Structural pattern and functional correlations of the long bone diaphyses intracortical vascular system: investigation carried out with China ink perfusion and multiplanar analysis in the rabbit femur.
Academic Article
Publication Date:
2011
Abstract:
The intracortical vessel system of the rabbit femur has been studied after perfusion of the vascular tree with a
water solution of dye (China ink) with multiplanar analysis. This method utilizes the full depth of field of the
microscope objectives focusing different planes of the thick cortex. The microscopic observation even if
restricted to a limited volume of cortex allowed to differentiate true 3-D nodes (54.5%) from the
superimposition of vessels lying on different planes. The network model with elongated meshes preferentially
oriented along the longitudinal axis of the diaphysis in his static configuration is not very different from the
vascular anatomy depicted in the 2-D traditional models; however, the semi-quantitative morphometric
analysis applied to the former supported the notion of a multidirectional microvascular network allowing
change of flow according to the functional requirements. Other peculiar aspects not previously reported were
cutting cone loops, blind-end and short-radius-bent vessels, and button-holes figures. The network design
and node distribution were consistent with the straight trajectory of the secondary remodeling, with the
proximal-to-distal and distal-to-proximal advancement directions of the cutting cones and with two main
modes of node formation, namely bifurcation of the cutting cone and interception with pre-existing canals.
The general organization of the network and its uninterrupted transformation during bone modeling and
remodeling suggested a substantial plasticity of the intracortical vascular system capable to adapt itself to the
changeable haemodynamic conditions.
water solution of dye (China ink) with multiplanar analysis. This method utilizes the full depth of field of the
microscope objectives focusing different planes of the thick cortex. The microscopic observation even if
restricted to a limited volume of cortex allowed to differentiate true 3-D nodes (54.5%) from the
superimposition of vessels lying on different planes. The network model with elongated meshes preferentially
oriented along the longitudinal axis of the diaphysis in his static configuration is not very different from the
vascular anatomy depicted in the 2-D traditional models; however, the semi-quantitative morphometric
analysis applied to the former supported the notion of a multidirectional microvascular network allowing
change of flow according to the functional requirements. Other peculiar aspects not previously reported were
cutting cone loops, blind-end and short-radius-bent vessels, and button-holes figures. The network design
and node distribution were consistent with the straight trajectory of the secondary remodeling, with the
proximal-to-distal and distal-to-proximal advancement directions of the cutting cones and with two main
modes of node formation, namely bifurcation of the cutting cone and interception with pre-existing canals.
The general organization of the network and its uninterrupted transformation during bone modeling and
remodeling suggested a substantial plasticity of the intracortical vascular system capable to adapt itself to the
changeable haemodynamic conditions.
CRIS type:
1.1 Articolo in rivista
Keywords:
intracortical vascular system
List of contributors:
Pazzaglia, Ugo; Congiu, T; Marchese, M; Zarattini, Guido
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