Right Vs. Left
Total Page:16
File Type:pdf, Size:1020Kb
Load more
Recommended publications
-
The Hands to Say It
Issue 91, February 2008 www.proteinspotlight.org The hands to say it Vivienne Baillie Gerritsen When I was a little girl, I thought that my left-handed classmates were special. I envied their difference. And I used to marvel at the way they crouched over their desk, embracing something invisible as they did their best to avoid smudging ink all over their sheet of paper. Left-handedness is special. But so is right-handedness. Humans are not the only animals to make use of their hands – or claws, or paws, or hooves - but they are the only ones who show a marked preference for either the left one, or the right one. If this is so, there must be a reason for it. And not only must there be a reason but it must translate a certain structure of our brain: an asymmetry somewhere. Indeed, our brain is divided into two hemispheres which are dedicated to processing different activities. One side looks after our dreams, while the other is far more down to earth. LRRTM1 is the first protein to have been discovered which seems to be directly involved in this brain asymmetry. Consequently, it influences the handedness of a human-being and, more astonishingly, may also predispose individuals to psychotic troubles such as schizophrenia. don’t have a distinct preference for one hand over the other. The passing of roles from hand to mind expresses a particular brain structure. In turn, the progressive use of speech has continued to mould our brain into a shape peculiar to the human species. -
EEG Glossary
EEG Glossary The first attempt to systematically propose a syllabus for Activation procedure Any procedure designed to modu- electroencephalographers was made by O’Leary and Knott late EEG activity, for instance to enhance physiologi- who in 1955 published in the EEG Journal “Some Minimal cal waveforms or elicit abnormal paroxysmal activity. Essentials for Clinical Electroencephalographers” [1]. In the Examples include eye closing, hyperventilation, photic following decades, with the EEG being increasingly used in stimulation, natural or drug-induced sleep, sensory stimu- the experimental and clinical field, need to adopt a language lation (acoustic, somatosensory, or pain). as common as possible between various laboratories world- Activity, EEG An EEG wave or sequence of waves of wide became even more pressing. In fact, the multiplicity of cerebral origin. terms generated (and sometimes still generates) confusion Alpha band Frequency band of 8–13 Hz inclusive. Greek and misinterpretations, promoting misdiagnosis and making letter: α. it difficult to compare data between different laboratories. Alpha rhythm Rhythm at 8–13 Hz inclusive occurring To overcome this risk, in 1974 “A Glossary of Terms,” most during wakefulness over the posterior regions of the head, commonly used by “Clinical Electroencephalographers,” was generally with maximum amplitudes over the occipital published in the EEG Journal; this glossary was the result of areas. Amplitude varies but is mostly below 50 μV in the the work of a group of experts from the International Federation adult, but often much higher in children. Best seen with of Clinical Neurophysiology (IFCN) led by Chatrian [2]. the eyes closed, during physical relaxation and relative Thanks to this document, it was for the first time officially mental inactivity. -
Symmetry and Beauty in the Living World I Thank the Governing Body and the Director of the G.B
SYMMETRY AND BEAUTY IN THE LIVING WORLD I thank the Governing Body and the Director of the G.B. Pant Institute of Himalayan Environment & Development for providing me this opportunity to deliver the 17th Govind Ballabh Pant Memorial Lecture. Pt. Pant, as I have understood, was amongst those who contributed in multiple ways to shape and nurture the nation in general and the Himalayan area in particular. Established to honour this great ‘Son of the Mountains’, the Institute carries enormous responsibilities and expectations from millions of people across the region and outside. Undoubtedly the multidisciplinary skills and interdisciplinary approach of the Institute and the zeal of its members to work in remote areas