Electrodermal activity
Electrodermal activity (EDA) is the property of the human body that causes continuous variation in the electrical characteristics of the skin. Historically, EDA has also been known as skin conductance, galvanic skin response (GSR), electrodermal response (EDR), psychogalvanic reflex (PGR), skin conductance response (SCR), sympathetic skin response (SSR) and skin conductance level (SCL). The long history of research into the active and passive electrical properties of the skin by a variety of disciplines has resulted in an excess of names, now standardized to electrodermal activity (EDA).[1][2][3]
The traditional theory of EDA holds that skin resistance varies with the state of sweat glands in the skin. Sweating is controlled by the sympathetic nervous system,[4] and skin conductance is an indication of psychological or physiological arousal. If the sympathetic branch of the autonomic nervous system is highly aroused, then sweat gland activity also increases, which in turn increases skin conductance. In this way, skin conductance can be a measure of emotional and sympathetic responses.[5] More recent research and additional phenomena (resistance, potential, impedance, electrochemical skin conductance, and admittance, sometimes responsive and sometimes apparently spontaneous) suggest that EDA is more complex than it seems, and research continues into the source and significance of EDA.
History
In 1849, Dubois-Reymond in Germany first observed that human skin was electrically active. He immersed the limbs of his subjects in a zinc sulfate solution and found that electric current flowed between a limb with muscles contracted and one that was relaxed. He therefore attributed his EDA observations to muscular phenomena.[6] Thirty years later, in 1878 in Switzerland, Hermann and Luchsinger demonstrated a connection between EDA and sweat glands. Hermann later demonstrated that the electrical effect was strongest in the palms of the hands, suggesting that sweat was an important factor.[7]
Vigouroux (France, 1879), working with emotionally distressed patients, was the first researcher to relate EDA to psychological activity. In 1888, the French neurologist Féré demonstrated that skin resistance activity could be changed by emotional stimulation and that activity could be inhibited by drugs.[7]
In 1889 in Russia, Ivane Tarkhnishvili observed variations in skin electrical potentials in the absence of any external stimuli, and he developed a meter to observe the variations as they happened in real time.[8][9]
The scientific study of EDA began in the early 1900s. One of the first references to the use of EDA instruments in psychoanalysis is the book by C. G. Jung entitled Studies in Word Analysis, published in 1906.[10][11] Jung and his colleagues used the meter to evaluate the emotional sensitivities of patients to lists of words during word association.[12][13] Jung was so impressed with EDA monitoring, he allegedly cried, "Aha, a looking glass into the unconscious!"[14] Jung described his use of the device in counseling in his book, Studies in Word Association, and such use has continued with various practitioners.[15]
The controversial Austrian psychoanalyst Wilhelm Reich also studied EDA in his experiments at the Psychological Institute at the University of Oslo, in 1935 and 1936, to confirm the existence of a bio-electrical charge behind his concept of vegetative, pleasurable "streamings".[16]
By 1972, more than 1500 articles on electrodermal activity had been published in professional publications, and today EDA is regarded as the most popular method for investigating human psychophysiological phenomena.[17] As of 2013, EDA monitoring was still on the increase in clinical applications.[18]
Description
Skin conductance is not under conscious control. Instead, it is modulated autonomously by sympathetic activity which drives human behavior, cognitive and emotional states on a subconscious level. Skin conductance, therefore, offers direct insights into autonomous emotional regulation.[19]
Human extremities, including fingers, palms, and soles of feet display different bio-electrical phenomena. They can be detected with an EDA meter, a device that displays the change electrical conductance between two points over time. The two current paths are along the surface of the skin and through the body. Active measuring involves sending a small amount of current through the body.
