Athletes in field and court sports require reactive agility—they must accelerate, decelerate, and change direction in a constantly changing environment. These requirements result in technical differences between sprinting in a field or court sport and sprinting the 100-m.

Learn how to use sprinting as a means of screening athletes for power, strength, range of motion, and coordination. In this session from the NSCA’s 2018 National Conference, Derek Hansen also identifies appropriate sprinting and running mechanics for optimizing performance and minimizing injury, and outlines a process for using sprinting as a return-to-play modality for soft-tissue and joint injuries.

Acceleration is the rate of change in velocity, so this phase of sprinting is critical for changing directions as rapidly and efficiently as possible. Optimal technique for linear sprinting in the acceleration phase involves four factors that maximize stride length and frequency.

Psyching up can be an effective technique for improving confidence and getting an individual ready for a sporting performance. This infographic shows that psyching up can affect the performance of short-distance sprinting.

The importance of sprinting in many sports has resulted in the search for the most appropriate training methods to improve sprint performance. Authors of recent reviews conclude that resistance training is an effective means to improve sprint performance. Others, however, have reported that resistance training is not as effective as simply engaging in sprint training.

This infographic describes the type of muscle activation three exercises elicited and their relationship to maximal sprinting performance.

This book excerpt is an overview of the fundamentals to sprinting mechanics and technique. It also covers starting, acceleration, drive phase, recovery phase, and deceleration.

Sprinting is a key component for many individual and team sports. Therefore, to enhance sprint performance, various training methods are widely used by coaches and practitioners, including maximum sprint speed and resisted sprint training. Resisted sprinting with sled towing is a method that has recently received considerable attention from the sport science community. However, to date, no consensus exists regarding its acute and chronic effects in team sport athletes. This narrative review aimed to (a) review and analyze the mechanics of sprinting under unresisted and resisted conditions with a specific focus on team sport disciplines; (b) provide a thorough and applied discussion on the importance of considering acute and chronic effects of sled loading on technique, electromyographic activity, and force production, as well as on the role of muscle architecture and neural factors in sled training; (c) analyze the effects of increasing sled loads during acceleration and maximum velocity phases on contact and flight phases, while concomitantly examining kinetic, kinematic, and neuromuscular aspects, because all these factors affect each other and cannot be properly understood in isolation.

The purpose of this article is to describe the cause of hamstring injuries in sprinters and present a biomechanical intervention, or drill, that can be used to prevent hamstring injuries while transitioning sprint athletes toward the utilization of frontside mechanics.

This study assessed the performance effects of a novel short-term and highly accessible training protocol based on maximal shuttle runs in the field.