and harsh Himalayan conditions will succeed in achieving the long term vision of Pt. Pant for the overall development of the region. My talk ‘Symmetry and Beauty in the Living World’ attempts to discuss aspects of symmetry and beauty in nature and their evolutionary explanations. I shall explain how these elements have helped developmental and evolutionary biologists to frame and answer research questions. INTRODUCTION Symmetry is an objective feature of the living world and also of some non-living entities. It forms an essential element of the laws of nature; it is often sought by human beings when they create artefacts. Beauty has to do with a subjective assessment of the extent to which something or someone has a pleasing appearance. It is something that people aspire to, whether in ideas, creations or people. Evolutionary biology tells us that it is useful to look for an evolutionary explanation of anything to do with life. -
Schizophrenia As Failure of Hemispheric Dominance for Language
J-P. Ewert – Key stimulus and releasing mechanism V IEWPOINT 63 Fentress, J.C. (1983) in Handbook of Behavioral Neurobiology: 67 Liaw, J-S., Weerasuriya, A. and Arbib, M.A. (1994) Neural Motivation (Vol. 6) (Satinoff, E. and Teitelbaum, P., eds), Networks 7, 1137–1152 pp. 185–234, Plenum 68 König, P., Engel, A.K. and Singer, W. (1996) Trends Neurosci. 64 Arbib, M.A. and Cobas, A. (1991) in Visual Structures and 19, 130–137 Integrated Functions (Arbib, M.A. and Ewert, J-P., eds), 69 Ungerleider, L.G. and Mishkin, M. (1982) in Analysis of Visual pp. 139–166, Plenum Behavior (Ingle, D.J., Goodale, M.A. and Mansfield, R.J.W., eds), 65 Matesz, C. and Székely, G. (1978) J. Comp. Neurol. 178, pp. 549–586, MIT Press 157–176 70 Goodale, M.A. and Milner, A.D. (1992) Trends Neurosci. 15, 66 Matsushima, T., Satou, M. and Ueda, K. (1989) J. Comp. 20–25 Physiol. A 166, 7–22 71 Jeannerod, M. et al. (1995) Trends Neurosci. 18, 314–320 Schizophrenia as failure of hemispheric dominance for language T.J. Crow Schizophrenic illnesses occur with approximately the same incidence in all human populations with a characteristic distribution (slightly earlier in males) of ages of onset.Given that the predisposition (which presumably is genetic) is associated with a procreative disadvantage why do such illnesses persist? Here it is suggested that these conditions are a manifestation of genetic diversity in the evolution of the specifically human characteristic of language, an innovation that has occurred by a process of progressive hemispheric specialization – the establishment of dominance for some critical component of language in one or the other hemisphere. -
A Cinch for the Brain
A Cinch for the Brain Our bodies, our behavior and even our brains are anything but symmetrical. And this seems to be an important factor in the seamless functioning of our thought, speech and motor faculties. Researchers at the Max Planck Institute for Psycholinguistics in Nijmegen are currently searching for genetic clues to this phenomenon. They want to decode the fundamental molecular biological mechanisms that contribute to asymmetry in the brain, and to identify possible causes for neurological disorders. TEXT STEFANIE REINBERGER t first glance, the human ture. It’s divided into two halves, both A strong left: Rafael Nadal, for body appears to be com- of which are equal in size and whose many years the world’s number pletely symmetrical: two furrows and bulges follow a similar pat- one men’s tennis player, is right-handed but holds the arms, two legs, two eyes, tern. But the functional centers are ex- racket in his left hand most of two ears. Even features tremely unevenly distributed. The right the time. Researchers are likeA the nose and mouth appear to be and left hemispheres specialize in dif- studying how the brains of left- evenly positioned in both halves of ferent cognitive functions. They essen- and right-handed people differ. the face in most people. On closer in- tially divide up the work between them, spection, though, we see that one leg possibly to expand the total range of is longer than the other, one hand is tasks performed. stronger, or maybe the left ear is posi- “Lateralization is a very distinct phe- tioned lower than the right one. -