Some studies include the human skin's response to alternating current, including recently deceased bodies.[20]
Physiological basis
There is a relationship between emotional arousal and sympathetic activity, although the electrical change alone does not identify which specific emotion is being elicited. These autonomic sympathetic changes alter sweat and blood flow, which in turn affects GSR and GSP (Galvanic skin potential). The amount of sweat glands varies across the human body, being highest in hand and foot regions (200–600 sweat glands per cm2).[19] The response of the skin and muscle tissue to external and internal stimuli can cause the conductance to vary by several microsiemens. A correctly calibrated device can record and display the subtle changes.[21]
The combined changes between electrodermal resistance and electrodermal potential make up electrodermal activity. Galvanic skin resistance (GSR) is an older term that refers to the recorded electrical resistance between two electrodes when a very weak current is steadily passed between them. The electrodes are normally placed about an inch apart, and the resistance recorded varies according to the emotional state of the subject. Galvanic skin potential (GSP) refers to the voltage measured between two electrodes without any externally applied current. It is measured by connecting the electrodes to a voltage amplifier. This voltage also varies with the emotional state of the subject.[21]
Examples
A painful stimulus such as a pinprick elicits a sympathetic response by the sweat glands, increasing secretion. Although this increase is generally very small, sweat contains water and electrolytes, which increase electrical conductivity, thus lowering the electrical resistance of the skin. These changes in turn affect GSR. Another common manifestation is the vasodilation (dilation) of blood vessels in the face, referred to as blushing, as well as increased sweating that occurs when one is embarrassed.[21]
EDA is highly responsive to emotions in some people. Fear, anger, startled response, orienting response, and sexual feelings are among the reactions that may be reflected in EDA. These responses are utilized as part of the polygraph or lie detector test.
EDA in regular subjects differs according to feelings of being treated fairly or unfairly, but psychopaths have been shown to manifest no such differences.[22] This indicates that the EDA record of a polygraph may be deceptive in a criminal investigation.
Different units of EDA
EDA reflects both slow varying tonic sympathetic activity and fast varying phasic sympathetic activity. Tonic activity can be expressed in units of electrodermal level (SCL), while phasic activity is expressed in units of electrodermal responses (EDR).[23]
Phasic changes (EDR) are short-lasting changes in EDA that appear as a response to a distinct stimulus. EDRs can also appear spontaneously without an observable external stimulus. These types of EDRs are referred to as "nonspecific EDR" (NS.EDR).[24] The phasic SCR is useful when investigating multifaceted attentional processes.[25]
Tonic changes (EDL) are based on the phasic parameters. The spontaneous fluctuations of nonspecific EDR can be used to evaluate tonic EDA. More specifically by using the frequency of "nonspecific EDR" as an index of EDA during a specific time period, e. g. 30–60 seconds. Tonic EDA is considered useful in investigations of general arousal and alertness.[23]
Uses
EDA is a common measure of autonomic nervous system activity, with a long history of being used in psychological research.[26] Hugo D. Critchley, Chair of Psychiatry at the Brighton and Sussex Medical School states, "EDA is a sensitive psychophysiological index of changes in autonomic sympathetic arousal that are integrated with emotional and cognitive states."[27] Many biofeedback therapy devices utilize EDA as an indicator of the user's stress response with the goal of helping the user to control anxiety.[28] EDA is used to assess an individual's neurological status without using traditional, but uncomfortable and expensive, EEG-based monitoring.[29] It has also been used as a proxy of psychological stress.[30]
EDA has also been studied as a method of pain assessment in premature born infants.[31]
Often, EDA monitoring is combined with the recording of heart rate, respiratory rate, and blood pressure, because they are all autonomically dependent variables. EDA measurement is one component of modern polygraph devices, which are often used as lie detectors.[21]
The E-meter used by the Church of Scientology as part of its practice of "auditing" and "security checking", is a custom EDA measurement device.[32]
Possible problems
External factors such as temperature and humidity affect EDA measurements, which can lead to inconsistent results. Internal factors such as medications and hydration can also change EDA measurements, demonstrating inconsistency with the same stimulus level. Also, the classic understanding has treated EDA as if it represented one homogeneous change in arousal across the body, but in fact different locations of its measurement can lead to different responses; for example, the responses on the left and right wrists are driven by different regions of the brain, providing multiple sources of arousal; thus, the EDA measured in different places on the body varies not only with different sweat gland density but also with different underlying sources of arousal.[33] Lastly, electrodermal responses are delayed 1–3 seconds. These show the complexity of determining the relationship between EDA and sympathetic activity.[21] The skill of the operator may be a significant factor in the successful application of the tool.[34]
Notes
- Boucsein, Wolfram (2012). Electrodermal Activity. Springer Science & Business Media. p. 2. ISBN 978-1-461-41126-0. Retrieved 20 October 2015.
- Critchley, Hugo D. (April 2002). "Book Review: Electrodermal Responses: What Happens in the Brain". The Neuroscientist. 8 (2): 132–142. doi:10.1177/107385840200800209. PMID 11954558. S2CID 146232135. Retrieved 15 April 2015.
Electrodermal activity (EDA) is now the preferred term for changes in electrical conductance of the skin, including phasic changes that have been referred to as galvanic skin responses (GSR)
- Boucsein, Wolfram (2013-04-17). Electrodermal Activity. Springer Science & Business Media. p. 1. ISBN 9781475750935.
