Brain Stimulation (Mar 2023)

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

  • Naveen Jayaprakash,
  • Weiguo Song,
  • Viktor Toth,
  • Avantika Vardhan,
  • Todd Levy,
  • Jacquelyn Tomaio,
  • Khaled Qanud,
  • Ibrahim Mughrabi,
  • Yao-Chuan Chang,
  • Moontahinaz Rob,
  • Anna Daytz,
  • Adam Abbas,
  • Zeinab Nassrallah,
  • Bruce T. Volpe,
  • Kevin J. Tracey,
  • Yousef Al-Abed,
  • Timir Datta-Chaudhuri,
  • Larry Miller,
  • Mary F. Barbe,
  • Sunhee C. Lee,
  • Theodoros P. Zanos,
  • Stavros Zanos

Journal volume & issue
Vol. 16, no. 2
pp. 484 – 506

Abstract

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Vagal fibers travel inside fascicles and form branches to innervate organs and regulate organ functions. Existing vagus nerve stimulation (VNS) therapies activate vagal fibers non-selectively, often resulting in reduced efficacy and side effects from non-targeted organs. The transverse and longitudinal arrangement of fibers inside the vagal trunk with respect to the functions they mediate and organs they innervate is unknown, however it is crucial for selective VNS. Using micro-computed tomography imaging, we tracked fascicular trajectories and found that, in swine, sensory and motor fascicles are spatially separated cephalad, close to the nodose ganglion, and merge caudad, towards the lower cervical and upper thoracic region; larynx-, heart- and lung-specific fascicles are separated caudad and progressively merge cephalad. Using quantified immunohistochemistry at single fiber level, we identified and characterized all vagal fibers and found that fibers of different morphological types are differentially distributed in fascicles: myelinated afferents and efferents occupy separate fascicles, myelinated and unmyelinated efferents also occupy separate fascicles, and small unmyelinated afferents are widely distributed within most fascicles. We developed a multi-contact cuff electrode to accommodate the fascicular structure of the vagal trunk and used it to deliver fascicle-selective cervical VNS in anesthetized and awake swine. Compound action potentials from distinct fiber types, and physiological responses from different organs, including laryngeal muscle, cough, breathing, and heart rate responses are elicited in a radially asymmetric manner, with consistent angular separations that agree with the documented fascicular organization. These results indicate that fibers in the trunk of the vagus nerve are anatomically organized according to functions they mediate and organs they innervate and can be asymmetrically activated by fascicular cervical VNS.