Целью настоящего исследования было оценить, является ли использование инфракрасных тепловых камер является правильным инструментом для выявления и количественной оценки боли в мышцах после тренировки.
Delayed onset muscle soreness (DOMS), also known as exercise induced muscle damage (EIMD), is commonly experienced in individuals who have been physically inactive for prolonged periods of time, and begin with an unexpected bout of exercise1-4, but can also occur in athletes who exercise beyond their normal limits of training5. The symptoms associated with this painful phenomenon can range from slight muscle tenderness, to severe debilitating pain1,3,5. The intensity of these symptoms and the related discomfort increases within the first 24 hours following the termination of the exercise, and peaks between 24 to 72 hours post exercise1,3. For this reason, DOMS is one of the most common recurrent forms of sports injury that can affect an individual’s performance, and become intimidating for many1,4.
For the last 3 decades, the DOMS phenomenon has gained a considerable amount of interest amongst researchers and specialists in exercise physiology, sports, and rehabilitation fields6. There has been a variety of published studies investigating this painful occurrence in regards to its underlying mechanisms, treatment interventions, and preventive strategies1-5,7-12. However, it is evident from the literature that DOMS is not an easy pathology to quantify, as there is a wide amount of variability between the measurement tools and methods used to quantify this condition6. It is obvious that no agreement has been made on one best evaluation measure for DOMS, which makes it difficult to verify whether a specific intervention really helps in decreasing the symptoms associated with this type of soreness or not. Thus, DOMS can be seen as somewhat ambiguous, because many studies depend on measuring soreness using a visual analog scale (VAS)10,13-15, which is a subjective rather than an objective measure. Even though needle biopsies of the muscle, and blood levels of myofibre proteins might be considered a gold standard to some6, large variations in some of these blood proteins have been documented 6,16, in addition to the high risks sometimes associated with invasive techniques.
Therefore, in the current investigation, we tested a thermal infra-red (IR) imaging technique of the skin above the exercised muscle to detect the associated muscle soreness. Infra-red thermography has been used, and found to be successful in detecting different types of diseases and infections since the 1950’s17. But surprisingly, near to nothing has been done on DOMS and changes in skin temperature. The main purpose of this investigation was to examine changes in DOMS using this safe and non-invasive technique.
Основная цель данного исследования заключалась в оценке полезности тепловых ИК-изображений для обнаружения и измерения боли в мышцах после физических нагрузок, и наши результаты показывают, что ИК-изображения могут быть действительны технику для обнаружения DOMS, особенно в течение пе…
The authors have nothing to disclose.
Мы хотим выразить признательность контракта (WS1763368) от Pfizer Pharmaceuticals за поддержку в этой работе. Мы также хотели бы поблагодарить Саудовской Аравии Министерства высшего образования (Мохэ) за их поддержку.
Name of the Device | Company | Catalogue number | Comments |
Infra-Red Thermal Camera | FLIR | FLIR SC660 | |
Thermal Infra-Red Analysis Software | ThermoVision ExaminIR | Software Version 1.10.2 | |
Bioelectric Amplifier Module | BioPac | DA100C | The DA100C provides variable gain settings, and adjustable voltage references. |
Analog to Digital Converter Module | BioPac | MP100 | |
Automated enzyme Immunoassay Analyzer | TOSOH | AIA -360 | This device was used to analyze the blood samples, and obtain the myoglobin readings. |