Literature DB >> 4774376

Pressure-flow characteristics of collapsible tubes: a reconciliation of seemingly contradictory results.

R W Brower, A Noordergraaf.   

Abstract

Mesh:

Year:  1973        PMID: 4774376     DOI: 10.1007/bf02407674

Source DB:  PubMed          Journal:  Ann Biomed Eng        ISSN: 0090-6964            Impact factor:   3.934


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  6 in total

1.  Alveolar pressure, pulmonary venous pressure, and the vascular waterfall.

Authors:  S PERMUTT; B BROMBERGER-BARNEA; H N BANE
Journal:  Med Thorac       Date:  1962

2.  Autoregulation in encapsulated, passive, softwalled vessels.

Authors:  S RODBARD
Journal:  Am Heart J       Date:  1963-05       Impact factor: 4.749

3.  An integrated approach to the study of the venous system with steps toward a detailed model of the dynamics of venous return to the right heart.

Authors:  A H Moreno; A I Katz; L D Gold
Journal:  IEEE Trans Biomed Eng       Date:  1969-10       Impact factor: 4.538

4.  Flow through collapsible tubes and through in situ veins.

Authors:  J P Holt
Journal:  IEEE Trans Biomed Eng       Date:  1969-10       Impact factor: 4.538

5.  Critical closure of pulmonary vessels analyzed in terms of Starling resistor model.

Authors:  R Lopez-Muniz; N L Stephens; B Bromberger-Barnea; S Permutt; R L Riley
Journal:  J Appl Physiol       Date:  1968-05       Impact factor: 3.531

6.  Flow through a collapsible tube. Experimental analysis and mathematical model.

Authors:  A I Katz; Y Chen; A H Moreno
Journal:  Biophys J       Date:  1969-10       Impact factor: 4.033
  6 in total
  11 in total

1.  Modeling the circulation with three-terminal electrical networks containing special nonlinear capacitors.

Authors:  J E Tsitlik; H R Halperin; A S Popel; A A Shoukas; F C Yin; N Westerhof
Journal:  Ann Biomed Eng       Date:  1992       Impact factor: 3.934

2.  A simple model for the two dimensional blood flow in the collapse of veins.

Authors:  K W Chow; C C Mak
Journal:  J Math Biol       Date:  2006-04-24       Impact factor: 2.259

3.  Experimental evidence on the mechanism for the instability of flow in collapsible vessels.

Authors:  R W Brower; C Scholten
Journal:  Med Biol Eng       Date:  1975-11

4.  Optimal postnodal lymphatic network structure that maximizes active propulsion of lymph.

Authors:  Arun M Venugopal; Christopher M Quick; Glen A Laine; Randolph H Stewart
Journal:  Am J Physiol Heart Circ Physiol       Date:  2008-11-21       Impact factor: 4.733

5.  Pulse wave reflection at the collapsed segment of an artery in Riva-Rocci's method.

Authors:  T Kenner
Journal:  Pflugers Arch       Date:  1976-08-24       Impact factor: 3.657

6.  The Korotkoff sound.

Authors:  G M Drzewiecki; J Melbin; A Noordergraaf
Journal:  Ann Biomed Eng       Date:  1989       Impact factor: 3.934

7.  Flow resistance characteristics of microdialysis probes in vitro.

Authors:  R A Kuipers; J Korf
Journal:  Med Biol Eng Comput       Date:  1994-01       Impact factor: 2.602

8.  Compression of the outlets of the leptomeningeal veins--the cause of intracranial plateau waves.

Authors:  R Laas; H Arnold
Journal:  Acta Neurochir (Wien)       Date:  1981       Impact factor: 2.216

9.  Steady pressure flow relations in compressed arteries: possible origin of Korotkoff sounds.

Authors:  W A Conrad; D M McQueen; E L Yellin
Journal:  Med Biol Eng Comput       Date:  1980-07       Impact factor: 2.602

10.  Cerebral infarction due to carotid occlusion and carbon monoxide exposure III. Influence of neck vein occlusion.

Authors:  R Laas; J Igloffstein
Journal:  J Neurol Neurosurg Psychiatry       Date:  1983-08       Impact factor: 10.154
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