- Martini, Frederic; Bartholomew, Edwin (2001). Essentials of Anatomy & Physiology. San Francisco, California: Benjamin Cummings. p. 263. ISBN 978-0-13-061567-1.
- Carlson, Neil (2013). Physiology of Behavior. New York City: Pearson Education, Inc. ISBN 978-0-205-23939-9.
- Boucsein, Wolfram (2012). Electrodermal Activity. Springer Science & Business Media. p. 3. ISBN 9781461411260. Retrieved 16 April 2015.
- Boucsein, Wolfram (2012). Electrodermal Activity. Springer Science & Business Media. p. 4. ISBN 9781461411260. Retrieved 16 April 2015.
- Society for Neuroscience (2011). SfN 2010 - Nano, Theme H, Featured Lectures, Special Lectures, Symposia/Minisymposia, Workshops, Satellites, and Socials. Coe-Truman Technologies. ISBN 978-161-330001-5. Retrieved 28 February 2017.
- Handbook of Clinical and Experimental Neuropsychology (eds. Gianfranco Denes, Luigi Pizzamiglio). Psychology Press, 1999. ISBN 9780863775420. Page 33.
- Daniels, Victor. "Notes on Carl Gustav Jung". Sonoma State University. Retrieved 4 April 2015.
By 1906 [Jung] was using GSR and breath measurement to note changes in respiration and skin resistance to emotionally charged worlds. Found that indicators cluster around stimulus words which indicate the nature of the subject's complexes...Much later L. Ron Hubbard used this approach in Scientology's "auditing," using the "e-meter" (a galvanic skin response indicator) to discern the presence of complexes.
- The Biofeedback Monitor Archived 2008-09-15 at the Wayback Machine
- "You can learn control of how your skin talks". San Bernardino, California: The San Bernardino County Sun. The San Bernardino County Sun. October 11, 1977. p. 12. Retrieved 8 April 2015.
Current research using the skin's electrical activity as a communications medium between patient and therapist looks promising in such stress problems as drug abuse, alcoholism, neuroses and other tension states.
- Binswanger, L. (1919). "XII". In Jung, Carl (ed.). Studies in Word-Association. New York, NY: Moffat, Yard & company. pp. 446 et seq. Retrieved 30 March 2015.
- Brown, Barbara (November 9, 1977). "Skin Talks -- And It May Not Be Saying What You Want To". Pocatello, Idaho: Field Enterprises, Inc. Idaho State Journal. p. 32. Retrieved 8 April 2015.
- Mitchell, Gregory. "Carl Jung & Jungian Analytical Psychology". Mind Development Courses. Retrieved 9 April 2015.
- Reich, W. "Experimentelle Ergebnisse ueber die electrische Funktion von Sexualitat und Angst" (Sexpolverlag, Copenhagen, 1937). Translated as "Experimental investigation of the electrical function of sexuality and anxiety" in Journal of Orgonomy, Vol. 3, No. 1-2, 1969.
- Boucsein, Wolfram (2012). Electrodermal Activity. Springer Science & Business Media. p. 7. ISBN 9781461411260. Retrieved 10 April 2015.
- Ogorevc, Jaka; Geršak, Gregor; Novak, Domen; Drnovšek, Janko (November 2013). "Metrological evaluation of skin conductance measurements". Measurement. 46 (9): 2993–3001. Bibcode:2013Meas...46.2993O. doi:10.1016/j.measurement.2013.06.024.
- "What is GSR". iMotions A/S. Retrieved 18 August 2017.
- Grimnes, Sverre; Jabbari, Azar; Martinsen, Ørjan G.; Tronstad, Christian (2011-02-01). "Electrodermal activity by DC potential and AC conductance measured simultaneously at the same skin site". Skin Research and Technology. 17 (1): 26–34. doi:10.1111/j.1600-0846.2010.00459.x. ISSN 1600-0846. PMID 20923453. S2CID 13563354.
- Pflanzer, Richard. "Galvanic Skin Response and the Polygraph" (PDF). BIOPAC Systems, Inc. Archived from the original (PDF) on 18 December 2014. Retrieved 18 August 2017.
- Oshumi, T., Ohira, H. "The positive side of psychopathy: Emotional detachment in psychopathy and rational decision-making in the ultimatum game". Personality and Individual Differences 49, 2010, pp. 451-456
- Boucsein, Wolfram (2012). Electrodermal Activity. Boston, MA: Springer US. doi:10.1007/978-1-4614-1126-0. ISBN 978-1-4614-1125-3.
