two half-squat jumps did not exceed 10 seconds The interval between static half-squat jump testing and 1-RM testing was greater than 48 hours
Study Oversight
Has Oversight DMC:
None
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?:
None