Your search keyword '"Briggs, Robert"' showing total 10 results

1. Anatomy and white-matter connections of the precuneus

Author

Tanglay, Onur, Young, Isabella M., Dadario, Nicholas B., Briggs, Robert G., Fonseka, R. Dineth, Dhanaraj, Vukshitha, Hormovas, Jorge, Lin, Yueh-Hsin, and Sughrue, Michael E.

Published

2022

2. Anatomy and white matter connections of the lateral occipital cortex

Author

Palejwala, Ali H., O’Connor, Kyle P., Pelargos, Panayiotis, Briggs, Robert G., Milton, Camille K., Conner, Andrew K., Milligan, Ty M., O’Donoghue, Daniel L., Glenn, Chad A., and Sughrue, Michael E.

Published

2020

3. Anatomy and White Matter Connections of the Middle Frontal Gyrus.

Author

Briggs, Robert G., Lin, Yueh-Hsin, Dadario, Nicholas B., Kim, Sihyong J., Young, Isabella M., Bai, Michael Y., Dhanaraj, Vukshitha, Fonseka, R. Dineth, Hormovas, Jorge, Tanglay, Onur, Chakraborty, Arpan R., Milligan, Ty M., Abraham, Carol J., Anderson, Christopher D., Palejwala, Ali H., Conner, Andrew K., O'Donoghue, Daniel L., and Sughrue, Michael E.

Subjects

*WHITE matter (Nerve tissue), *ANATOMY, *TEMPORAL lobe, *TREATMENT effectiveness, *SHORT-term memory, *VOXEL-based morphometry, *FUNCTIONAL magnetic resonance imaging

Abstract

The middle frontal gyrus (MFG) is involved in attention, working memory, and language-related processing. A detailed understanding of the subcortical white matter tracts connected within the MFG can facilitate improved navigation of white matter lesions in and around this gyrus and explain the postoperative morbidity after surgery. We aimed to characterize the fiber tracts within the MFG according to their connection to neuroanatomic structures through the use of diffusion spectrum imaging-based fiber tractography and validate the findings by gross anatomic dissection for qualitative visual agreement. Tractography analysis was completed using diffusion imaging data from 10 healthy, adult subjects enrolled in the Human Connectome Project. We assessed the MFG as a whole component according to its fiber connectivity with other neural regions. Mapping was completed on all tracts within both hemispheres, with the resultant tract volumes used to calculate a lateralization index. A modified Klingler technique was used on 10 postmortem dissections to demonstrate the location and orientation of the major tracts. Two major connections of the MFG were identified: the superior longitudinal fasciculus, which connects the MFG to parts of the inferior parietal lobule, posterior temporal lobe, and lateral occipital cortex; and the inferior fronto-occipital fasciculus, which connected the MFG to the lingual gyrus and cuneus. Intra- and intergyral short association, U-shaped fibers were also identified. Subcortical white matter pathways integrated within the MFG include the superior longitudinal fasciculus and inferior fronto-occipital fasciculus. The MFG is implicated in a variety of tasks involving attention and memory, making it an important cortical region. The postoperative neurologic outcomes related to surgery in and around the MFG could be clarified in the context of the anatomy of the fiber bundles highlighted in the present study. [ABSTRACT FROM AUTHOR]

Published

2021

4. Anatomy and white matter connections of the lateral occipital cortex.

Author

Palejwala, Ali H., O'Connor, Kyle P., Pelargos, Panayiotis, Briggs, Robert G., Milton, Camille K., Conner, Andrew K., Milligan, Ty M., O'Donoghue, Daniel L., Glenn, Chad A., and Sughrue, Michael E.

