Influence of fluid-flow direction on effective permeability of the vertebral end plate: an analytical model

被引：4

作者：

Swider, P. ^{[1
]}

Accadbled, F. ^{[2
]}

Laffosse, J. M. ^{[2
]}

de Gauzy, J. Sales ^{[1
]}

机构：

[1] Univ Toulouse, IMFT UMR CNRS 5502, Toulouse, France

[2] CHU Toulouse, Hop Enfants, Serv Orthopedie, Toulouse, France

来源：

COMPUTER METHODS IN BIOMECHANICS AND BIOMEDICAL ENGINEERING | 2012年 / 15卷 / 02期

关键词：

convective transport; permeability; hydraulic resistance; vertebral end plate; spine; INTERVERTEBRAL DISC; MACROSCOPIC PERMEABILITY; DIFFUSION; METABOLISM; TRANSPORT; NUTRITION; FIBROSUS; GLUCOSE; OXYGEN; VIVO;

D O I：

10.1080/10255842.2010.518960

中图分类号：

TP39 [计算机的应用];

学科分类号：

081203 ; 0835 ;

摘要：

Convective transports in the vertebral end plate (VEP) play a significant role in the homeostasis of the spine. A few studies hypothesised that the hydraulic resistance or effective permeability of the VEP could be dependant upon fluid-flow direction. Results were influenced by species, region of interest within the end plate and pathology. Some results were contradictory. We propose an analytical model based on steady-state Newtonian flows in capillary media to develop a phenomenological analysis of convective transport through the VEP. This dependence was established using a biquadratic analytical function involving porosities of subchondral bone, capillary bed and cartilage end plate. Discussion of results provided a theoretical justification for variable and/or contradictory experimental results concerning the amount of energy lost by fluid during its course through the end plate. Tissue porosities and, especially, those relative to the capillary bed could strongly influence the dependence of fluid energy loss on flow direction and could potentially modify tissue homeostasis related to the day and night cycle.

引用

页码：151 / 156

页数：6

共 50 条

[31] FLUID-FLOW MODEL FOR CERAMIC TAPE CASTING
CHOU, YT
KO, YT
YAN, MF
JOURNAL OF THE AMERICAN CERAMIC SOCIETY, 1987, 70 (10) : C280 - C282
[32] A MODEL FOR 2-PHASE FLUID-FLOW
BEREUX, F
COMPTES RENDUS DE L ACADEMIE DES SCIENCES SERIE I-MATHEMATIQUE, 1993, 317 (01): : 121 - 124
[33] FLUID-FLOW THROUGH A MODEL INTERCELLULAR CLEFT
ADAMSON, RH
YAHAGHI, AS
CURRY, FE
FASEB JOURNAL, 1993, 7 (04): : A876 - A876
[34] A LATTICE BOLTZMANN MODEL FOR THE SIMULATION OF FLUID-FLOW
KINGDON, RD
SCHOFIELD, P
WHITE, L
JOURNAL OF PHYSICS A-MATHEMATICAL AND GENERAL, 1992, 25 (12): : 3559 - 3566
[35] RELATION BETWEEN CONDUCTIVITY AND FLUID-FLOW PERMEABILITY IN POROUS ALUMINA CERAMICS
BROUERS, F
RAMSAMUGH, A
SOLID STATE COMMUNICATIONS, 1986, 60 (12) : 951 - 953
[36] STOCHASTIC PERMEABILITY MODELS OF FLUID-FLOW DURING CONTACT-METAMORPHISM
GERDES, ML
BAUMGARTNER, LP
PERSON, M
GEOLOGY, 1995, 23 (10) : 945 - 948
[37] INFLUENCE OF LANCE DESIGN ON FLUID-FLOW IN TORPEDO CARS
CARLSSON, G
XIU, WT
BRAMMING, M
IRONMAKING & STEELMAKING, 1984, 11 (02) : 95 - 100
[38] FLUID-FLOW IN CRACKS AS RELATED TO LOW-PERMEABILITY GAS SANDS
BROWER, KR
MORROW, NR
SOCIETY OF PETROLEUM ENGINEERS JOURNAL, 1985, 25 (02): : 191 - 201
[39] INFLUENCE OF FLUID-FLOW VELOCITY ON LOSS FACTOR OF PLATES
MUHLE, C
ACUSTICA, 1976, 36 (03): : 233 - 238
[40] INCOMPRESSIBLE MICROPOLAR FLUID-FLOW OVER A SEMI-INFINITE PLATE
DEY, J
NATH, G
INTERNATIONAL JOURNAL OF ENGINEERING SCIENCE, 1983, 21 (08) : 967 - 972

← 1 2 3 4 5 →