Bryn A Martin1, Francis Loth. 1. Ecole Polytechnique Fédérale de Lausanne, Integrative Bioscience Institute, Laboratory of Hemodynamics and Cardiovascular Technology, Lausanne, Switzerland.
Abstract
BACKGROUND: The influence of coughing, on the biomechanical environment in the spinal subarachnoid space (SAS) in the presence of a cerebrospinal fluid flow stenosis, is thought to be an important etiological factor in craniospinal disorders, including syringomyelia (SM), Chiari I malformation, and hydrocephalus. The aim of this study was to investigate SAS and syrinx pressures during simulated coughing using in vitro models and to provide information for the understanding of the craniospinal fluid system dynamics to help develop better computational models. METHODS: Four in vitro models were constructed to be simplified representations of: 1) non-communicating SM with spinal SAS stenosis; 2) non-communicating SM due to spinal SAS stenosis with a distensible spinal column; 3) non-communicating SM post surgical removal of a spinal SAS stenosis; and 4) a spinal SAS stenosis due to spinal trauma. All of the models had a flexible spinal cord. To simulate coughing conditions, an abrupt CSF pressure pulse (~ 5 ms) was imposed at the caudal end of the spinal SAS by a computer-controlled pump. Pressure measurements were obtained at 4 cm intervals along the spinal SAS and syrinx using catheter tip transducers. RESULTS: Pressure measurements during a simulated cough, showed that removal of the stenosis was a key factor in reducing pressure gradients in the spinal SAS. The presence of a stenosis resulted in a caudocranial pressure drop in the SAS, whereas pressure within the syrinx cavity varied little caudocranially. A stenosis in the SAS caused the syrinx to balloon outward at the rostral end and be compressed at the caudal end. A >90% SAS stenosis did not result in a significant Venturi effect. Increasing compliance of the spinal column reduced forces acting on the spinal cord. The presence of a syrinx in the cord when there was a stenosis in the SAS, reduced pressure forces in the SAS. Longitudinal pressure dissociation acted to suck fluid and tissue caudocranially in the SAS with a stenosis. CONCLUSIONS: Pressures in the spinal SAS during a simulated cough in vitro had similar peak, transmural, and longitudinal pressures to in vivo measurements reported in the literature. The pressure wave velocities and pressure gradients during coughing (longitudinal pressure dissociation and transmural pressure) were impacted by alterations in geometry, compliance, and the presence of a syrinx and/or stenosis.
BACKGROUND: The influence of coughing, on the biomechanical environment in the spinal subarachnoid space (SAS) in the presence of a cerebrospinal fluid flow stenosis, is thought to be an important etiological factor in craniospinal disorders, including syringomyelia (SM), Chiari I malformation, and hydrocephalus. The aim of this study was to investigate SAS and syrinx pressures during simulated coughing using in vitro models and to provide information for the understanding of the craniospinal fluid system dynamics to help develop better computational models. METHODS: Four in vitro models were constructed to be simplified representations of: 1) non-communicating SM with spinal SAS stenosis; 2) non-communicating SM due to spinal SAS stenosis with a distensible spinal column; 3) non-communicating SM post surgical removal of a spinal SAS stenosis; and 4) a spinal SAS stenosis due to spinal trauma. All of the models had a flexible spinal cord. To simulate coughing conditions, an abrupt CSF pressure pulse (~ 5 ms) was imposed at the caudal end of the spinal SAS by a computer-controlled pump. Pressure measurements were obtained at 4 cm intervals along the spinal SAS and syrinx using catheter tip transducers. RESULTS: Pressure measurements during a simulated cough, showed that removal of the stenosis was a key factor in reducing pressure gradients in the spinal SAS. The presence of a stenosis resulted in a caudocranial pressure drop in the SAS, whereas pressure within the syrinx cavity varied little caudocranially. A stenosis in the SAS caused the syrinx to balloon outward at the rostral end and be compressed at the caudal end. A >90% SAS stenosis did not result in a significant Venturi effect. Increasing compliance of the spinal column reduced forces acting on the spinal cord. The presence of a syrinx in the cord when there was a stenosis in the SAS, reduced pressure forces in the SAS. Longitudinal pressure dissociation acted to suck fluid and tissue caudocranially in the SAS with a stenosis. CONCLUSIONS: Pressures in the spinal SAS during a simulated cough in vitro had similar peak, transmural, and longitudinal pressures to in vivo measurements reported in the literature. The pressure wave velocities and pressure gradients during coughing (longitudinal pressure dissociation and transmural pressure) were impacted by alterations in geometry, compliance, and the presence of a syrinx and/or stenosis.
Authors: Matthew J McGirt; April Atiba; Frank J Attenello; Bruce A Wasserman; Ghazala Datoo; Muraya Gathinji; Benjamin Carson; John D Weingart; George I Jallo Journal: Childs Nerv Syst Date: 2008-01-19 Impact factor: 1.475
Authors: Tatyana Kondrashova; Joshua Blanchard; Lucas Knoche; James Potter; Bruce A Young Journal: J Comp Physiol A Neuroethol Sens Neural Behav Physiol Date: 2019-12-06 Impact factor: 1.836
Authors: Bryn A Martin; Theresia I Yiallourou; Soroush Heidari Pahlavian; Suraj Thyagaraj; Alexander C Bunck; Francis Loth; Daniel B Sheffer; Jan Robert Kröger; Nikolaos Stergiopulos Journal: Ann Biomed Eng Date: 2015-10-07 Impact factor: 3.934
Authors: Suraj Thyagaraj; Soroush Heidari Pahlavian; Lucas R Sass; Francis Loth; Morteza Vatani; Jae-Won Choi; R Shane Tubbs; Daniel Giese; Jan-Robert Kroger; Alexander C Bunck; Bryn A Martin Journal: IEEE Trans Biomed Eng Date: 2017-09-26 Impact factor: 4.538
Authors: Soroush Heidari Pahlavian; Theresia Yiallourou; R Shane Tubbs; Alexander C Bunck; Francis Loth; Mark Goodin; Mehrdad Raisee; Bryn A Martin Journal: PLoS One Date: 2014-04-07 Impact factor: 3.240
Authors: Gabryel Conley Natividad; Sophia K Theodossiou; Nathan R Schiele; Gordon K Murdoch; Alkiviadis Tsamis; Bertrand Tanner; Gabriel Potirniche; Martin Mortazavi; David A Vorp; Bryn A Martin Journal: Fluids Barriers CNS Date: 2020-11-12
Authors: Selda Yildiz; John Grinstead; Andrea Hildebrand; John Oshinski; William D Rooney; Miranda M Lim; Barry Oken Journal: Sci Rep Date: 2022-06-28 Impact factor: 4.996
Authors: Theresia I Yiallourou; Jan Robert Kröger; Nikolaos Stergiopulos; David Maintz; Bryn A Martin; Alexander C Bunck Journal: PLoS One Date: 2012-12-21 Impact factor: 3.240