Manual Asymmetry and Handedness (Trophi Nteclon/Smt Symme-A Try) DALE PURVES*, LEONARD E
Proc. Natd. Acad. Sci. USA Vol. 91, pp. 5030-5032, May 1994 Neurobiology Manual asymmetry and handedness (trophI nteclon/smt symme-a try) DALE PURVES*, LEONARD E. WHITE, AND TIMOTHY J. ANDREWS Duke University Medical Center, Department of Neurobiology, Durham, NC 27710 Contributed by Dale Purves, February 2, 1994 ABSTRACT Volumtric mnasurements show that right- handed Individuals have lager right hands than left hands. In contrst, the hands of left-handers are much more nearly symmetrical. Based on what Is known about tophic interac- dons between neurons and targets, these fings predict a c d aSymmetr of the relevant parts of the sensori- motor system in right-handers. The lack of an opposite-hand asymmy among left-handers further implies that right- and left-handed phenotypes do not arise according to the same developmental rules. Nerve cells and their targets are linked by long-term trophic interactions that coordinate somatic and neural growth (see ref. 1 and below). If one hand is generally larger than the other-as some earlier studies of the human metacarpals suggest (2, 3)-then this asymmetry should be reflected in the size of the related neural structures. As a first step in exploring this neurosomatic relationship, we have measured the volume of the two hands among right- and left-handers. We solicited 52 adult volunteers (students, faculty, and staff from Duke University) who described themselves as right-handers and 50 who considered themselves left-handers (Table 1). The volumes of the two hands were measured for FIG. 1. Diagram ofapparatus used to measure hand size by water each subject by a simple water displacement technique (Fig. -
The Effect of Handedness As Related to the Communication Arts" (1957)
Eastern Illinois University The Keep Masters Theses Student Theses & Publications 1957 The ffecE t of Handedness as Related to the Communication Arts Bertha Beck Eastern Illinois University Recommended Citation Beck, Bertha, "The Effect of Handedness as Related to the Communication Arts" (1957). Masters Theses. 4560. https://thekeep.eiu.edu/theses/4560 This Dissertation/Thesis is brought to you for free and open access by the Student Theses & Publications at The Keep. It has been accepted for inclusion in Masters Theses by an authorized administrator of The Keep. For more information, please contact [email protected]. THE EFFECT OF HANDEDNESS - AS RELATED TO THE COMMUNICATION ARTS A Subst'antiiil' Paper Presented to THE FACULTY OF THE DEPARTMENT OF EDUCATION EASTERN ILLINIOS UNIVERSITY In Partial Fulf'illment Of' the REQUIREMENTS FOR THE DEGREE MASTER OF·SCIENCE IN EDUCATION by ·Bertha Beck - - July;1957 ACKNOWLEDGEMENTS I wish to express my sincere appreciation and thanks to the following people: Dr. A. U. Edwards for his pa tience and guidance. The staff of the libraries, both at the University of Illinois and at Eastern Illinois University, for their assistance. Mrs. Vera Slover, Sullivan, Illinois, for reviewing the paper with me. Mrs. Janice R�Yehrich' for tyPing the final manuscript. CONTENTS Chapter Page I. INTRODUCTION. • • • • • • • • • • • • • • • • • • • 1 . ' II. THE INCIDENCE OF THE CONCEPT OF HANDEDNESS. • • • • 3 Inherited Acquired III. THE EF�ECT OF CHANGING A CHILD'S HANDEDNESS; CHARACTERISTICS OF LATERALITY ON • • • • • • • • • .13 , . Writing Speaking Reading IV• HANDEDNESS AND ITS EFFECT ON SPECIAL CASES. • • ••26 Mentally Deficient Retarded Achievers v. CONCLUSION •••• . • 31 BIBLIOGRAPHY. • • • • • • • • • • • . • • • •.33 CHAPTER I When .� he �ubject of handedness is st�died, a person -t ' -· � finds many rs:mifications �hich can, .be conp dered. -
Left -Handedness Laterality Characteristics and Their