Subjects

WHITE matter (Nerve tissue), OCCIPITAL lobe, ANATOMY, FACE perception, PREOPTIC area, BRAIN imaging

Abstract

Purpose: White matter tracts link different regions of the brain, and the known functions of those interconnected regions may offer clues about the roles that white matter tracts play in information relay. The authors of this report discuss the structure and function of the lateral occipital lobe and how the lateral occipital lobe communicates with other regions via white matter tracts. Methods: The authors used generalized q-sampling imaging and cadaveric brain dissections to uncover the subcortical white matter connections of the lateral occipital lobe. The authors created GQI of ten healthy controls and dissected ten cadaveric brains. Results: The middle longitudinal fasciculus, vertical occipital fasciculus, inferior fronto-occipital fasciculus, inferior longitudinal fasciculus, optic radiations, and a diverse array of U-shaped fibers connect the lateral occipital lobe to itself, parts of the temporal, parietal, and medial occipital cortices. The complex functional processes attributed to the lateral occipital lobe, including object recognition, facial recognition, and motion perception are likely related to the subcortical white matter tracts described within this study. Conclusions: There was good concordance between the white matter tracts generated using GQI and the white matter tracts that were found after dissection of the cadaveric brains. This article presents the anatomic connections of the lateral occipital lobe and discusses the associated functions. [ABSTRACT FROM AUTHOR]

Published

2021

5. A connectomic atlas of the inferior longitudinal fasciculus.

Author

Salı, Göksel, Briggs, Robert G., Conner, Andrew K., Rahimi, Meherzad, Baker, Cordell M., Burks, Joshua D., Glenn, Chad A., Smitherman, Adam D., Mccoy, Tressie M., Battiste, James D., O'donoghue, Daniel L., and Sughrue, Michael E.

Subjects

*WHITE matter (Nerve tissue), *HIGHER nervous activity, *BRAIN mapping

Abstract

Objective: The Inferior Longitudinal Fasciculus (ILF) is one of the major white matter tract bundles connecting key cortical areas of the cerebrum. The location, functional connectivity, and structural connectivity of the cortical regions giving rise to the ILF have previously been described. Using these data we demonstrate the extent and anatomical boundaries of the ILF. Methods: We built an anatomic model of the ILF based on the parcellation scheme previously published under the Human Connectome Project. Through Diffusion Spectrum Imaging, we demonstrate the tractography of this fasciculus arising from its relevant cortical regions, and show a tract map summarizing those regions with white matter connections specific to the ILF. Results: The ILF extends from the ventral and lateral temporal cortices to parts of the occipital lobe. Seven parcellations of the temporal lobe and one from the posterior parietal lobe demonstrate structural connectivity in the distribution of the ILF. Most demonstrate fiber tracts via the ILF to early visual areas, V1-V4. Conclusion: The literature describes several critical functions to the ILF including visual processing, object recognition, reading disturbance, emotional processing, facial recognition, ventral semantic processing, visual hallucinations, and arithmetic. Precisely what cortical information is integrated and transferred from the occipital lobe to areas of the temporal and parietal lobes remains poorly understood. Our connection model of the ILF is one step forward towards elucidating these processes. We show the anatomic connections of the ILF and define the cortical regions from which the ILF arises. Future studies will refine this model for clinical application. [ABSTRACT FROM AUTHOR]

Published

2018

6. Anatomy and White Matter Connections of the Lingual Gyrus and Cuneus.

Author

Palejwala, Ali H., Dadario, Nicholas B., Young, Isabella M., O'Connor, Kyle, Briggs, Robert G., Conner, Andrew K., O'Donoghue, Daniel L., and Sughrue, Michael E.

Subjects

*WHITE matter (Nerve tissue), *OCCIPITAL lobe, *ANATOMY, *VERBAL memory, *QUALITY of life, *VOXEL-based morphometry, *BRAIN imaging

