{"id":27,"date":"2022-04-30T18:05:54","date_gmt":"2022-04-30T22:05:54","guid":{"rendered":"https:\/\/pressbooks.bccampus.ca\/capalan\/?post_type=chapter&p=27"},"modified":"2022-09-23T15:30:34","modified_gmt":"2022-09-23T19:30:34","slug":"twitch-interpolaiton-techniques","status":"publish","type":"chapter","link":"https:\/\/pressbooks.bccampus.ca\/capalan\/chapter\/twitch-interpolaiton-techniques\/","title":{"raw":"Twitch Interpolaiton Techniques","rendered":"Twitch Interpolaiton Techniques"},"content":{"raw":"Recall that nerves carry information throughout the body in the form of electrical signals called action potentials.\u00a0 These signals are what cause our muscles to contract, our heart to beat, our diaphragm to draw air into our lungs; whether we are consciously aware of it or not, essentially everything that happens in the body happens because the nervous (and endocrine) system tells it to!\r\n\r\nWe have the ability to \u2018tap in\u2019 to this internal electrical messaging system through external methods. By administering an external stimulation to the nerve, we can induce an artificial response in the effector, without involving the central nervous system.\r\n\r\nWhen the effector is a skeletal muscle, we can see the result of this stimulation as a muscle twitch.\u00a0 If the electrical stimulation is low, only a few motor units with be recruited and we will see a small twitch in the muscle.\r\n\r\nAs the amplitude of the stimulation increases, more and more motor units are recruited and the resultant twitch will get larger until a maximum is reached, however the maximum induced by the twitch is well below that which can be achieved through voluntary contraction.\r\n\r\n[caption id=\"attachment_71\" align=\"alignright\" width=\"300\"]\"\" (Image retrieved from commons wiki)[\/caption]\r\n\r\nScientists primary use muscle twitch to assess Voluntary Activation (VA).\r\n\r\nThis is a way for researchers to know if a human muscle is fully activated (ie-maximal recruitment has occurred) during an attempted maximal voluntary effort (Hales & Gandevia, 1988).\r\n\r\nWhy is this important?\u00a0 Well let\u2019s say you wanted to examine the effect of a fatiguing contraction on the gastrocnemii.\r\n\r\nYou would collect a baseline Maximal Voluntary Contraction (MVC) by having the subject perform plantar flexion against a force plate and record the result.\r\n\r\nThen you would ask them to do submaximal fatiguing plantar flexion contractions, then repeat the MVC.\u00a0 We would hypothesize that the MVC would decrease after the subject was fatigued, but what if the subject wasn\u2019t fatigued and the second time around they just didn\u2019t try as hard during the MVC? We would still see a decrease in the data, but it wouldn\u2019t be due to the intervention!\r\n\r\n[caption id=\"attachment_72\" align=\"alignleft\" width=\"300\"]\"\" (Jowko et al., 2019)[\/caption]\r\n\r\nTo prevent this, the researchers will use the twitch interpolation technique to assess voluntary activation.\r\n\r\nEssentially a stimulation is applied to a nerve while the muscle it stimulates is trying to produce an MVC effort and if the force increases with the twitch, the muscle is not fully activated (ie-the person is not producing a maximal recruitment effort).\r\n\r\nIf there is minimal force increase (less than 2%, Hales & Gandevia, 1988) then the muscle is considered fully activated and we can rest assured the person is trying as hard as they can to produce their MVC.\r\n\r\nIf Twitch is used in conjunction with EMG then researchers can also use it to measure:\r\n