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THE EFFECT OF CERTAIN MENTAL OPERATIONS UPON THE ALPHA RHYTHM A Dissertation Presented to the Faculty of the Graduate School The University of Southern California In Partial Fulfillment of the Requirements for the Degree Doctor of Philosophy by George Donald Gray February 1950 UMI Number: DP30390 All rights reserved INFORMATION TO ALL USERS The quality of this reproduction is dependent upon the quality of the copy submitted. In the unlikely event that the author did not send a complete manuscript and there are missing pages, these will be noted. Also, if material had to be removed, a note will indicate the deletion. Dissertation Ptibiisfung UMI DP30390 Published by ProQuest LLC (2014). Copyright in the Dissertation held by the Author. Microform Edition © ProQuest LLC. All rights reserved. This work is protected against unauthorized copying under Title 17, United States Code ProQuest LLC. 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, Ml 48106- 1346 D*. /^ro <£• p k i 0. \'s This dissertation, written by GEO«GS.DPMy?..GMI................ under the guidance of A...is. Faculty Committee on Studies, and approved by all its members, has been presented to and accepted by the Council on Graduate Study and Research, in partial ful­ fillment of requirements for the degree of DO CTO R OF P H ILO S O P H Y Dean lLrJ$.5P Date Committee on Studies Chairman TABLE OF CONTENTS CHAPTER PAGE I. INTRODUCTION................'........... 1 Psychology and the E E G ................. 4 Types of waves, constituting the EEG . . 4 Variables of the EEG and their measurement 7 Characteristics of the alpha waves . . . 10 The origin of the alpha waves.......... 29 Characteristics and origin of beta waves 32 Characteristics and origin of delta waves 37 Characteristics and origin of kappa waves 41 Relationship between records of the two hemispheres......................... 42 Underlying factors in brain rhythms . . . 44 The brain rhythm and mathematical biophysics 65 II. THE PROBLEM............................. 68 III. REVIEW OF THE LITERATURE............... 70 IV. APPARATUS, SUBJECTS, AND PROCEDURE . . . . 85 Bipolar versus monopolar recording . . . 87 Artifacts............................. 89 Recording equipment .................... 92 Recording room.............. 92 Electrodes and their placement ........ 93 Subjects and procedure ................. 94 Analysis of data*....................... 95 CHAPTER PACE V. RESULTS................................. 98 VI. DISCUSSION . . ....................... . . 129 Analysis of this s t u d y ....................... 129 Comparison with former studies ............... 133 VII. SUMMARY AND CONCLUSIONS.................. 141 Summary............................... 141 Conclusions . . . . . . . 143 BIBLIOGRAPHY...................................... 146 APPENDIX A. The tests......................... 159 APPENDIX B. A section of record................ 161 LIST OF TABLES TABLE PAGE I. Alpha Wave Count for Twenty Seconds of Record ..................... 99 II. Alpha Index for Twenty Seconds of Record .■ . . 101 III. F.-Test and t-Test Results................. 105 IV. F-Tests C A R .....................112 V. t-Tests C A ................................... - 114 VI. t-Tests C R ................................. 117 VII. t-Tests A R ................................. 118 VIII. t-Tests CA Number.......................... 120 IX. t-Tests CR Number.......................... 122 X. t-Tests AR Number.......................... 123 XI. t-Tests CA Language........................ 124 XII. t-Tests CR Language........................ 125 XIII. t-Tests AR Language ...................... 127 XIV. LR Control............... 128 CHAPTER I INTRODUCTION Definite knowledge of the electrical properties of living tissue began with the investigations of Du Bois-Reymond (49), which resulted in the discovery of the demarcation and action current in muscle and nerve in 1843. In 1874, Caton (30) discovered evidences of electrical activity in the brains of living animals. Throughout the years to 1924 various ani­ mal studies were reported, but in this year Berger (9) suc­ ceeded in recording the activity of the human brain. In 1925, Neminski (123), working on the electrical activity of the cor­ tex of the dog, coined the work electrocerebrogram to describe the spontaneous fluctuations in potentials which he observed. In his electrocerebrogram, which he was able to obtain from the cortex itself, the dura, and the outer surface of the skull, he distinguished spontaneous fluctuations in potential with a frequency of 10-15 waves per second, and