The fractal properties of the retinal vascular architecture

Purpose: The human retinal vasculature has been demonstrated to exhibit fractal, or statistically self similar properties. Fractal analysis offers a simple quantitative method to characterise the complexity of the branching vessel network in the retina. Several methods have been proposed to quantify the fractal properties of the retina. Methods: Twenty five healthy volunteers underwent retinal photography, retinal oximetry and ocular biometry. A robust method to evaluate the fractal properties of the retinal vessels is proposed; it consists of manual vessel segmentation and box counting of 50 degree retinal photographs centred on the fovea. Results: Data is presented on the associations between the fractal properties of the retinal vessels and various functional properties of the retina. Conclusion Fractal properties of the retina could offer a promising tool to assess the risk and prognostic factors that define retinal disease. Outstanding efforts surround the need to adopt a standardised protocol for assessing the fractal properties of the retina, and further demonstrate its association with disease processes.

Architecture of the caudal vena cava wall of the dog at the level of the liver caudate lobe

The vascular segment of the caudal vena cava of the dog at the level of the caudate lobe was shown to be intimately related to hepatic tissue through the hepatic capsule and parenchyma. The tunica adventitia of the caudal vena cava was formed mainly by smooth muscle cells with collagen and elastic fibers arranged in bundles. The thin tunica media of the vein was also formed by smooth muscle cells, collagen and elastic fibers arranged in bundles. The tunica intima presented an elastic sub-endothelial network. The hepatic segment of the caudal vena cava showed a myoconnective architecture and propulsive characteristics in terms of its hemodynamic pattern.

A novel characterisation model for microvasulature changes following closed soft tissue trauma using micro-CT imaging

INTRODUCTION There is evidence that the reduction of blood perfusion caused by closed soft tissue trauma (CSTT) delays the healing of the affected soft tissues and bone [1]. We hypothesise that the characterisation of vascular morphology changes (VMC) following injury allows us to determine the effect of the injury on tissue perfusion and thereby the severity of the injury. This research therefore aims to assess the VMC following CSTT in a rat model using contrast-enhanced micro-CT imaging. METHODOLOGY A reproducible CSTT was created on the left leg of anaesthetized rats (male, 12 weeks) with an impact device. After euthanizing the animals at 6 and 24 hours following trauma, the vasculature was perfused with a contrast agent (Microfil, Flowtech, USA). Both hind-limbs were dissected and imaged using micro-CT for qualitative comparison of the vascular morphology and quantification of the total vascular volume (VV). In addition, biopsy samples were taken from the CSTT region and scanned to compare morphological parameters of the vasculature between the injured and control limbs. RESULTS AND DISCUSSION While the visual observation of the hindlimb scans showed consistent perfusion of the microvasculature with microfil, enabling the identification of all major blood vessels, no clear differences in the vascular architecture were observed between injured and control limbs. However, overall VV within the region of interest (ROI)was  measured to be higher for the injured limbs after 24h. Also, scans of biopsy samples demonstrated that vessel diameter and density were higher in the injured legs 24h after impact. CONCLUSION We believe these results will contribute to the development of objective diagnostic methods for CSTT based on changes to the microvascular morphology as well as aiding in the validation of future non-invasive clinical assessment modalities.

Estudo da vascularização dos nervos periféricos e da sua influência na regeneração nervosa : estudo experimental e no cadáver humano