LEFT -HANDEDNESS LATERALITY CHARACTERISTICS AND THEIR EDUCATIONAL IMPLICATIONS by Margaret MacDonald Clark, M.A., Ed.B. Submitted in fulfilment of the requirements for the degree Doctor of Philosophy University of Glasgow 1953 ProQuest Number: 13838552 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 com plete manuscript and there are missing pages, these will be noted. Also, if material had to be removed, a note will indicate the deletion. uest ProQuest 13838552 Published by ProQuest LLC(2019). Copyright of the Dissertation is held by the Author. All rights reserved. This work is protected against unauthorized copying under Title 17, United States C ode Microform Edition © ProQuest LLC. ProQuest LLC. 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, Ml 48106- 1346 ii PREFACE Lack of knowledge concerning left-handedness springs from the multiplicity of studies and contradictory nature of the findings on the various aspects of laterality, father than any insufficiency of material on the subject. The absence of any single authoritative work and extensiveness of existing material make necessary for a full appreciation of the problem a study more prolonged than the average interested person is willing or able to make. The present work, presenting as it does both an attempt at critical evaluation of previous investigations and an original study of laterality characteristics in a group of normal children, will it is hoped satisfy a need for a comprehensive report on the subject. The practical problems confronting teachers and parents dealing with left-handed children have been kept in the forefront through out, in the hope that the information contained herein may make some contribution towards a better understanding of left-handedness and may even lead to a more tolerant attitude towards the * sinister minority*, to which the author herself belongs. -
Genome-Wide Association Study Identifies 48 Common Genetic Variants Associated with Handedness
bioRxiv preprint doi: https://doi.org/10.1101/831321; this version posted November 18, 2019. The copyright holder for this preprint (which was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made available under aCC-BY-NC-ND 4.0 International license. Genome-wide association study identifies 48 common genetic variants associated with handedness. Gabriel Cuellar Partida1, Joyce Y Tung2, Nicholas Eriksson2, Eva Albrecht3, Fazil Aliev4, Ole A Andreassen5,6, Inês Barroso7,8,9, Jacques S Beckmann10, Marco P Boks11, Dorret I Boomsma12,13, Heather A Boyd14, Monique MB Breteler15, Harry Campbell16, Daniel I Chasman17,18, Lynn F Cherkas19, Gail Davies20,21, Eco JC de Geus12,13, Ian J Deary20,21, Panos Deloukas22, Danielle M Dick23, David L Duffy24, Johan G Eriksson25,26, Tõnu Esko27,28, Bjarke Feenstra14, Frank Geller14, Christian Gieger29,30, Ina Giegling31, Scott D Gordon24, Jiali Han32,33, Thomas F Hansen34,35, Annette M Hartmann31, Caroline Hayward36, Kauko Heikkilä37, Andrew A Hicks38, Joel N Hirschhorn39,40,41, Jouke-Jan Hottenga12,13, Jennifer E Huffman36, Liang-Dar Hwang1, Mohammad A Ikram42, Jaakko Kaprio43,44, John P Kemp1,45, Kay-Tee Khaw46, Norman Klopp47, Bettina Konte31, Zoltan Kutalik48,49, Jari Lahti50,51, Xin Li32,33, Ruth JF Loos8,52,53, Michelle Luciano20,21, Sigurdur H Magnusson54, Massimo Mangino19, Pedro Marques-Vidal55, Nicholas G Martin24, Wendy L McArdle56, Mark I McCarthy57,58,59†, Carolina Medina-Gomez42,60, Mads Melbye14,61,62, Scott A -
Evidence from Intrinsic Activity That Asymmetry of the Human Brain Is Controlled by Multiple Factors
Evidence from intrinsic activity that asymmetry of the human brain is controlled by multiple factors Hesheng Liua, Steven M. Stufflebeama,b, Jorge Sepulcrea,c,d, Trey Heddena,c, and Randy L. Bucknera,c,d,e,1 aAthinoula A. Martinos Center for Biomedical Imaging, Department of Radiology, Massachusetts General Hospital, Charlestown, MA 02129; bHarvard-Massachusetts Institute of Technology Division of Health Sciences and Technology, Cambridge, MA 02139; cHarvard University Department of Psychology, Center for Brain Science, Cambridge, MA 02138; dHoward Hughes Medical Institute, Cambridge, MA 02138; and eDepartment of Psychiatry, Massachusetts General Hospital, Charlestown, MA 02129 Edited by Marcus E. Raichle, Washington University School of Medicine, St. Louis, MO, and approved October 12, 2009 (received for review July 18, 2009) Cerebral lateralization is a fundamental property of the human Here we show strong evidence that multiple factors associate brain and a marker of successful development. Here we provide with asymmetry of distinct brain systems and provide a method evidence that multiple mechanisms control asymmetry for distinct to measure the