Abstract

The medial occipital lobe, composed of the lingual gyrus and cuneus, is necessary for both basic and higher level visual processing. It is also known to facilitate cross-modal, nonvisual functions, such as linguistic processing and verbal memory, after the loss of the visual senses. A detailed cortical model elucidating the white matter connectivity associated with this area could improve our understanding of the interacting brain networks that underlie complex human processes and postoperative outcomes related to vision and language. Generalized q-sampling imaging tractography, validated by gross anatomic dissection for qualitative visual agreement, was performed on 10 healthy adult controls obtained from the Human Connectome Project. Major white matter connections were identified by tractography and validated by gross dissection, which connected the medial occipital lobe with itself and the adjacent cortices, especially the temporal lobe. The short- and long-range connections identified consisted mainly of U-shaped association fibers, intracuneal fibers, and inferior fronto-occipital fasciculus, inferior longitudinal fasciculus, middle longitudinal fasciculus, and lingual–fusiform connections. The medial occipital lobe is an extremely interconnected system, supporting its ability to perform coordinated basic visual processing, but also serves as a center for many long-range association fibers, supporting its importance in nonvisual functions, such as language and memory. The presented data represent clinically actionable anatomic information that can be used in multimodal navigation of white matter lesions in the medial occipital lobe to prevent neurologic deficits and improve patients' quality of life after cerebral surgery. [ABSTRACT FROM AUTHOR]

Published

2021

7. Anatomy and White Matter Connections of the Parahippocampal Gyrus.

Author

Lin, Yueh-Hsin, Dhanaraj, Vukshitha, Mackenzie, Alana E., Young, Isabella M., Tanglay, Onur, Briggs, Robert G., Chakraborty, Arpan R., Hormovas, Jorge, Fonseka, R. Dineth, Kim, Sihyong J., Yeung, Jacky T., Teo, Charles, and Sughrue, Michael E.

Subjects

*WHITE matter (Nerve tissue), *COGNITIVE ability, *ANATOMY, *EXECUTIVE function, *HUMAN dissection, *VOXEL-based morphometry, TUMOR surgery

Abstract

The parahippocampal gyrus is understood to have a role in high cognitive functions including memory encoding and retrieval and visuospatial processing. A detailed understanding of the exact location and nature of associated white tracts could significantly improve postoperative morbidity related to declining capacity. Through diffusion tensor imaging−based fiber tracking validated by gross anatomic dissection as ground truth, we have characterized these connections based on relationships to other well-known structures. Diffusion imaging from the Human Connectome Project for 10 healthy adult controls was used for tractography analysis. We evaluated the parahippocampal gyrus as a whole based on connectivity with other regions. All parahippocampal gyrus tracts were mapped in both hemispheres, and a lateralization index was calculated with resultant tract volumes. We identified 2 connections of the parahippocampal gyrus: inferior longitudinal fasciculus and cingulum. Lateralization of the cingulum was detected (P < 0.05). The parahippocampal gyrus is an important center for memory processing. Subtle differences in executive functioning following surgery for limbic tumors may be better understood in the context of the fiber-bundle anatomy highlighted by this study. [ABSTRACT FROM AUTHOR]

Published

2021

8. Parcellation‐based anatomic modeling of the default mode network.

Author

Sandhu, Zainab, Tanglay, Onur, Young, Isabella M., Briggs, Robert G., Bai, Michael Y., Larsen, Micah L., Conner, Andrew K., Dhanaraj, Vukshitha, Lin, Yueh‐Hsin, Hormovas, Jorge, Fonseka, Rannulu Dineth, Glenn, Chad A., and Sughrue, Michael E.

Subjects

*PARIETAL lobe, *CINGULATE cortex, *WHITE matter (Nerve tissue), *FUNCTIONAL magnetic resonance imaging, *DEFAULT mode network

Abstract

Background: The default mode network (DMN) is an important mediator of passive states of mind. Multiple cortical areas, such as the anterior cingulate cortex, posterior cingulate cortex, and lateral parietal lobe, have been linked in this processing, though knowledge of network connectivity had limited tractographic specificity. Methods: Using resting‐state fMRI studies related to the DMN, we generated an activation likelihood estimation (ALE). We built a tractographical model of this network based on the cortical parcellation scheme previously published under the Human Connectome Project. DSI‐based fiber tractography was performed to determine the structural connections between cortical parcellations comprising the network. Results: Seventeen cortical regions were found to be part of the DMN: 10r, 31a, 31pd, 31pv, a24, d23ab, IP1, p32, POS1, POS2, RSC, PFm, PGi, PGs, s32, TPOJ3, and v23ab. These regions showed consistent interconnections between adjacent parcellations, and the cingulum was found to connect the anterior and posterior cingulate clusters within the network. Conclusions: We present a preliminary anatomic model of the default mode network. Further studies may refine this model with the ultimate goal of clinical application. [ABSTRACT FROM AUTHOR]