other faster fluctuations of 20-32 waves per second. The former he called waves of the first order and the latter waves of the second order. Berger, apparently a purist, changed the second root in electrocerebrogram, and referred to his record as the elektrenkephalORramm. which is usually rendered into English as electroencephalogram and abbreviated EEG-. During the ensuing years, particularly 1929-33, 2 Berger (9,12,13,14->15) carried out the first systematic study of the EEG- of human subjects. He made several important dis­ coveries and proposed some theories. He noted that the spon­ taneous rhythm is recordable from, the surface of the intact skull of the conscious human subject, and that the rhythm gives the greatest effect over bone defects in the skull. He further noted that the same frequency rhythm is obtainable over most any part of the haad and with particular prominence over the occiput, and that, for the entire head between elec­ trode pairs, there were always secondary fast rhythms super­ imposed on the slower dominant ones. To these slow dominant rhythms, most prominent over the occiput and having a fre­ quency of about 10 vibrations per second, he gave the name aloha waves; and to the superimposed low amplitude, higher frequency activity he applied the name beta waves. He con­ cluded that the alpha rhythm originates in the cortex, that it represents a fundamental activity of the brain, and that it has a wide and less specific origin than the occipital lobes — that every part of the cortex may contribute to the recorded potential changes. He ruled out the possibility that the waves come from the blood vessels or connective tis­ sue; and concluded that the alpha rhythm results from the activity of a large mass of neurons in the cortex as a whole, and that it is a reflection of biologic activities associated with psychophysical processes. 3 Berger found that the alpha waves appear most favor­ ably when the subject is lying quietly with his eyes closed; and that the rhythm can be modified by the application of sensory stimuli, or by having the subject engage in some­ thing that occupies his whole attention, e.g., a problem in mental arithmetic. He noted in these situations that beta waves are apparently unaffected, and concluded that they arise from nutritive and metabolic functions. It was posited that attention to specific sensory stimuli is associated with facilitative processes in one specific locus of the cortex, and inhibition of activities in all other parts. Depression of the alpha rhythm reflects this process of in­ hibition in the greater part of the cortex. Adrian and Matthews (2) confirmed the work of Berger, but disagreed as to the locus of the alpha rhythm, contend­ ing that the rhythm is occipital in origin. They even sus­ pected that muscle potentials picked up by the scalp might account for the record. Accordingly, they conducted an ex­ tensive study, in which they were able to rule out muscle sources, but in which they became further convinced that the rhythm was entirely occipital in origin. In fact, they applied the expression f,Berger rhythm” to the occipital alpha waves in order to distinguish them from Berger's alleged over-the-whole-cortex alpha rhythm. 4 I. PSYCHOLOGY AND THE EEG It is well established that the EEG reflects physio­ logic activity in the brain. If factors in the brain on which the EEG depends are also factors in psychological phe­ nomena, them the EEG might be an indicator of physiologic mechanisms underlying psychological phenomena. If this be true, then it lies within the province of the psychologist to look into the nature of the brain activities which regu­ late psychological performance. The suggested steps to be followed are (a) a determination of an empirical correlation between any psychologic variables and some property of the EEG; if the result is positive, then (b) a determination of the factors in the brain which are responsible for the partic­ ular type of EEG obtained; and then, (c) the formulation of a working hypothesis of the role played by these factors in the psychologic phenomena under consideration (104). II TYPES OF WAVES CONSTITUTING THE EEG The alpha waves. With respect to frequency, the upper and lower limits and the range assigned to these waves are somewhat arbitrary. The lowest and highest limit and the broadest spread are allowed by Narrow (36), who gives 7-14 waves per second; the other extreme is found with Adrian and Matthews (2), who give 9.5-10.5 waves per second. It is generally agreed that the waves have a frequency of about 10

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