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Heschl's Gyrus

 

Heschl's Gyrus

Heschl's Gyrus is a convolution or fold of the temporal lobe of the brain and is the cortical center for hearing. It runs obliquely outward and forward from the posterior, or back part of the lateral sulcus. ^[1] This brain area is also known as the Transverse temporal gyrus. This gyrus was first described by an Austrian named Richard Heschl during the 1850's. The main functions of the structure have been found to be related to audition or hearing since it serves as a piece of the primary auditory cortex. Tumors to this brain area have been found to cause problems related to verbal processing and may contribute to the development of certain psychological disorders. Future research advocates for the use of more advanced technology to develop a more complete understanding of the function of the gyrus, as well as the consequences of abnormalities of the structure.

History

 

Richard L. Heschl

Richard L. Heschl (1824-81) is the man credited for first describing the transverse temporal gyrus ^[2]. Heschl was born in Austria in 1824 and attended the University of Vienna where he later became a professor of pathological anatomy ^[2]. While at the University of Vienna, he wrote many pieces that impacted the scientific community at the time, including a compendium of pathological anatomy. He also described a new method of biological tissue staining called metachromasia that is still used today in detecting the pathology of amyloidosis ^[2].

There are many folds in the cerebral cortex or surface layer of the brain. The depressions are known as sulci and the ridges are known as gyri. It is hypothesized that these folds allow the brain more capacity for storage, retrieval, and other brain activity ^[3]. These convolutions were first described by various scientists including Adolph Pansch, Pozzi, Ecker, Giacomini, and Heschl. ^[4] Heschl described the transverse temporal gyrus as “a convolution springing from the first temporal convolution about the middle of the lower border of the Sylvian fissure and ending either singly or by joining the second temporal gyrus” ^[4].

Structure and Function

 

Lobes of the Brain

Heschl's gyrus is located bilaterally on the temporal plane. It serves as a general marker for the location of the primary auditory cortex, which still cannot be localized exactly. The primary auditory cortex was identified over 100 years ago, but due to human genetic variation and technology limitations it has not been routinely identifiable in the living human brain ^[5].

Studies have been done in attempt to relate variations in the structure of human brain anatomy to variations in the functioning of Heschl's Gyrus. ^[6]. One such study addressed this by relating physical measurements of Heschl's Gyrus to how the region processes acoustic information ^[6]. Volume measurements were taken from subjects and as predicted a large amount of structural variation was found. Auditory responses were then recorded using an MRI and the results found structure to be related to function. The larger the volume of Heschl's Gyrus in the right side of the brain, the more cortex response was associated with temporal, or time processing. The larger the volume on the right, the more spatially related cortex was activated ^[6]. This study helps support one of the overarching theories of science that form dictates function.

Brain areas of the temporal plane respond differently to various sounds in the environment according to spatial arrangement. This is known as tonotopy. Studies have been able to identify tonotopy in the temporal lobes of monkeys. ^[7] The studies used fMRI readings to map out which brain areas respond to which types of sound frequencies. The relation between the structure and function of a monkey's brain is identifiable through these maps, but technology has not allowed for this research in humans as of yet. This is due to the small size of this brain region in humans in relation to the current instruments available for inspection. ^[8]

Research

Heschl's gyrus has been the focus of various areas of research. Such areas include: research in mental illness (for example schizophrenia and bipolar disorder), as well as research on pitch perception and acoustic processing.

Mental Illness

Mental Illness is any condition characterized by abnormalities in cognitive, emotional, or behavioral functioning. Mental Illness can be caused by social, psychological, biochemical, genetic, or other factors, such as infection or head trauma ^[9]. Examples of mental illness include bipolar disorder, anxiety disorder, schizophrenia, and personality disorders among others. In relation to Heschl's Gyrus there has been more research pertaining to schizophrenic symptoms than there has been to other mental illnesses.