- Society for Psychophysiological Research Ad Hoc Committee on Electrodermal Measures (August 2012). "Publication recommendations for electrodermal measurements: Publication standards for EDA". Psychophysiology. 49 (8): 1017–1034. doi:10.1111/j.1469-8986.2012.01384.x. PMID 22680988. S2CID 17713243.
- Handbook of psychophysiology. Cacioppo, John T., Tassinary, Louis G., Berntson, Gary G. (3rd ed.). Cambridge [England]: Cambridge University Press. 2007. ISBN 978-0-511-27907-2. OCLC 166506595.
{{cite book}}
: CS1 maint: others (link) - Mendes, Wendy Berry (2009). "Assessing Autonomic Nervous System Activity" (PDF). In Harmon-Jones, E.; Beer, J. (eds.). Methods in Social Neuroscience. New York: Guilford Press. ISBN 978-1-606-23040-4. Retrieved October 20, 2015.
- Critchley, Hugo D. (April 2002). "Book Review: Electrodermal Responses: What Happens in the Brain". Neuroscientist. 8 (2): 132–142. doi:10.1177/107385840200800209. PMID 11954558. S2CID 146232135. Retrieved 27 April 2015.
- Alterman, Ben. "Services Provided". Retrieved 28 August 2015.
- Birjandtalab, J.; Cogan, D.; Pouyan, M. B.; Nourani, M. (2016-10-01). "A Non-EEG Biosignals Dataset for Assessment and Visualization of Neurological Status". 2016 IEEE International Workshop on Signal Processing Systems (SiPS). pp. 110–114. doi:10.1109/SiPS.2016.27. ISBN 978-1-5090-3361-4. S2CID 31596383.
- Yang, X; McCoy, E (November 2021). "The effects of traveling in different transport modes on galvanic skin response (GSR) as a measure of stress: An observational study". Environment International. 156: 106764. doi:10.1016/j.envint.2021.106764. ISSN 0160-4120. PMID 34273874. S2CID 236035129.
- Munsters, Josanne; Wallström, Linda; Ågren, Johan; Norsted, Torgny; Sindelar, Richard (January 2012). "Skin conductance measurements as pain assessment in newborn infants born at 22–27weeks gestational age at different postnatal age". Early Human Development. 88 (1): 21–26. doi:10.1016/j.earlhumdev.2011.06.010. PMID 21764228.
- Brad Graham; Kathy McGowan (2009). Mind Performance Projects for the Evil Genius: 19 Brain-Bending Bio Hacks (illustrated ed.). McGraw Hill Professional. p. 31. ISBN 978-0-07-162392-6.
- Picard, Rosalind; Fedor, Szymon; Ayzenberg, Yadid (2016). "Multiple Arousal Theory". Emotion Review. 8 (1): 62–75. doi:10.1177/1754073914565517. S2CID 10550306.
- Matté, James Allan (2000-01-01). Examination and Cross-examination of Experts in Forensic Psychophysiology Using the Polygraph. J.A.M. Publications. ISBN 9780965579421.
References
- Conesa J (1995). "Electrodermal palmar asymmetry and nostril dominance". Perceptual and Motor Skills. 80 (1): 211–216. doi:10.2466/pms.1995.80.1.211. PMID 7624194. S2CID 31812398.
- Carlson, Neil (2013). Physiology of Behavior. New Jersey: Pearson Education, Inc. ISBN 978-0-205-23939-9.
- Figner, B., & Murphy, R. O. (2010). Using skin conductance in judgment and decision making research. A Handbook of Process Tracing Methods for Decision Research: A Critical Review and User's Guide, 163–84.
- Pflanzer, Richard. "Galvanic Skin Response and the Polygraph". BIOPAC Systems, Inc. Retrieved 5 May 2013.
- Nagai, Y.; Goldstein, L. H.; Fenwick, P. B. C.; Trimble, M. R. (2004). "Clinical efficacy of galvanic skin response biofeedback training in reducing seizures in adult epilepsy: A preliminary randomized controlled study". Epilepsy & Behavior. 5 (2): 216–223. doi:10.1016/j.yebeh.2003.12.003. PMID 15123023. S2CID 23077324.
- Loggia, M. L.; Juneau, M. N.; Bushnell, M. C. (2011). "Autonomic responses to heat pain: Heart rate, skin conductance, and their relation to verbal ratings and stimulus intensity". Pain. 152 (3): 592–598. doi:10.1016/j.pain.2010.11.032. PMID 21215519. S2CID 15779956.