RESUMO: Na clínica, a recuperação funcional que se segue a uma lesão nervosa raramente é atingida na sua totalidade. A reinervação, quer motora, quer sensitiva, ocorre geralmente com maior ou menor deficit. Interessa, então, identificar os factores que podem interferir na regeneração nervosa. O neurónio é a unidade anatómica fundamental do sistema nervoso periférico e é muito vulnerável à isquemia pela grande distância que existe entre o corpo neuronal e a extensão do axónio, que pode ser de apenas alguns milímetros ou até atingir um metro. É, por isso, fundamental o estudo da vascularização do nervo periférico e da sua influência na regeneração nervosa. O resultado deste estudo pode levar ao desenvolvimento de técnicas cirúrgicas que criem as condições que garantam, por sua vez, a revascularização precoce do nervo periférico em caso de lesão, ou mesmo em caso de doenças, nas quais a vascularização do nervo está alterada como, por exemplo, na neuropatia diabética. O estudo da vascularização do nervo periférico realizou-se através da investigação da vascularização do nervo mediano do cadáver humano, pela investigação da vascularização do nervo isquiático do rato Wistar e do Plexo Braquial (PB) do mesmo. A vascularização do PB do rato não é muito diferente daquela que é reportada na espécie humana, existindo uma homologia entre o rato e o Homem no que diz respeito à morfologia e à vascularização do PB. Através da comparação angiomorfológica entre o nervo isquiático do rato e o nervo mediano humano, concluíu-se que a microvascularização do nervo isquiático do rato e do mediano humano são muito semelhantes, o que suporta a utilização do rato como modelo experimental de lesões do nervo mediano humano. Para a avaliação da influência da vascularização na regeneração nervosa foi feita a análise da eficácia de enxerto de tubo de membrana amniótica humana imunologicamente inerte, de enxerto de veia jugular externa autóloga e de auto-enxerto de nervo, na reparação de um defeito de 10 milímetros no nervo isquiático do rato, na presença de um fornecimento vascular axial, comparando-se com os mesmos procedimentos em estudos realizados anteriormente, sem suprimento vascular. Os ratos foram avaliados funcionalmente através do estudo das pegadas, da electroneurografia e da força de flexão ao nível do tornozelo, e estruturalmente, através das avaliações histológicas e morfométricas, da taxa de recuperação do peso dos músculos gastrocnémio e solhear e da marcação axonal retrógrada com True Blue às 4, 8 e 12 semanas. Os nervos reconstruídos apresentaram uma arquitectura normal, incluindo a arquitectura vascular. A membrana amniótica foi bem tolerada, persistindo imunologicamente em torno do nervo até à 12.ª semana. Concluiu-se também que, na presença de um suprimento vascular axial local, a membrana amniótica humana e as veias autólogas são, pelo menos, tão eficazes como os auto-enxertos nervosos na reconstrução de defeitos nervosos de 10 milímetros.--------------------------------------ABSTRACT: At the clinic, the functional recovery that follows a nerve lesion is rarely achieved in full. The neuron is very vulnerable to ischemia that’s why it is essential to study the vascularization of the peripheral nerve and its influence on the nerve’s regeneration. The outcome of this study may lead to the development of surgical techniques that create the conditions which are necessary to ensure an early revascularization in case of a peripheral nerve injury. This study investigated the vascularization of the median nerve of the human cadaver and the vascularization of the sciatic nerve of the Wistar rat and his Brachial Plexus (BP) through animal experimentation. The mouse's BP vascularization is not so different from the one that is reported in the human species. An angiomorphological comparison between the mouse sciatic nerve and the human median nerve concluded that the microvascularizations are very similar, which supports the use of the mouse as an experimental model for the study of median nerve’s lesions. To evaluate the influence of vascularization in the nerve’s regeneration, it was made an assessment of the effectiveness of the human amniotic immuno-inert membrane grafts, of the autologous external jugular vein grafts and of the nerve auto-graft in the repair of a defect of 10 mm on the sciatic nerve of the rat, in the presence of an axial vascular supply, comparing these with the same procedures that were adopted in the previous studies, without vascular supply. The rats were functionally assessed and structurally evaluated (through histological and morphometric evaluations) at the 4.th, 8.th and 12.th weeks. The nerves reconstructed presented a normal architecture, including vascular architecture. The amniotic membrane was well-tolerated immunologically, persisting around the nerve until the 12.th week. As a result, it was also concluded that in the presence of a local axial vascular supply, the human amniotic membrane and the autologous veins are, at least, as effective as the nerve auto-grafts in the reconstruction of the nerve’s defects of 10 mm.

