Klingler’s method of brain dissection: review of the technique including its usefulness in practical neuroanatomy teaching, neurosurgery and neuroimaging

Wysiadecki, Grzegorz; Clarke, Edwin; Polguj, Michał; Haładaj, Robert; Żytkowski, Andrzej; Topol, Mirosław

doi:10.5603/fm.a2018.0113

Cited by 27 publications

(24 citation statements)

References 46 publications

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“…Postmortem dissections were performed using a modified Klingler technique 19 . While there have been documented modifications to this technique 19 , 20 , it was first described by Ludwig and Klingler et al in 1956 21 . Initial requirement was to freeze the brains to at least − 10°C 21 .…”

Section: Methodsmentioning

confidence: 99%

“…The purpose of the post-mortem dissections was to demonstrate the location of major tracts connecting to the lateral occipital lobe. Postmortem dissections were performed using a modified Klingler technique 19 . While there have been documented modifications to this technique 19,20 , it was first described by Ludwig and Klingler et al in 1956 21 .…”

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confidence: 99%

“…An example of brains frozen to temperatures up to − 80 °C is demonstrated by David et al 20 . The most comprehensive analysis of this technique is described by Wysiadecki et al 19 . There is no documented advantage to freezing temperatures beyond this point.…”

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confidence: 99%

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Anatomy and white matter connections of the fusiform gyrus

Palejwala

O’Connor

Milton

et al. 2020

Sci Rep

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the fusiform gyrus is understood to be involved in the processing of high-order visual information, particularly related to faces, bodies, and stimuli characterized by high spatial frequencies. A detailed understanding of the exact location and nature of associated white-tracts could significantly improve post-operative morbidity related to declining capacity. through generalized q-sampling imaging (GQi) validated by gross dissection as a direct anatomical method of identifying white matter tracts, we have characterized these connections based on relationships to other well-known structures. We created the white matter tracts using GQI and confirmed the tracts using gross dissection. These dissections demonstrated connections to the occipital lobe from the fusiform gyrus along with longer association fibers that course through this gyrus. The fusiform gyrus is an important region implicated in such tasks as the visual processing of human faces and bodies, as well as the perception of stimuli with high spatial frequencies. post-surgical outcomes related to this region may be better understood in the context of the fiber-bundle anatomy highlighted by this study. The fusiform gyrus, also known as the occipitotemporal gyrus, is a structure spanning the basal surface of the temporal and occipital lobes 1. It is the largest component of the human ventral temporal cortex, a functionallydefined region critical for visual categorization 1,2. Although the precise function of the fusiform gyrus has not yet been entirely revealed, it has been implicated in high-level tasks regarding visual processing, particularly the processing of information related to faces 3-5 , bodies 6,7 , and stimuli characterized by high spatial frequencies 8. The connection between the anatomical structure of the fusiform gyrus and this region's function remains contested 2,7. Clarification of the fiber-bundle anatomy and functional relationships inherent to the fusiform gyrus may have relevance to clinical applications such as operative planning for glioma resection and awake craniotomies. In addition, human neuroimaging studies have found that certain regions of the fusiform gyrus and its underlying white matter connections are related to a variety of conditions, such as developmental prosopagnosia 5,9,10 , pure alexia 8,11 , and anorexia nervosa. Nevertheless, direct correlations between surgical anatomy and functional connectivity of the fusiform gyrus have not been previously described in neurosurgical literature. A white matter tract identification technique consisting of gross brain dissection and generalized q-sampling tractography has been implemented previously to suggest links between form and function for other brain regions 12,13. Here we investigate the structural organization and network connectivity of the fusiform gyrus. Through GQI-based fiber tracking validated by gross dissection as a direct anatomical method of determining white matter connections 14 , we have characterized these tracts based on key connections and anatomical re...

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Section: Methodsmentioning

confidence: 99%

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confidence: 99%

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Anatomy and white matter connections of the fusiform gyrus

Palejwala

O’Connor

Milton

et al. 2020

Sci Rep

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“…The gyral organization in normal human brain may vary between individuals. Thus, an understanding of the anatomical variations in the human cortex may be important for neuroanatomy teaching, diagnostic neuroimaging and for neurosurgical procedures [10,12,13,16,18,27,28]. Anatomy of the hippocampal region is thought to be very complex and difficult to understand for non-specialized neurosurgeons or neurologists [6].…”

Section: Introductionmentioning

confidence: 99%

Anatomical variations of the dentate gyrus in normal adult brain

Haładaj

2019

Surg Radiol Anat

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Recent scientific papers indicate the clinical significance of the dentate gyrus. However, a detailed knowledge of the anatomical variations of this structure in normal adult brain is still lacking. An understanding of the variable morphology of the dentate gyrus may be important for diagnostic neuroimaging. Thus, the purpose of this macroscopic cadaveric study was to describe the anatomical variations of the dentate gyrus. Forty formalin-fixed human cerebral hemispheres, obtained from bodies of donors without the history of neuropathological diseases, were included in the study. The dentate gyrus was classified as well-developed, when it protruded completely from under the fimbria of the hippocampus. The gyrus was classified as underdeveloped, when it was covered by the fimbria of the hippocampus (but clearly visible at the coronal section of the hippocampal formation), while the hypoplastic gyrus was not visible macroscopically under the fimbria of the hippocampus. The well-developed type was observed in 27 cases (67.5%). The thickness of well-developed type of the dentate gyrus, measured between the fimbriodentate sulcus and hippocampal sulcus, varied from 2.74 to 5.21 mm (mean = 3.67 mm, median = 5.54 mm, SD 0.65 mm). In the next nine cases (22.5%), the dentate gyrus was underdeveloped. The thickness of underdeveloped type of the dentate gyrus varied from 1.75 to 2.37 mm (mean = 2.02 mm, median = 2.16 mm, SD 0.33 mm). In the remaining four cases (10%), the dentate gyrus was hypoplastic and could not be distinguished macroscopically. In all injected hemispheres, arterial supply of the dentate gyrus was provided by the branches of the posterior cerebral artery. Awareness of normal variations of the dentate gyrus may allow for better correlation of anatomical knowledge with radiological data and for use this knowledge to describe abnormal conditions.

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“…After removing half of the cortex above the insula, the EmC appears, consisting of association fibers connecting the insula and the operculum. Upon gentle removal of the insular cortex, from internal to external, external capsule, claustrum and EmC could be seen respectively, as well as putamen ( Wysiadecki et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

Extreme capsule is a bottleneck for ventral pathway

Shekari

Goudarzi

Shahriari

et al. 2021

IBRO Neuroscience Reports

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As neuroscience literature suggests, extreme capsule is considered a whiter matter tract. Nevertheless, it is not clear whether extreme capsule itself is an association fiber pathway or only a bottleneck for other association fibers to pass. Via our review, investigating anatomical position, connectivity and cognitive role of the bundles in extreme capsule, and by analyzing data from the dissection, it can be argued that extreme capsule is probably a bottleneck for the passage of uncinated fasciculus (UF) and inferior fronto-occipital fasciculus (IFOF), and these fasciculi are responsible for the respective roles in language processing.

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Klingler’s method of brain dissection: review of the technique including its usefulness in practical neuroanatomy teaching, neurosurgery and neuroimaging

Cited by 27 publications

References 46 publications

Anatomy and white matter connections of the fusiform gyrus

Anatomy and white matter connections of the fusiform gyrus

Anatomical variations of the dentate gyrus in normal adult brain

Extreme capsule is a bottleneck for ventral pathway

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