Published

2021

9. Anatomy and White Matter Connections of the Inferior Temporal Gyrus.

Author

Lin, Yueh-Hsin, Young, Isabella M., Conner, Andrew K., Glenn, Chad A., Chakraborty, Arpan R., Nix, Cameron E., Bai, Michael Y., Dhanaraj, Vukshitha, Fonseka, R. Dineth, Hormovas, Jorge, Tanglay, Onur, Briggs, Robert G., and Sughrue, Michael E.

Subjects

*WHITE matter (Nerve tissue), *ANATOMY, *BRAIN

Abstract

The inferior temporal gyrus (ITG) is known to be involved in high-cognitive functions, including visual and language comprehensions and emotion regulation. A detailed understanding of the nature of association fibers could significantly improve postoperative morbidity related to declining capacity. Through diffusion spectrum imaging−based fiber tracking, we have characterized these connections on the basis of their relationships to other cortical areas. Diffusion spectrum images from 10 healthy adults of the Human Connectome Project were randomly selected and used for tractography analysis. We evaluated the ITG as a whole based on connectivity with other regions. All ITG tracts were mapped in both hemispheres, and a lateralization index was calculated with resultant tract volumes. We identified 5 major connections of the ITG: U-fiber, inferior longitudinal fasciculus, vertical occipital fasciculus, arcuate fasciculus, and uncinate fasciculus. There was no fiber lateralization detected. This study highlights the principal white-matter pathways of the ITG and demonstrates key underlying connections. We present a summary of the relevant clinical anatomy for this region of the cerebrum as part of a larger effort to understand it in its entirety. [ABSTRACT FROM AUTHOR]

Published

2020

10. White matter connections of the inferior parietal lobule: A study of surgical anatomy.

Author

Burks, Joshua D., Boettcher, Lillian B., Conner, Andrew K., Glenn, Chad A., Bonney, Phillip A., Baker, Cordell M., Briggs, Robert G., Pittman, Nathan A., O'Donoghue, Daniel L., Wu, Dee H., and Sughrue, Michael E.

Subjects

*SURGICAL & topographical anatomy, *WHITE matter (Nerve tissue), *PARIETAL lobe, *UNILATERAL neglect, *COGNITIVE ability, *DIFFUSION tensor imaging, *SEMANTIC networks (Information theory), *PHYSIOLOGY

Abstract

Introduction Interest in the function of the inferior parietal lobule (IPL) has resulted in increased understanding of its involvement in visuospatial and cognitive functioning, and its role in semantic networks. A basic understanding of the nuanced white-matter anatomy in this region may be useful in improving outcomes when operating in this region of the brain. We sought to derive the surgical relationship between the IPL and underlying major white-matter bundles by characterizing macroscopic connectivity. Methods Data of 10 healthy adult controls from the Human Connectome Project were used for tractography analysis. All IPL connections were mapped in both hemispheres, and distances were recorded between cortical landmarks and major tracts. Ten postmortem dissections were then performed using a modified Klingler technique to serve as ground truth. Results We identified three major types of connections of the IPL. (1) Short association fibers connect the supramarginal and angular gyri, and connect both of these gyri to the superior parietal lobule. (2) Fiber bundles from the IPL connect to the frontal lobe by joining the superior longitudinal fasciculus near the termination of the Sylvian fissure. (3) Fiber bundles from the IPL connect to the temporal lobe by joining the middle longitudinal fasciculus just inferior to the margin of the superior temporal sulcus. Conclusions We present a summary of the relevant anatomy of the IPL as part of a larger effort to understand the anatomic connections of related networks. This study highlights the principle white-matter pathways and highlights key underlying connections. [ABSTRACT FROM AUTHOR]

Published

2017