Automatic three-dimensional reconstruction of fascicles in peripheral nerves from histological images

Tovbis, Daniel; Agur, Anne; Mogk, Jeremy P.M.; Zariffa, José

doi:10.1371/journal.pone.0233028

Cited by 9 publications

(4 citation statements)

References 26 publications

(37 reference statements)

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“…Deep-learning based algorithms have recently received attention in anatomically guided, medical image segmentation [ 90 ]. With regard to segmentation of anatomical features of nerves, deep-learning algorithms have been used on EM images, to resolve single fibers, and on ultrasound [ 91 ] and histological images [ 92 ], to resolve fascicles. To the best of our knowledge, this is the first use of convolutional neural networks on micro-CT and IHC data, to segment and extract anatomical features from micro-CT or IHC data in a user-assisted, semi-automated manner.…”

Section: Discussionmentioning

confidence: 99%

Organ- and function-specific anatomical organization of vagal fibers supports fascicular vagus nerve stimulation

Jayaprakash¹,

Song²,

Tóth³

et al. 2023

Brain Stimulation

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Section: Discussionmentioning

confidence: 99%

Organ- and function-specific anatomical organization of vagal fibers supports fascicular vagus nerve stimulation

Jayaprakash¹,

Song²,

Tóth³

et al. 2023

Brain Stimulation

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“…Another minor limitation of our simulations was the necessity of estimating the position of the vagus nerve within the neurovascular bundle, which was due to the limited resolution of the images obtained from the Visible Human Project. Future histologic studies could improve the precision of the model by extracting vagus nerve position data at regular intervals along the cervical vagus nerve, and then reconstructing the nerve as in situ [51]. Magnetic resonance neurography could also be performed to acquire in-vivo images of the vagus nerve within the cervical region; this could be done on multiple volunteers to allow for comparison between individuals.…”

Section: Discussionmentioning

confidence: 99%

Enhancing the selective electrical activation of human vagal nerve fibers: a comparative computational modeling study with validation in a rat sciatic model

Tovbis,

Lee,

Koh

et al. 2023

J. Neural Eng.

Self Cite

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Vagus Nerve Stimulation (VNS) is an emerging treatment option for a myriad of medical disorders, where the method of delivering electrical pulses can vary depending on the clinical indication. In this study, we investigated the relative effectiveness of electrically activating the cervical vagus nerve among three different approaches: nerve cuff electrode stimulation (NCES), transcutaneous electrical nerve stimulation (TENS), and enhanced TENS (eTENS). The objectives were to characterize factors that influenced nerve activation and to compare the nerve recruitment properties as a function of nerve fiber diameter. The Finite Element Model, based on data from the Visible Human Project, was implemented in COMSOL. The three simulation types were compared under a range of vertical and horizontal displacements relative to the location of the vagus nerve. Monopolar anodic stimulation was examined, along with latency and activation of different fiber sizes. Nerve activation was determined via the activating function and McIntyre-Richardson-Grill models, and activation thresholds were validated in an in-vivo rodent model. While NCES produced the lowest activation thresholds, eTENS generally performed superior to TENS under the range of conditions and fiber diameters, producing activation thresholds up to 3 times lower than TENS. eTENS also preserved its enhancement when surface electrodes were displaced away from the nerve. Anodic stimulation revealed an inhibitory region that removed eTENS benefits. eTENS also outperformed TENS by up to 4 times when targeting smaller diameter nerve fibers, scaling similar to a cuff electrode. In latency and activation of smaller diameter nerve fibers, eTENS results resembled those of NCES more than a TENS electrode. Activation threshold ratios were consistent in in-vivo validation.Our findings expand upon previously identified mechanisms for eTENS and further demonstrate how eTENS emulates a nerve cuff electrode to achieve lower activation thresholds. This work further characterizes considerations required for VNS under the three stimulation methods.

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“…Deep-learning based algorithms have recently received attention in anatomically guided, medical image segmentation [44]. With regard to segmentation of anatomical features of nerves, deep-learning algorithms have been used on EM images [45], with regard to single fibers, and on ultrasound [46] and histological images [47], with regard to fascicles. To the best of our knowledge, this is the first use of convolutional neural networks, in particular mask-RCNN, on micro-CT and IHC data, to automatically segment and extract anatomical features at the fascicle and single fiber level.…”

Section: Discussionmentioning

confidence: 99%

Organ- and function-specific anatomical organization of the vagus nerve supports fascicular vagus nerve stimulation

Jayaprakash

Tóth

Song

et al. 2022

Preprint

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Afferent and efferent fibers in the vagus travel inside nerve fascicles and form branches to innervate organs and regulate organ functions. The organization of fibers and fascicles in the vagus trunk, with respect to the functions they mediate and the organs they innervate, remains largely unknown. Accordingly, it is unknown whether that anatomical organization can be leveraged by bioelectronic devices for function- and organ-specific neuromodulation. To characterize the microscopic functional anatomy of the vagus we developed a pipeline consisting of micro-computed tomography-based morphometry of fascicles and quantitative immunohistochemistry of single fibers. We found that, in the swine vagus, fascicles form clusters specific to afferent and efferent functions, increasingly separated in the rostral direction, and other clusters specific to the innervated organs, including larynx, lungs and heart, increasingly separated in the caudal direction. Large myelinated and small unmyelinated efferents have small counts, cover large area of the nerve, and are limited to specific fascicles; small unmyelinated afferents have large counts, cover small area, and are uniformly distributed across fascicles. To test whether fiber populations can be selectively modulated, we developed a multi-contact cuff electrode that observes the fascicular vagus anatomy. Targeting of different nerve sub-sections evokes compound action potentials from different fiber types and elicits differential organ responses, including laryngeal muscle contraction, cough reflex, and changes in breathing and heart rate. Our results indicate that vagus fibers are spatially clustered according to functions they mediate and organs they innervate and can be differentially modulated by spatially selective nerve stimulation.

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Automatic three-dimensional reconstruction of fascicles in peripheral nerves from histological images

Cited by 9 publications

References 26 publications

Organ- and function-specific anatomical organization of vagal fibers supports fascicular vagus nerve stimulation

Organ- and function-specific anatomical organization of vagal fibers supports fascicular vagus nerve stimulation

Enhancing the selective electrical activation of human vagal nerve fibers: a comparative computational modeling study with validation in a rat sciatic model

Organ- and function-specific anatomical organization of the vagus nerve supports fascicular vagus nerve stimulation

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