Literature DB >> 34390441

Transmantle and transvenous pressure gradients in cerebrospinal fluid disorders.

Mendel Castle-Kirszbaum1, Tony Goldschlager2,3.   

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.
© 2021. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.

Entities:  

Keywords:  CSF; Hydrocephalus; IIH; Transmantle; Transvenous

Mesh:

Year:  2021        PMID: 34390441     DOI: 10.1007/s10143-021-01622-1

Source DB:  PubMed          Journal:  Neurosurg Rev        ISSN: 0344-5607            Impact factor:   3.042


  49 in total

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Journal:  Neuroradiology       Date:  2003-01-16       Impact factor: 2.804

2.  Dutch normal-pressure hydrocephalus study: prediction of outcome after shunting by resistance to outflow of cerebrospinal fluid.

Authors:  A J Boon; J T Tans; E J Delwel; S M Egeler-Peerdeman; P W Hanlo; H A Wurzer; C J Avezaat; D A de Jong; R H Gooskens; J Hermans
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3.  Arterial inflow and venous outflow in idiopathic intracranial hypertension associated with venous outflow stenoses.

Authors:  Grant A Bateman
Journal:  J Clin Neurosci       Date:  2008-01-31       Impact factor: 1.961

4.  Differences in the Calculated Transvenous Pressure Drop between Chronic Hydrocephalus and Idiopathic Intracranial Hypertension.

Authors:  G A Bateman; A R Bateman
Journal:  AJNR Am J Neuroradiol       Date:  2018-11-22       Impact factor: 3.825

5.  Vascular compliance in normal pressure hydrocephalus.

Authors:  G A Bateman
Journal:  AJNR Am J Neuroradiol       Date:  2000-10       Impact factor: 3.825

6.  The pathophysiology of idiopathic normal pressure hydrocephalus: cerebral ischemia or altered venous hemodynamics?

Authors:  G A Bateman
Journal:  AJNR Am J Neuroradiol       Date:  2007-10-09       Impact factor: 3.825

7.  Dependency of cerebrospinal fluid outflow resistance on intracranial pressure.

Authors:  Nina Andersson; Jan Malm; Anders Eklund
Journal:  J Neurosurg       Date:  2008-11       Impact factor: 5.115

8.  Cerebrospinal fluid absorption block at the vertex in chronic hydrocephalus: obstructed arachnoid granulations or elevated venous pressure?

Authors:  Grant A Bateman; Sabbir H Siddique
Journal:  Fluids Barriers CNS       Date:  2014-05-23

9.  The incidence of significant venous sinus stenosis and cerebral hyperemia in childhood hydrocephalus: prognostic value with regards to differentiating active from compensated disease.

Authors:  Grant Alexander Bateman; Swee Leong Yap; Gopinath Musuwadi Subramanian; Alexander Robert Bateman
Journal:  Fluids Barriers CNS       Date:  2020-04-29

10.  A venous mechanism of ventriculomegaly shared between traumatic brain injury and normal ageing.

Authors:  Toshihiko Aso; Genichi Sugihara; Toshiya Murai; Shiho Ubukata; Shin-Ichi Urayama; Tsukasa Ueno; Gaku Fujimoto; Dinh Ha Duy Thuy; Hidenao Fukuyama; Keita Ueda
Journal:  Brain       Date:  2020-06-01       Impact factor: 13.501
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