Somatic cell nuclear transfer is associated with altered expression of angiogenic factor systems in bovine placentomes at term

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Untersuchungen zur Pathogenese der "Bypass graft disease"

Untersuchung zur Pathogenese der 'Bypass graft disease' Histomorphologische Untersuchungen und in vitro Zellkulturanalysen bilden die Grundlage für Fortschritte im Verständnis der pathologischen Mechanismen der aortokoronaren 'Bypass graft disease'. In der vorliegenden Arbeit wurde die pathomorphologische Veränderung der Gefäßanatomie im Verlauf der 'Bypass graft disease' an Hand histologischer Präparate explantierter humaner venöser Bypass-Läsionen analysiert. Erstmalig wurde ein histomorphologisches Klassifizierungsschema (Typ I - Typ III) beschrieben. Morphometrische Analysen zeigten, dass die Fläche der Neointima und Media im Verlauf der pathologischen Umgestaltung der Bypass-Architektur (Typ I zu Typ III) deutlich zunimmt. Bestimmungen der Zelldichte dokumentierten eine deutlich größere Zellzahl in allen Gefäßwandschichten der Bypass-Läsionen bei der Gegenüberstellung mit einer Kontrollgruppe nativer Venen, wobei im Verlauf der 'Bypass graft disease' (Typ I zu Typ III) eine Abnahme der Zelldichte zu beobachten war. Erstmalig durchgeführte Untersuchungen zur Proliferationsaktivität in aortokoronaren Bypass-Läsionen im Vergleich zu nativen Gefäßen präsentierten eine deutlich höhere zelluläre Proliferation in den Bypass-Präparaten. Diese war am stärksten in Typ III Läsionen ausgeprägt. Expressionsstudien im in vitro Zellkulturmodellsystem identifiziereten die homodimeren Isotypen (AA / BB) des Wachstumsfaktors PDGF als Stimulatoren der Transkriptionsfaktoren c-fos und c-myc in primärkultivierten humanen Muskelzellen der Aorta.

The mammary gland vasculature revisited

Concomitant with the extensive growth and differentiation of the mammary epithelium during pregnancy and lactation, and epithelial involution after weaning, the vasculature of the mammary gland undergoes repeated cycles of expansion and regression. Vascular expansion is effected by sprouting angiogenesis, intussusception and conceivably also vasculogenesis. The capacity of the epithelial cells to stimulate vascular growth and differentiation is dependent on the constellation of systemic and local hormones and growth factors as well as the changing demands for oxygenation and nutrient supply. This results in the release of angiogenic factors which stimulate endothelial cell growth and regulate vascular architecture. In contrast to the angiogenic phase of the mammary gland cycle, little is known about the control of vascular regression although this would possibly offer new insights into therapeutic possibilities against breast cancer. In this review we summarize knowledge regarding the mechanisms regulating the vasculature of the mammary gland and delineate the importance of the vasculature in the attainment of organ function. In addition, we discuss the angiogenic mechanisms observed during mammary carcinogenesis and their consequences for breast cancer therapy.

Hybrid Scaffolds Built From PET and Collagen as a Model For Vascular Graft Architecture

A hybrid material with excellent mechanical and biological properties is produced by electrospinning a co-solution of PET and collagen. The fibers are mapped using SEM, confocal Raman microscopy and collagenase digestion assays. Fibers of different compositions and morphologies are intermingled within the same membrane, resulting in a heterogeneous scaffold. The collagen distribution and exposure are found to depend on the PET/collagen ratio. The materials are chemically and mechanically characterized and biologically tested with fibroblasts (3T3-L1) and a HUVEC culture in vitro. All of the hybrid scaffolds show better cell attachment and proliferation than PET. These materials are potential candidates to be used as vascular grafts.

