Transmantle and transvenous pressure gradients in cerebrospinal fluid disorders

Mendel Castle-Kirszbaum; Tony Goldschlager

doi:10.1007/s10143-021-01622-1

Transmantle and transvenous pressure gradients in cerebrospinal fluid disorders

Mendel Castle-Kirszbaum
, Tony Goldschlager

Surgery Monash Health

Research output: Contribution to journal › Review Article › Other › peer-review

8 Citations (Scopus)

Abstract

Hydrocephalus is the symptomatic endpoint of a variety of disease processes. Simple hydrodynamic models have failed to explain the entire spectrum of cerebrospinal fluid (CSF) disorders. Physical principles argue that for ventricles to expand, they must be driven by a force, Fishman’s transmantle pressure gradient (TMPG). However, the literature to date, reviewed herein, is heterogenous and fails to consistently measure a TMPG. The venous system, like CSF, traverses the cerebral mantle, and thus analogous transparenchymal and transvenous pressure gradients have been described, reliant on the differential haemodynamics of the deep and superficial venous systems. Interpreting CSF disorders through these models provides new insights into the possible pathophysiological mechanisms underlying these diseases. However, until more sophisticated testing is performed, these models should remain heuristics.

Original language	English
Pages (from-to)	305-315
Number of pages	11
Journal	Neurosurgical Review
Volume	45
Issue number	1
DOIs	https://doi.org/10.1007/s10143-021-01622-1
Publication status	Published - Feb 2022

Keywords

CSF
Hydrocephalus
IIH
Transmantle
Transvenous

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10.1007/s10143-021-01622-1

Cite this

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abstract = "Hydrocephalus is the symptomatic endpoint of a variety of disease processes. Simple hydrodynamic models have failed to explain the entire spectrum of cerebrospinal fluid (CSF) disorders. Physical principles argue that for ventricles to expand, they must be driven by a force, Fishman{\textquoteright}s transmantle pressure gradient (TMPG). However, the literature to date, reviewed herein, is heterogenous and fails to consistently measure a TMPG. The venous system, like CSF, traverses the cerebral mantle, and thus analogous transparenchymal and transvenous pressure gradients have been described, reliant on the differential haemodynamics of the deep and superficial venous systems. Interpreting CSF disorders through these models provides new insights into the possible pathophysiological mechanisms underlying these diseases. However, until more sophisticated testing is performed, these models should remain heuristics.",

keywords = "CSF, Hydrocephalus, IIH, Transmantle, Transvenous",

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AU - Castle-Kirszbaum, Mendel

AU - Goldschlager, Tony

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N2 - Hydrocephalus is the symptomatic endpoint of a variety of disease processes. Simple hydrodynamic models have failed to explain the entire spectrum of cerebrospinal fluid (CSF) disorders. Physical principles argue that for ventricles to expand, they must be driven by a force, Fishman’s transmantle pressure gradient (TMPG). However, the literature to date, reviewed herein, is heterogenous and fails to consistently measure a TMPG. The venous system, like CSF, traverses the cerebral mantle, and thus analogous transparenchymal and transvenous pressure gradients have been described, reliant on the differential haemodynamics of the deep and superficial venous systems. Interpreting CSF disorders through these models provides new insights into the possible pathophysiological mechanisms underlying these diseases. However, until more sophisticated testing is performed, these models should remain heuristics.

AB - Hydrocephalus is the symptomatic endpoint of a variety of disease processes. Simple hydrodynamic models have failed to explain the entire spectrum of cerebrospinal fluid (CSF) disorders. Physical principles argue that for ventricles to expand, they must be driven by a force, Fishman’s transmantle pressure gradient (TMPG). However, the literature to date, reviewed herein, is heterogenous and fails to consistently measure a TMPG. The venous system, like CSF, traverses the cerebral mantle, and thus analogous transparenchymal and transvenous pressure gradients have been described, reliant on the differential haemodynamics of the deep and superficial venous systems. Interpreting CSF disorders through these models provides new insights into the possible pathophysiological mechanisms underlying these diseases. However, until more sophisticated testing is performed, these models should remain heuristics.

KW - CSF

KW - Hydrocephalus

KW - IIH

KW - Transmantle

KW - Transvenous

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DO - 10.1007/s10143-021-01622-1

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VL - 45

SP - 305

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JO - Neurosurgical Review

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ER -

Transmantle and transvenous pressure gradients in cerebrospinal fluid disorders

Abstract

Keywords

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