The relationship between schizophrenic auditory hallucinations and Heschl's Gyrus has been an expanding area of study. Early studies on this topic found little to no relationship between schizophrenia and Heschl's Gyrus. ^[10] A 2004 study by David Cotter and company investigated cell density and cortical thickness of Heschl's Gyrus in order to determine any cellular differences between post-mortem patients with diagnoses of either major depressive disorder, schizophrenia and/or bipolar disorder. These were compared to normal experimental controls. No difference was found between the patient group and the control group so it was concluded that there was no support for the presence of cellular pathology within Heschl's Gyrus in schizophrenia. Looking at the size of brain matter, however, is only one way to compare differences between groups. Another method includes comparing the various connections of cells and this technique has been used in more recent studies.

 

Cloth Embroidered by Schizophrenia Sufferer Shows Peak Inside The Mind

This evolution in thinking beyond size comparisons mirrors the thinking of cognitive science as a whole. In the past it was thought that the larger a species' brain size the more intelligence the species possessed ^[11]. This was eventually refuted as it was shown that body size plays a role in brain size. Whales for example have larger brains than humans. Later, relative size of cortex was thought to equate with intelligence, but this view was also difficult to uphold ^[11]. More currently, the amount of brain cell connections are being researched to determine intelligence and proper functioning ^[11].

In a more recent 2012 study by Shinn and company some support was found for Heschl’s Gyrus playing a role in auditory hallucinations, which are a symptom of schizophrenia. ^[12] This study used a resting-state fMRI to investigate the connectivity of the primary auditory cortex, located on Heschl's Gyrus, in patients with schizophrenia induced auditory hallucinations ^[12]. The results showed that increased left hemisphere Heschl's Gyrus connectivity was positively related to hallucination severity in other brain areas. It was then concluded that abnormal interactions between the left Heschl's gyrus and the brain regions involved in speech/language, memory, and the monitoring of self-generated events may contribute to propensity for hallucinations ^[12]. Similar studies have been conducted that support the role of primary auditory cortex abnormalities in auditory hallucinations ^{[13] [14] [15] [16]}.

Another school of thought advocates that auditory hallucinations cause the abnormalities witnessed in Heschl's Gyrus, and are not an underlying symptom of schizophrenia. A study by Daniela Hubl and company compared the volume of Heschl's Gyrus in patients with schizophrenia induced auditory hallucinations with those without auditory hallucinations. The study found a higher volume of Heschl's Gyrus in the right hemisphere of patients with hallucinations than those without ^[17]. The scientists conducting this study suggested that the volume increases of Heschl's Gyrus were caused by the hallucinations and not by the underlying disorder of schizophrenia.

There are a variety of techniques and methods involved in the study of the brain, as well as a variety of schools of thought related to the topic. Each process and mode adds more information to the scientific community in its own way and aids in better understanding of the role of Heschl's Gyrus in mental illness. Cognitive Science as a subject increases knowledge in a similar interdisciplinary fashion, combining information learned from a variety of faculties, from cognitive psychology, to neuroscience, to computer science. ^[18].

Acoustic Processing

Heschl's Gyrus is one of the primary centers for hearing in the brain. Studies have been performed to better understand how pitch perception and acoustic processing occur in the brain.

A much cited study by Peter Schneider and company demonstrated that pitch perception localization varies based on the type of listener. There are two different types of pitches, f(0) or f(sp) and depending on the subjects dominant perceptual mode, localization will occur in either the right or left hemisphere. It was found that F(0) listeners had more right hemisphere localization and f(sp) listeners had more left hemisphere localization ^[19]. Localization in this sense refers to the area where brain activity is highest upon exposure to a certain stimulus.

This study was supplemented by a second study from the same colleagues, which supported that pitch preferences in Heschl's Gyrus occur regardless of musical ability ^[20]. This study also demonstrated that relative size of Heschl's Gyrus may be related to musical ability. The study used MRI scanning to examine and compare activity in Heschl's Gyrus of 334 professional musicians, 75 amateur musicians, and 54 non-musicians. Researchers such as Sebastian Puschmann were still not convinced that localization of pitch was due to perception and not stimulation.

Puschmann and his colleagues conducted a study using dichotic pitch stimuli in order to ensure that it was indeed pitch that was being perceived in Heschl's Gyrus and not just any sound stimulus. The study found that the lateral end of Heschl's gyrus was equally activated for sequences of fixed pitch or random pitch which supports prior research that the brain area is critical to the perception and evaluation of pitch information. The research concluded that Heschl's Gyrus might represent a general pitch processing centre in humans ^[21].

