Sports Genetic Testing in Salem

At Valli Orthopaedic and Sports Hospital, we perform genetic tests for athletes to acquire data for planning the most suitable type of physical activity and the most appropriate diet plan for each practitioner’s specific requirements, whether in professional or leisure exercise to enhance their sports performance.

Genetic Testing Centre in salem

At Valli Orthopaedic and Sports Hospital, we perform genetic tests for athletes to acquire data for planning the most suitable type of physical activity and the most appropriate diet plan for each practitioner’s specific requirements, whether in professional or leisure exercise to enhance their sports performance.
Gene fitness: Genes play a significant part in defining your athletic ability and fitness level. Recent studies have confirmed that a lot of our genes influence how well we can do demanding physical activities. Inheritance of favourable genetic components is more commonly observed in athletes or fitness professionals depending on the type of exercise or sports activity they perform. The body’s capacity for endurance during an exercise activity, as well as the time and pace at which fitness gains can be made, are all determined by genetic makeup. Based on your genetic evaluation, we may choose a fitness regimen for you that will suit you best and be the most beneficial.

The following are the traits that we evaluate in genetic testing, Salem:

  • Aerobic Capacity: Aerobic capacity is described as our body’s maximum capacity to transport and use oxygen during exercise. During exercise, oxygen is used to break down fuel stores for energy production, which raises its demand. Sufficient aerobic capacity is required for a comfortable workout. Numerous genes control our ability to exercise, and as a result, they play a significant part in determining how fit we are. During gene testing, we analyse genes that are involved in cellular oxygen supply and utilisation.
  • Anaerobic Capacity: The total quantity of energy available from anaerobic energy systems is known as anaerobic capacity. Increased anaerobic capacity will allow you to absorb more lactate quickly, produce and utilise more anaerobic enzymes, and continue converting body resources into readily usable energy.
  • Endurance: Endurance is the body’s ability to use oxygen for energy production and maintain it for an extended period of time during physical activity. A person with a high endurance capacity can engage in mild to moderate-intensity activities for a longer period with little to no discomfort from exhaustion and breathlessness.
  • Power: Power measures the sudden burst of energy experienced during high-intensity activity. The ability of blood vessels to constrict and increase the efficiency of oxygen utilisation is also essential for power. We examine genes that influence the percentage distribution of muscle fibres and their ability to exert maximum power in a short period of time.
  • Flexibility: Flexibility is crucial for fitness since it enhances athletic and exercise performance. Additionally, it increases your degree of comfort when performing regular tasks like bending, walking, and lifting. We examine the genes that might influence your performance and flexibility by affecting the structure of your ligaments and tendons.
  • Muscle Fatigue and Lactate Threshold: When muscles obtain energy during physical exercise, there is a possibility of lactate accumulating, which is a main factor of muscle fatigue. Apart from this, increased inflammation caused by exercise and a lack of flexibility are two more factors that contribute to muscle weariness. Your ability to resist muscular exhaustion determines how long and how hard you can exercise.
  • Muscle Injury: The risk of tendinopathy and muscle injury is highest in athletes and runners who put stress on the Achilles tendon. The Achilles tendon joins your calf muscles to your heel bone. Individuals with specific genotypes are more prone to injury than others, putting them at a higher risk of tendinopathy and other muscular ailments.
  • Injury Repair: Our immune systems improve our resistance to infection, hasten the healing process after exterior injuries, and even reduce the consequences of autoimmune illnesses. Exercise can cause inflammation, which normally goes away once our bodies have adapted to the physical stress. The rate at which exercise-induced inflammation decreases or resumes at the basal level determines the length of recovery periods between exercises. We examine the genes that impact how effectively muscles heal from exercise-induced damage.
  • Exercise and Fat Loss: Exercise can reduce fat levels and help to regulate body functions. Regular exercise promotes weight loss by improving metabolism and fatty acid oxidation. During exercise, the body can use oxidised fatty acids as a fuel source in addition to glucose. Genes have a significant impact on how effectively people burn fat after exercise. However, the influence of carbohydrate and fat metabolism on weight loss response to exercise is uncertain.Â