The Effect of Architecture and Shear Stress on Endothelialization of 3D Printed Vascular Networks

Despite significant progress in the field of tissue engineering within the last decade, a number of unsolved problems still remain. One of the most relevant issues is the lack of proper vascularization that limits the size of engineered tissues to smaller than clinically relevant dimensions. In particular, the growth of engineered tissue in vitro within bioreactors is plagued with this challenge. Specifically, the tubular perfusion system bioreactor has been used for large scale bone constructs; however these engineered constructs lack inherent vasculature and quickly develop a hypoxic core, where no nutrient exchange can occur, thus leading to cell death. Through the use of 3D printed vascular templates in conjunction with a tubular perfusion system bioreactor, we attempt to create an endothelial cell monolayer on 3D scaffolds that could potentially serve as the foundation of inherent vasculature within these engineered bone grafts.

Perturbed Lignification Impacts Tree Growth in Hybrid Poplar-A Function of Sink Strength, Vascular Integrity, and Photosynthetic Assimilation

The effects of reductions in cell wall lignin content, manifested by RNA interference suppression of coumaroyl 3'-hydroxylase, on plant growth, water transport, gas exchange, and photosynthesis were evaluated in hybrid poplar trees (Populus alba 3 grandidentata). The growth characteristics of the reduced lignin trees were significantly impaired, resulting in smaller stems and reduced root biomass when compared to wild-type trees, as well as altered leaf morphology and architecture. The severe inhibition of cell wall lignification produced trees with a collapsed xylem phenotype, resulting in compromised vascular integrity, and displayed reduced hydraulic conductivity and a greater susceptibility to wall failure and cavitation. In the reduced lignin trees, photosynthetic carbon assimilation and stomatal conductance were also greatly reduced, however, shoot xylem pressure potential and carbon isotope discrimination were higher and water-use efficiency was lower, inconsistent with water stress. Reductions in assimilation rate could not be ascribed to increased stomatal limitation. Starch and soluble sugars analysis of leaves revealed that photosynthate was accumulating to high levels, suggesting that the trees with substantially reduced cell wall lignin were not carbon limited and that reductions in sink strength were, instead, limiting photosynthesis.

Micro-CT based characterisation of changes to the vascular network following closed soft tissue trauma and cryotherapy

This project has investigated how the architecture of the blood vessels supplying nutrients to skeletal muscles is affected by muscle contusion injuries, and how it changes during healing with or without initial treatment of the injury by icing. In order to do this, we used contrast agents to visualise blood vessels in 3D with micro-computed tomography imaging. This research significantly contributes to the fields of orthopaedics, traumatology and sports medicine, as it improves our understanding of muscle contusion injuries. Furthermore, the methods developed in this thesis may help to improve the diagnosis and monitoring of these injuries.

Root system traits of Norway spruce, Scots pine, and silver birch in mixed boreal forests: an analysis of root architecture, morphology, and anatomy

The aim of this thesis was to unravel the functional-structural characteristics of root systems of Betula pendula Roth., Picea abies (L.) Karst., and Pinus sylvestris L. in mixed boreal forest stands differing in their developmental stage and site fertility. The root systems of these species had similar structural regularities: horizontally-oriented shallow roots defined the horizontal area of influence, and within this area, each species placed fine roots in the uppermost soil layers, while sinker roots defined the maximum rooting depth. Large radial spread and high ramification of coarse roots, and the high specific root length (SRL) and root length density (RLD) of fine roots indicated the high belowground competitiveness and root plasticity of B. pendula. Smaller radial root spread and sparser branching of coarse roots, and low SRL and RLD of fine roots of the conifers could indicate their more conservative resource use and high association with and dependence on ectomycorrhiza-forming fungi. The vertical fine root distributions of the species were mostly overlapping, implying the possibility for intense belowground competition for nutrients. In each species, conduits tapered and their frequency increased from distal roots to the stem, from the stem to the branches, and to leaf petioles in B. pendula. Conduit tapering was organ-specific in each species violating the assumptions of the general vascular scaling model (WBE). This reflects the hierarchical organization of a tree and differences between organs in the relative importance of transport, safety, and mechanical demands. The applied root model was capable of depicting the mass, length and spread of coarse roots of B. pendula and P. abies, and to the lesser extent in P. sylvestris. The roots did not follow self-similar fractal branching, because the parameter values varied within the root systems. Model parameters indicate differences in rooting behavior, and therefore different ecophysiological adaptations between species.