A study by John Brugge was conducted to compare the progression that Heschl's Gyrus undergoes for auditory processing in humans compared to monkeys. There is a deeper understanding of the structure and function of the primary auditory cortex in monkeys than there is in humans due to the ability to perform more invasive tests and the flatter structure of the monkey brain area. One technique used in science to understand more about humans is to compare human anatomy to their closest relatives; primates. In the study by Brugge it was found that auditory processing in monkeys was similar to humans. The study used electrodes implanted into the Heschl's Gyrus area of 15 patients to record results of brain activity. Researches exposed subjects to click sounds of varying rates. It was found that two auditory fields seemed to exist. A core field of the Gyrus could detect slower click rates, up until 200Hz, and a separate field responded to the highest click rates of the study. ^[22]. The study concluded that auditory processing may occur in a similar fashion across humans and primates.

Directions for Future Research

The future understanding of Heschl's Gyrus will depend on new technological innovations. As microscopes and scanning systems are able to view brain areas at the neuronal level, a deeper understanding of the structure and function of Heschl's Gyrus will come about. Developing a tonotopic map of this structure should be researched in the future in order to more accurately identify the primary auditory cortex in humans. Understanding more about the transverse temporal gyrus could help in finding a cure, or prevention method, for schizophrenia and other mental illnesses. Once more, basic research has been conducted on this topic. Scientists and psychologists should apply this knowledge in order to benefit society.

See Also

Below are links to other articles on areas of the brain related to Heshcl's Gyrus, for those interested in understanding the connections of the brain in more detail.

• Lobes of the brain
• Broca's area
• Wernicke's area
• Superior temporal area 22
• Brodmann area

