Mechanical Demands of the Hang Power Clean and Jump Shrug: A Joint-Level Perspective

Kipp, Kristof; Malloy, Philip; Smith, Jordan C; Giordanelli, Matthew D.; Kiely, Michael T.; Geiser, Christopher; Suchomel, Timothy J.

doi:10.1519/jsc.0000000000001636

Cited by 31 publications

(53 citation statements)

References 19 publications

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“…Research investigating the optimal load for weightlifting pulling derivatives is limited because of the lack of criteria that indicates a successful repetition (100). However, several studies have suggested that lighter loads (i.e., 30-45% 1RM hang power clean) may optimize training stimuli for the jump shrug (60,92,(102)(103)(104)(105) and hang high pull (94,102,104) 33-35,73) may produce the optimal training stimulus for velocity and power adaptations during the clean/snatch pull from the floor. Practitioners should however consider that the optimal load for power production may be specific to the joint, athlete plus load system, or the bar (66), may be altered based on the relative strength of the athlete (87), and may be impacted by movement pattern and the fatigue status of the athlete Strength and Conditioning Journal | www.nsca-scj.com (54).…”

Section: Speed-strengthmentioning

confidence: 99%

“…Although previous research supports the notion that weightlifting catching derivatives may train an athlete's ability to "absorb" a load during impact activities (68), more recent studies indicate that weightlifting pulling derivatives that exclude the catch phase may produce a similar or greater load absorption stimulus (i.e., loading work, mean force, and duration) following the second pull compared with weightlifting catching derivatives (17,99). Moreover, further research has demonstrated that weightlifting pulling derivatives produce comparable (11,12) or greater (60,102,104,105) force, velocity, and power characteristics during the second pull compared with weightlifting movements that include a catch element. Although the complete removal of weightlifting catching derivatives is not being suggested, the integration of weightlifting pulling derivatives into resistance training programs should be considered for the comprehensive development of an athlete's forcevelocity profile, as elimination of the catch phase permits the use of greater loads (i.e., greater forces) (14,16,39) and potentially greater velocities (95,101).…”

mentioning

confidence: 99%

“…The placement of the jump shrug and hang high pull on the force-velocity curve is supported by previous research demonstrating that the jump shrug (104,105) and the hang high pull (104) produced higher velocities compared with the hang power clean. Moreover, previous research also indicates that these exercises may be best prescribed using lighter loads to maximize power and velocity (60,92,94,(102)(103)(104)(105). Additional research also supports the placement of the power clean, power clean from the knee, and midthigh power clean based on the 1RM (i.e., greater force or less force) that may be achieved for each exercise (56).…”

mentioning

confidence: 99%

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Enhancing the Force-Velocity Profile of Athletes Using Weightlifting Derivatives

Suchomel

Comfort

Lake

2017

Strength &Amp; Conditioning Journal

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100

127

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WEIGHTLIFTING MOVEMENTS AND THEIR DERIVATIVES MAY BE IMPLEMENTED IN A SEQUENCED PROGRESSION THROUGHOUT THE TRAINING YEAR TO OPTIMIZE THE DEVELOPMENT OF AN ATHLETE'S STRENGTH, RATE OF FORCE DEVELOPMENT, AND POWER OUTPUT. WEIGHTLIFTING MOVEMENTS AND THEIR DERIVATIVES CAN BE PROGRAMMED EFFECTIVELY BY CONSIDERING THEIR FORCE–VELOCITY CHARACTERISTICS AND PHYSIOLOGICAL UNDERPINNINGS TO MEET THE SPECIFIC TRAINING GOALS OF RESISTANCE TRAINING PHASES IN ACCORDANCE WITH THE TYPICAL APPLICATION OF PERIODIZED TRAINING PROGRAMS.