Vascular structures for volumetric cooling and mechanical strength

When solid material is removed in order to create flow channels in a load carrying structure, the strength of the structure decreases. On the other hand, a structure with channels is lighter and easier to transport as part of a vehicle. Here, we show that this trade off can be used for benefit, to design a vascular mechanical structure. When the total amount of solid is fixed and the sizes, shapes, and positions of the channels can vary, it is possible to morph the flow architecture such that it endows the mechanical structure with maximum strength. The result is a multifunctional structure that offers not only mechanical strength but also new capabilities necessary for volumetric functionalities such as self-healing and self-cooling. We illustrate the generation of such designs for strength and fluid flow for several classes of vasculatures: parallel channels, trees with one, two, and three bifurcation levels. The flow regime in every channel is laminar and fully developed. In each case, we found that it is possible to select not only the channel dimensions but also their positions such that the entire structure offers more strength and less flow resistance when the total volume (or weight) and the total channel volume are fixed. We show that the minimized peak stress is smaller when the channel volume (φ) is smaller and the vasculature is more complex, i.e., with more levels of bifurcation. Diminishing returns are reached in both directions, decreasing φ and increasing complexity. For example, when φ=0.02 the minimized peak stress of a design with one bifurcation level is only 0.2% greater than the peak stress in the optimized vascular design with two levels of bifurcation. © 2010 American Institute of Physics.

Effect of vascular endothelial growth factor upregulation on retinal gene expression in the Kimba mouse

Background:  The Kimba mouse carries a human vascular endothelial growth factor transgene causing retinal neovascularisation similar to that seen in diabetic retinopathy. Here, we examine the relationship between differential gene expression induced by vascular endothelial growth factor overexpression and the architectural changes that occur in the retinae of these mice.

Methods:  Retinal gene expression changes in juvenile and adult Kimba mice were assayed by microarray and compared with age-matched wild-type littermates. Transcription of selected genes was validated by quantitative real-time polymerase chain reaction. Protein translation was determined using immunohistochemistry and enzyme-linked immunosorbent assay.

Results:  Semaphorin 3C was upregulated, and nuclear receptor subfamily 2, group 3, member 3 (Nr2e3) was downregulated in juvenile Kimba mice. Betacellulin and endothelin 2 were upregulated in adults. Semaphorin 3C colocalized with glial fibrillary acidic protein in Müller cells of Kimba retinae at greater signal intensities than in wild type. Endothelin 2 colocalised to Müller cell end feet and extended into the outer limiting membrane. Endothelin receptor type B staining was most pronounced in the inner nuclear layer, the region containing Müller cell somata.

Conclusions:  An early spike in vascular endothelial growth factor induced significant long-term retinal neovascularisation associated with changes to the retinal ganglion, photoreceptor and Müller cells. Overexpression of vascular endothelial growth factor led to dysregulation of photoreceptor metabolism through differential expression of Nr2e3, endothelin 2, betacellulin and semaphorin 3C. Alterations in the expression of these genes may therefore play key roles in the pathological mechanisms that result from retinal neovascularisation.

Paralelização em GPU da segmentação vascular com extração de Centerlines por Height Ridges

The vascular segmentation is important in diagnosing vascular diseases like stroke and is hampered by noise in the image and very thin vessels that can pass unnoticed. One way to accomplish the segmentation is extracting the centerline of the vessel with height ridges, which uses the intensity as features for segmentation. This process can take from seconds to minutes, depending on the current technology employed. In order to accelerate the segmentation method proposed by Aylward [Aylward & Bullitt 2002] we have adapted it to run in parallel using CUDA architecture. The performance of the segmentation method running on GPU is compared to both the same method running on CPU and the original Aylward s method running also in CPU. The improvemente of the new method over the original one is twofold: the starting point for the segmentation process is not a single point in the blood vessel but a volume, thereby making it easier for the user to segment a region of interest, and; the overall gain method was 873 times faster running on GPU and 150 times more fast running on the CPU than the original CPU in Aylward