References

1. "Heschl's gyrus". 2013. In Merriam-Webster.com. Retrieved February 28th, 2013, from http://www.merriam-webster.com/dictionary/heschl'sgyrus
2. Aternman, K. (1976). A PRETTY A VISTA REACTION FOR TISSUES WITH AMYLOID DEGENERATION," 1875: AN IMPORTANT YEAR FOR PATHOLOGY. Journal Of The History Of Medicine & Allied Sciences, 31(4), 431-447
3. White, T., & Hilgetag, C. C. (2008). Gyrification and development of the human brain. Cambridge, MA, US: MIT Press, Cambridge, MA. Retrieved from https://www.lib.uwo.ca/cgi-bin/ezpauthn.cgi/docview/622167193?accountid=15115.
4. Humphrey, G. M., Turner, W. M., McKendrick, J. G., & Creighton, C. (1879). Journal of anatomy and physiology. (Vol. XIII, p. 270). London and Cambridge: Macmillan and Co. Retrieved from http://books.google.ca/books?id=_dsDAAAAYAAJ&pg=PA277&lpg=PA277&dq=pansch convolutions brain&source=bl&ots=LJnKJuY3Nc&sig=XFntpyu3ceOuMvAGuAbBND2XF8c&hl=en&sa=X&ei=OENLUdiaCtHbqwHCyYG4Dg&ved=0CC4Q6AEwAA
5. Rauschecker JP, Tian B,Pons T,Mishkin M(1997) Serial and parallel processing in rhesus monkey auditory cortex. J Comp Neurol 382:89–103
6. Warrier, C., Wong, P., Penhune, V., Zatorre, R., Parrish, T., Abrams, D., & Kraus, N. (2009). Relating structure to function: Heschl’s gyrus and acoustic processing. The Journal of Neuroscience, 29(1), 61-69. doi: http://dx.doi.org/10.1523/JNEUROSCI.3489-08.2009
7. Rauschecker JP, Tian B,Pons T,Mishkin M(1997) Serial and parallel processing in rhesus monkey auditory cortex. J Comp Neurol 382:89–103
8. Da Costa, S., van, d. Z., Marques, J. P., Frackowiak, R. S. J., Clarke, S., & Saenz, M. (2011). Human primary auditory cortex follows the shape of heschl's gyrus. The Journal of Neuroscience, 31(40), 14067-14075. doi: http://dx.doi.org/10.1523/JNEUROSCI.2000-11.2011
9. mental illness. (n.d.) The American Heritage® Dictionary of the English Language, Fourth Edition. (2003). Retrieved March 21 2013 from http://www.thefreedictionary.com/mental+illness
10. Cotter, David, Daniel Mackay, Sophia Frangou, Lance Hudson, and Sabine Landau. 2004. Cell density and cortical thickness in Heschl's Gyrus in schizophrenia, major depression and bipolar disorder. The British Journal of Psychiatry 185, (3): 258-259, https://www.lib.uwo.ca/cgi-bin/ezpauthn.cgi/docview/620507511?accountid=15115 (accessed March 21, 2013).
11. Workman, L., & Reader, W. (2008). Evolutionary psychology: An introduction. (2nd ed.). New York: Cambridge University Press
12. Shinn, A. K., Baker, J. T., Cohen, B. M., & Öngür, D. (2012). Functional connectivity of left heschl's gyrus in vulnerability to auditory hallucinations in schizophrenia. Schizophrenia Research, doi: http://dx.doi.org/10.1016/j.schres.2012.11.037
13. McCarley, R.W., Wible, C.G., Frumin, M., Hirayasu, Y., Levitt, J.J., Fischer, I.A., Shenton, M.E., 1999. MRI anatomy of schizophrenia. Biol. Psychiatry 45, 1099–1119
14. Allen, P., Laroi, F., McGuire, P.K., Aleman, A., 2008. The hallucinating brain: a review of structural and functional neuroimaging studies of hallucinations. Neurosci. Biobehav.Rev. 32 (1), 175–191
15. Modinos, G., Costafreda, S.G., van Tol, M.J., McGuire, P.K., Aleman, A., Allen, P., 2012. Neuroanatomy of auditory verbal hallucinations in schizophrenia: a quantitative meta-analysis of voxel-based morphometry studies. Cortex (Electronic publica-tion ahead of print February 1, 2012)
16. Sweet, R.A., Bergen, S.E., Sun, Z., Sampson, A.R., Pierri, J.N., Lewis, D.A., 2004. Pyramidal cell size reduction in schizophrenia: evidence for involvement of auditory feedforward circuits. Biol. Psychiatry 55 (12), 1128–1137
17. Hubl, D., Dougoud-Chauvin, V., Zeller, M., Federspiel, A., Boesch, C., Strik, W., . . . Koenig, T. (2009). Structural analysis of heschl's gyrus in schizophrenia patients with auditory hallucinations. Neuropsychobiology, 61(1), 1-9. doi: http://dx.doi.org/10.1159/000258637
18. Friedenberg, J., & Silverman, G. (2012). Cognitive science: An introduction to the study of mind. Los Angeles: Sage Publications Inc.
19. Schneider, Peter, Vanessa Sluming, Neil Roberts, Michael Scherg, Rainer Goebel, Hans J. Specht, H. Gü Dosch, Stefan Bleeck, Christoph Stippich, and André Rupp. 2005. Structural and functional asymmetry of lateral heschl's gyrus reflects pitch perception preference. Nature neuroscience 8, (9): 1241-1247, https://www.lib.uwo.ca/cgi-bin/ezpauthn.cgi/docview/620876285?accountid=15115 (accessed March 22, 2013).
20. Schneider, Peter, Vanessa Sluming, Neil Roberts, Stefan Bleeck, and André Rupp. 2005. Structural, functional, and perceptual differences in Heschl's gyrus and musical instrument preference. In , 387-394. New York, NY, US: New York Academy of Sciences, New York, NY, https://www.lib.uwo.ca/cgi-bin/ezpauthn.cgi/docview/621200375?accountid=15115 (accessed March 22, 2013).
21. Puschmann, Sebastian, Stefan Uppenkamp, Birger Kollmeier, and Christiane M. Thiel. 2010. Dichotic pitch activates pitch processing centre in heschl's gyrus. NeuroImage 49, (2): 1641-1649, https://www.lib.uwo.ca/cgi-bin/ezpauthn.cgi/docview/622185609?accountid=15115 (accessed March 22, 2013).
22. Brugge, John F., Kirill V. Nourski, Hiroyuki Oya, Richard A. Reale, Hiroto Kawasaki, Mitchell Steinschneider, and Matthew A. Howard. 2009. Coding of repetitive transients by auditory cortex on heschl's gyrus. Journal of neurophysiology 102, (4): 2358-2374, https://www.lib.uwo.ca/cgi-bin/ezpauthn.cgi/docview/621977774?accountid=15115 (accessed March 22, 2013).

