An estimated 10% of the general population experiences fear of flying (FOF) and 25% of the population that flies experiences distress during the flight. The most effective psychological technique for the treatment of phobias is in vivo exposure. Using planes in real flights, however, takes a large amount of time and money that is not easily accessible. Virtual Reality Exposure Treatment (VRET) of FOF is now well established but generalization of such treatment in clinical settings is still rare.
Researchers from INSERM Centre of Psychiatry and Neurosciences presented a case report of a 31-year-old woman who was chosen for treatment because of her FOF. She attended a demonstration of the new VR equipment and disclosed her FOF. Researcher’s proposed a VRET as she had to fly in a few months and anticipated high anxiety during the scheduled flight.
The woman received six sessions of VRET, delivered with standard BIOPAC VR setup, using the included Virtual Environment (VE) of an aircraft with minor adaptations. The woman was seated in an aircraft chair that vibrated during takeoff and turbulences. Researchers used a standard BIOPAC VR Ultimate system, a high-resolution stereoscopic head-mounted display providing a monocular field of view of 60°, a tracking device in order to adapt the field of view to head movements, connected to a MP150 physiological responses amplifier. Skin Conductance Level and Heart Rate were recorded with BIOPAC’s BioNomadix wireless transmitter-receiver modules connected to electrodes.
Results showed evidence of a progressive reduction of the subject’s anxiety in the reactivity to takeoffs and turbulences. A Flight Anxiety Situations questionnaire showed a reduction of anticipation anxiety. The woman succeeded in flying alone three months after completion of VRET. Physiological monitoring may provide indexes predictive of outcome; further research is required. Full immersion rather than the graphical quality of VE is the main driver of the sense of reality experiences by the subject.
A flow state typically occurs when a person’s abilities match the level of difficulty for the current task they are completing. During this state, researchers have found that most people who exhibit flow experience changes in blood pressure, muscle activation, and mental focus, among other responses. They also lose self-awareness and subjectively evaluate time as passing more quickly than usual. All of these factors relate to both the sympathetic and parasympathetic nervous systems, suggesting that flow may involve a non-reciprocal coactivation of both systems. Neuroscience and Psychology researchers in Stockholm, Sweden hypothesize that these effects suggest a potential physiological component that differentiates flow from other states of increased mental effort. This indication may provide accurate measurement of deep concentration in a flow state during various activities, including, but not limited to, music, video games, and writing.
To test this hypothesis, the researchers had a total of 77 participants play a modified version of the video game Tetris and then complete a questionnaire about their experience. Participants were instructed to play three game difficulties: Easy, Optimal, and Difficult. In the Optimal setting, researchers adjusted the speed of the game to match the participants’ ability, based on initial performance. Speed was then decreased and increased by three stages for Easy and Difficult modes, respectively. Wireless ECG and Respiration data was recorded using the wearable BioNomadix amplifier (BN-RSPEC); surface electrodes were placed on the left and right chest. In addition, mental activity was measured in 35 participants—this was determined by frontal lobe oxygenation, which was recorded by placing the BIOPAC fNIR100 optical brain imaging sensor on the forehead of each participant. After completing all three video game difficulties, subjects were given a questionnaire to indicate their subjective experience with each game level. The results found that while larger respiratory depth was associated with deeper flow, there was no significant correlation between frontal cortex activity and flow.
Muscle mechanical energy expenditure shows the neuromotor strategies used by the nervous system to analyze human locomotion tasks and is directly related to its efficiency. Kaur, Shilpi, Bhatia, and Joshi investigated the impact of gender on the activity of agonist-antagonist muscles during maximum knee and ankle contraction in males and females. Twenty right leg dominant male and female adult volunteers were recruited in the study. Limb dominance was determined according to which leg the individual chooses and relies on to carry out the activities. Movements of knee and ankle used for the maximum contractions were knee flexion and extension, and ankle plantar flexion and dorsiflexion. EMG Signals were recorded wirelessly from the selected ipsilateral and contralateral muscles of both the dominant and non-dominant lower limbs of all subjects. Recordings used BIOPAC multi-channel Wireless EMG and the collected data was stored using AcqKnowledge software included with the data recording system. Results showed that there is no significant influence of gender on agonist-antagonist muscle energy expenditure during maximum knee contraction. For ankle contractions, gender has significant influence on energy expenditure during maximum ankle dorsiflexion. Researchers found that these results are helpful in understanding gender related differences in the energy expenditure of selected muscles during maximum knee and ankle contractions. The wireless BioNomadix modules used by the researchers permitted free movement for the knee and ankle movements required of the study. The Dynamometry-EMG BioNomadix Pair has matched transmitter and receiver module specifically designed to measure one or both signals. These units interface with the MP150 and data acquisition and AcqKnowledge software, allowing advanced analysis for multiple applications and supporting acquisition of a broad range of signals and measurements. Both channels have extremely high-resolution EMG and Dynamometry waveforms at the receiver’s output. The pair emulates a “wired” connection from the computer to subject, in terms of quality, but with all the benefits of a fully-wireless recording system.
A growing health risk in modern times is the increased amount of time the average person spends sitting. Whether at work for 8 hours at a computer or on the couch all day watching a favorite show, sitting contributes to a sedentary lifestyle, which is a known risk factor for cardiovascular disease and diabetes. It has been found that even those who exercise regularly, yet spend a prolonged portion of their day seated, have increased risk of similar ailments. Though many health risks of sitting are known, there has been little research on its impact on the musculoskeletal system. Physical therapists have noted an inexplicably high rate of clinical weakness of the gluteus maximus muscle. Doctoral candidates in physical therapy at City University of New York recently published a capstone project on their hypothesis that the habit of prolonged sitting directly leads to weakening of the gluteus maximus and the hamstrings. In the experiment, subjects were asked, after a brief warm-up, to perform maximal voluntary isometric contraction (MVIC) for both muscle groups. In addition, two functional activities were performed by the subjects: a “sit-to-stand” exercise and a “forward step-up” exercise. The subjects were separated into two groups based on their sitting/standing habits throughout the day. Surface EMG signals were recorded from the subjects using a BioNomadix wireless EMG Transmitter and Receiver set, along with an MP150 data acquisition system. Using AcqKnowledge software, the researchers were able to process the raw EMG signals with automated data reduction routines and statistical analysis. Further analysis of the data found no statistically significant differences in gluteus strength between the two groups. However, the group still believes that there remains to be studied the muscular effects of prolonged sitting. Further studies may be benefitted by the use of the BioNomadix Logger for continuous, 24-hour logging of a range of physiological signals. BIOPAC offers BioNomadix wireless physiology systems and a number of other solutions for EMG and other signals and measurements.