degree of lateralization of each of these factors brain systems. Using intrinsic activity to measure asymmetry in 300 in individual subjects. We first developed an approach to quan- adults, we mapped the most strongly lateralized brain regions. tify functional laterality based on intrinsic activity fluctuations Both men and women showed strong asymmetries with a signif- using fMRI (23, 24). Factor analysis was then performed to icant, but small, group difference. Factor analysis on the asymmet- explore whether all lateralized brain systems arise from a ric regions revealed 4 separate factors that each accounted for common factor or through multiple, distinct factors. -
Which Side Are YOU On? Explore How Brain Dominance Affects Your Physical Abilities
Which Side Are YOU On? Explore how brain dominance affects your physical abilities. You probably know whether you’re right- or left-handed, but have you ever thought about whether you’re right- or left-footed? How could you find out? Try these experiments to see what you can discover! HERE’S WHAT YOU’LL NEED: • Access to a mirror • Pencil and paper • Access to a gym or • Stopwatch, timer or clock with a second hand basketball court • Tape • Kickball or soccer ball • Meter stick or tape measure • Basketball • Footstool We’ll begin by conducting some simple tests to learn more about brain dominance. Start by considering your hand dominance: WARMUPS • Which hand do you use to write? • Which hand do you primarily use to drink? • Which hand do you use to brush your teeth? Is the answer to all of these questions the same hand, or do you use different hands for different primary actions? Make a table where you can start recording your findings. Next, try these activities to help determine your foot dominance: • Kick a ball three or four times in a row without thinking about it too much. Which foot did you primarily use to kick the ball? • Step up onto a footstool three or four times in a row. Did you make the first step up onto the stool with one foot more often than the other? Record your findings in your table. Do your results indicate that you have a dominant foot? Is it the same as your dominant hand? Lastly, test your eye dominance: • Wink at yourself in the mirror a few times. -
Hemispheric Lateralization and Handedness Correlation of Human Evoked "Steady-State" Responses to Patterned Visual Stimuli
Phy siological Psy chology 1980, Vol. 8 (3), 409-416 Hemispheric lateralization and handedness correlation of human evoked "steady-state" responses to patterned visual stimuli W. R. KLEMM, W. D. GIBBONS, R. G. ALLEN, and E. O. RICHEY Laser Effects Branch, USAF School of Aerospace Medicine, Brooks Air Force Base, Texas 78235 We studied "steady-state" visual evoked potentials (VEPs) in 10 adult males (5 of whom were left-handed), using an alternating vertical-bar-pattern monocular stimulus in which the bar positions reversed at rates of 6,11, and 16 Hz. VEPs from electrodes over each hemisphere and midline were computer-averaged over 2 min and the average then subjected to spectral (Fourier) analyses. The stimulus reversals were square-wave regulated, and all subjects responded with near sine-wave spectral components (fundamental and some harmonics) at the corresponding reversal frequencies. Each subject developed larger responses at one of the stimulus frequencies (usually 6 Hz). Response magnitude at either the fundamental or harmonics of the stimulus frequency varied greatly across subjects. One of the specific hypotheses tested was that larger VEPs should develop after stimulation of the dominant eye; this could not be demonstrated. Two other hypotheses were verified: (1) VEPs should be lateralized and should correlate with handedness, and (2) some of the response received in a given hemisphere is physiologically re layed to the other hemisphere, and this occurs in both directions. Hemispheric lateralization occurred most clearly at each subject's optimum frequency. The "dominant" hemisphere for this kind of stimulus was always in the left hemisphere for the five right-handed subjects and in the right hemisphere for four of the left-handed subjects (the other left-hander had marked left-hemisphere dominance and also several right-handed behaviors).