v t e Human brain: forebrain (cerebrum, cerebral cortex, cerebral hemispheres, grey matter) (TA A14.1.09.002–240, 301–320, GA 9.818–826)
Frontal lobe	Superolateral Prefrontal Superior frontal gyrus 4l 6l 8l Middle frontal gyrus 9l 10l 46 Inferior frontal gyrus: 11l 47-Pars orbitalis Broca's area 44-Pars opercularis 45-Pars triangularis Superior frontal sulcus Inferior frontal sulcus Precentral Precentral gyrus Precentral sulcus Medial/inferior Prefrontal Superior frontal gyrus 4m 6m Medial frontal gyrus 8m 9m Paraterminal gyrus/Paraolfactory area 12 Straight gyrus 11m Orbital gyri/Orbitofrontal cortex 10m 11m 12 Ventromedial prefrontal cortex 10m Subcallosal area 25 Olfactory sulcus Orbital sulci Precentral Paracentral lobule 4 Paracentral sulcus Both Primary motor cortex 4 Premotor cortex 6 Supplementary motor area 6 Frontal eye fields 8
Parietal lobe	Superolateral Superior parietal lobule 5l 7l Inferior parietal lobule 40-Supramarginal gyrus 39-Angular gyrus Parietal operculum 43 Intraparietal sulcus Medial/inferior Paracentral lobule 1m 2m 3m 5m Precuneus 7m Marginal sulcus Both Postcentral gyrus/primary somatosensory cortex 1 2 3 Secondary somatosensory cortex 5 Posterior parietal cortex 7
Occipital lobe	Superolateral Occipital pole of cerebrum Lateral occipital gyrus 18 19 Lunate sulcus Transverse occipital sulcus Medial/inferior Primary visual cortex 17 Cuneus Lingual gyrus Calcarine fissure
Temporal lobe	Superolateral Transverse temporal gyrus/Primary auditory cortex 41 42 Superior temporal gyrus 38 22/Wernicke's area Middle temporal gyrus 21 Inferior temporal gyrus 20 Superior temporal sulcus Inferior temporal sulcus Medial/inferior Fusiform gyrus 37 Medial temporal lobe 27 28 34 35 36 Inferior temporal sulcus
Interlobar sulci/fissures	Superolateral Central (frontal+parietal) Lateral (frontal+parietal+temporal) Parieto-occipital Preoccipital notch Medial/inferior Medial longitudinal Cingulate (frontal+cingulate) Collateral (temporal+occipital) Callosal sulcus
Limbic lobe	Parahippocampal gyrus anterior Entorhinal cortex Perirhinal cortex Posterior parahippocampal gyrus Prepyriform area Cingulate cortex/gyrus Subgenual area 25 Anterior cingulate 24 32 33 Posterior cingulate 23 31 Isthmus of cingulate gyrus: Retrosplenial cortex 26 29 30 Hippocampal formation Hippocampal sulcus Fimbria of hippocampus Dentate gyrus Rhinal sulcus Other Supracallosal gyrus Uncus
Insular lobe	Long gyrus of insula Short gyri of insula Circular sulcus of insula
General	Operculum Poles of cerebral hemispheres
Some categorizations are approximations, and some Brodmann areas span gyri. v t e Index of the central nervous system Description Anatomy meninges cortex association fibers commissural fibers lateral ventricles basal ganglia diencephalon mesencephalon pons cerebellum medulla spinal cord tracts Physiology neutrotransmission enzymes intermediates Development Disease Addiction Cerebral palsy Meningitis Demyelinating diseases Seizures and epilepsy Headache Stroke Sleep Congenital Injury Neoplasms and cancer Other paralytic syndromes ALS Symptoms and signs eponymous lesions Tests CSF Treatment Procedures Drugs general anesthetics analgesics dependence epilepsy cholinergics migraine Parkinson's vertigo other

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