Ms. Fatemeh Safari, Ms. Reyhane Rafie, Ms. Hanieh Golshadi, Mr. Hamed Rezaei Adriani, Dr Mojtaba Babaei Khorzoghi, Dr Mohsen Shanbeh,
Volume 0, Issue 0 (11-2019)
Abstract
Sports injuries hold significant importance due to several reasons such as injury types and their nature, identifying risk factors associated with these injuries, the effectiveness of sports equipment, and individual variations in injury occurrence. Common among athletes, these injuries range from sprains and strains to fractures, significantly impacting their performance. One of the methods to prevent all kinds of injuries is the use of smart textiles and wearable technologies. Smart textiles refer to textile-based structures that have the ability to sense or react to various stimuli, including physiological variables of the body. These structures play a significant role in monitoring the performance of athletes in various disciplines and improving sports injuries, both among athletes and at the community level. This study reviews the definitions, nature, and types of sports injuries, and the principles and application of smart textiles in sports. Moreover, heat-generating smart textiles as a method of improving and treating sports injuries are explained. Information was collected through searches on Google Scholar and Semantic Scholar using keywords such as "sports injuries," "smart textiles," "wearable technology," and "heat-generating textiles" within the time frame of 2000-2023. The review followed a systematic approach, including defining the topic, selecting relevant databases, and using a combination of keywords to gather comprehensive and representative sources. The most significant findings from the reviewed articles include the effectiveness of heat therapy in reducing muscle soreness and promoting recovery, the role of smart textiles in injury improvement, and the advancements in wearable technology for monitoring and improving athletic performance. Flexibility, air permeability, and temperature control were among the features of textile-based structures designed and investigated in various studies. Previous studies also showed that the textile structure and the type of conductive materials, such as conductive polymers and conductive yarns, affect its heat generation capability and uniformity. Moreover, the use of conductive yarns showed more technical advantages, such as higher uniformity in heat generation compared to other proposed methods.
Mahdi Safari Bak, Reza Baharifard, Amin Gandomkar,
Volume 18, Issue 20 (11-2020)
Abstract
The chronic ankle sprain is the most common injury among athletes, and using the tape is one way to prevent it. The aim of the present study was to determine the effect of the Kinsio-tape on the compressive and shear mechanical forces of the ankle joint during single-leg jump landing. 12 subjects were selected based on inclusion criteria. Subjects were asked to perform landing after jump in the conditions of with Kinsio-tape and barefoot, with the injured leg. The peak and mean compressive and shear forces of ankle joint were calculated in MATLAB software. Paired t-test was used to test the hypotheses (P≤0.05). There is no significant difference in all variables between two condition of landing with barefoot (mean of shear force= 0/05 ± 0/01, peak of shear force= 0/85 ± 0/06, mean of compressive force= 0/39 ± 0/02, peak of compressive force= 4/41 ± 0/22) and with Kinsio tape (mean of shear force= 0/05 ± 0/01, peak of shear force= 0/82 ± 0/06, mean of compressive force= 0/38 ± 0/03, peak of compressive force= 4/43 ± 0/28) (P>0.05). Since the use of the Kinsio-tape did not make a significant difference in the variables, it cannot be suggested as a safe prescription to protect ankle joint from compressive and shear mechanical forces in volleyball players.