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Section: Speed-strengthmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Enhancing the Force-Velocity Profile of Athletes Using Weightlifting Derivatives

Suchomel

Comfort

Lake

2017

Strength &Amp; Conditioning Journal

Self Cite

100

127

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“…Interestingly, power production was higher in the MTP from 30-70% BM when compared to HPC, but at 80-90% BM this shifted toward HPC prevalence over MTP. As stated before, there are several factors such as rate of force development (6), impulse (6,23), propulsion (34) and joint internal power output (20) that contribute to effective levels of power production. That reinforces the idea of prescribing not only the exercises that work the same musculature/joints but also the ones that are more similar in nature with sport-specific moves, so the athlete can enhance performance more effectively.…”

Section: Optimal Load Based On Bm In Different Weightlifting Derivativesmentioning

confidence: 99%

“…Consequently, the strategy that has largely been used to determine the training load for these exercises is using percentages of the PC or HPC (6,27,33). However, the application of this method requires the individual to become very proficient in a more complex exercise to determine the training load of less complex exercises (5,20,34).…”

Section: Introductionmentioning

confidence: 99%

Body Mass As The Optimal Load Predictor For Power Clean Variations: A Practical Approach

Santos¹

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The purpose of this study was to identify the optimal load of the Hang Power Clean (HPC), Hang High Pull (HHP), and Mid-thigh Clean Pull (MTP) based on a relative percentage of the subjects' body mass (BM). Fifteen males with experience in weightlifting (age: 21.8 ± 1.9 years; BM: 83.2 ± 9.0 kg; height: 175.4 ± 6.0 cm; 1-repetition maximum [1RM]: 93.0 ± 12.7 kg;1RM to BM ratio: 1.12 ± 0.13) performed HPC, HHP, and MTP at intensities of 30, 40, 50, 60, 70, 80, and 90% BM. Kinematic data were collected through a 16-camera infrared motion capture system and processed based on a three-dimensional lower-extremity model. Kinetic data were collected from two force plates. Peak power was found at 80, 80, and 90% BM for HPC, HHP, and MTP, respectively. Highest peak power output was found during the HHP for all intensities when compared to HPC and MTP. Power production was higher in the MTP from 30-70% BM when compared to HPC, but at 80-90% BM this shifted toward HPC prevalence over MTP. Results of the present study indicate that relative percentages of body mass presented as a reliable alternative for prescribing loads for the HPC, HHP, and MTP for healthy males with experience in resistance training. This information is relevant for load prescription for exercises without the catch phase (HHP, MTP) in which trainers and coaches rely on 1RM tests in exercises with more technical complexity such as the power clean (PC) and HPC.

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The Importance of Muscular Strength: Training Considerations

et al. 2018

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This review covers underlying physiological characteristics and training considerations that may affect muscular strength including improving maximal force expression and time-limited force expression. Strength is underpinned by a combination of morphological and neural factors including muscle cross-sectional area and architecture, musculotendinous stiffness, motor unit recruitment, rate coding, motor unit synchronization, and neuromuscular inhibition. Although single- and multi-targeted block periodization models may produce the greatest strength-power benefits, concepts within each model must be considered within the limitations of the sport, athletes, and schedules. Bilateral training, eccentric training and accentuated eccentric loading, and variable resistance training may produce the greatest comprehensive strength adaptations. Bodyweight exercise, isolation exercises, plyometric exercise, unilateral exercise, and kettlebell training may be limited in their potential to improve maximal strength but are still relevant to strength development by challenging time-limited force expression and differentially challenging motor demands. Training to failure may not be necessary to improve maximum muscular strength and is likely not necessary for maximum gains in strength. Indeed, programming that combines heavy and light loads may improve strength and underpin other strength-power characteristics. Multiple sets appear to produce superior training benefits compared to single sets; however, an athlete's training status and the dose-response relationship must be considered. While 2- to 5-min interset rest intervals may produce the greatest strength-power benefits, rest interval length may vary based an athlete's training age, fiber type, and genetics. Weaker athletes should focus on developing strength before emphasizing power-type training. Stronger athletes may begin to emphasize power-type training while maintaining/improving their strength. Future research should investigate how best to implement accentuated eccentric loading and variable resistance training and examine how initial strength affects an athlete's ability to improve their performance following various training methods.

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Mechanical Demands of the Hang Power Clean and Jump Shrug: A Joint-Level Perspective

Cited by 31 publications

References 19 publications

Enhancing the Force-Velocity Profile of Athletes Using Weightlifting Derivatives

Enhancing the Force-Velocity Profile of Athletes Using Weightlifting Derivatives

Body Mass As The Optimal Load Predictor For Power Clean Variations: A Practical Approach

The Importance of Muscular Strength: Training Considerations

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