Leaf-inspired microcontact printing vascular patterns.

The vascularization of tissue grafts is critical for maintaining viability of the cells within a transplanted graft. A number of strategies are currently being investigated including very promising microfluidics systems. Here, we explored the potential for generating a vasculature-patterned endothelial cells that could be integrated into distinct layers between sheets of primary cells. Bioinspired from the leaf veins, we generated a reverse mold with a fractal vascular-branching pattern that models the unique spatial arrangement over multiple length scales that precisely mimic branching vasculature. By coating the reverse mold with 50 μg ml-1 of fibronectin and stamping enabled selective adhesion of the human umbilical vein endothelial cells (HUVECs) to the patterned adhesive matrix, we show that a vascular-branching pattern can be transferred by microcontact printing. Moreover, this pattern can be maintained and transferred to a 3D hydrogel matrix and remains stable for up to 4 d. After 4 d, HUVECs can be observed migrating and sprouting into Matrigel. These printed vascular branching patterns, especially after transfer to 3D hydrogels, provide a viable alternative strategy to the prevascularization of complex tissues

MicroRNA regulation of endothelial homeostasis and commitment—implications for vascular regeneration strategies using stem cell therapies

Human embryonic (hESC) and induced pluripotent (hiPSC) stem cells have broad therapeutic potential in the treatment of a range of diseases, including those of the vascular system. Both hESCs and hiPSCs have the capacity for indefinite self-renewal, in addition to their ability to differentiate into any adult cell type. These cells could provide a potentially unlimited source of cells for transplantation and, therefore, provide novel treatments, e.g. in the production of endothelial cells for vascular regeneration. MicroRNAs are short, noncoding RNAs that act posttranscriptionally to control gene expression and thereby exert influence over a wide range of cellular processes, including maintenance of pluripotency and differentiation. Expression patterns of these small RNAs are tissue specific, and changes in microRNA levels have often been associated with disease states in humans, including vascular pathologies. Here, we review the roles of microRNAs in endothelial cell function and vascular disease, as well as their role in the differentiation of pluripotent stem cells to the vascular endothelial lineage. Furthermore, we discuss the therapeutic potential of stem cells and how knowledge and manipulation of microRNAs in stem cells may enhance their capacity for vascular regeneration

Correlation between magnifying narrow band imaging and histopathology in gastric protruding/or polypoid lesions: a pilot feasibility trial

<p>Abstract</p> <p>Background</p> <p>Several study showed usefulness of microscopic capillaries, seen by magnifying narrow band imaging (NBI) endoscopy for predicting histopathology among superficial depressed or flat elevated gastric neoplasia (GN). Here we assessed the diagnostic efficacy of magnifying NBI for predicting histopathology among gastric protruding/or polypoid lesions.</p> <p>Methods</p> <p>Using endoscopic pictures of magnifying NBI from 95 protruding/or polypoid lesions (19 fundic gland polyps: FGP, 47 hyperplastic polyps: HP, and 29 GN), fine mucosal patterns were classified into four categories: small round, prolonged, villous or ridge, and unclear patterns, and micro vascular patterns were classified into five categories: honey comb, dense vascular, fine net work, core vascular, and unclear patterns.</p> <p>Results</p> <p>Most suggestive micro vascular patterns for predicting FGP, and HP were honeycomb (sensitivity 94.7%, specificity 97.4%), and dense vascular patterns (sensitivity 93.6%, specificity 91.6%), respectively. Fine net work, core vascular, and unclear patterns presented higher specificity (97%, 100%, and 100%) for predicting GN, and diagnostic efficacy of combined of those patterns was favorable (sensitivity 86.2%, specificity 97.0%).</p> <p>Conclusion</p> <p>Micro vascular patterns by using magnifying NBI provides meaningful information for predicting the histopathology of gastric protruding/or polypoid lesions.</p

Coupling and robustness of intra-cortical vascular territories

Vascular domains have been described as being coupled to neuronal functional units enabling dynamic blood supply to the cerebral cyto-architecture. Recent experiments have shown that penetrating arterioles of the grey matter are the building blocks for such units. Nevertheless, vascular territories are still poorly known, as the collection and analysis of large three-dimensional micro-vascular networks are difficult. By using an exhaustive reconstruction of the micro-vascular network in an 18 mm 3 volume of marmoset cerebral cortex, we numerically computed the blood flow in each blood vessel. We thus defined arterial and venular territories and examined their overlap. A large part of the intracortical vascular network was found to be supplied by several arteries and drained by several venules. We quantified this multiple potential to compensate for deficiencies by introducing a new robustness parameter. Robustness proved to be positively correlated with cortical depth and a systematic investigation of coupling maps indicated local patterns of overlap between neighbouring arteries and neighbouring venules. However, arterio-venular coupling did not have a spatial pattern of overlap but showed locally preferential functional coupling, especially of one artery with two venules, supporting the notion of vascular units. We concluded that intra-cortical perfusion in the primate was characterised by both very narrow functional beds and a large capacity for compensatory redistribution, far beyond the nearest neighbour collaterals

Directional control of angiogenesis to produce a designed multiscale micro-vascular network with bioprinting

Department of Biomedical EngineeringThe biomimetic vascular network is a key element in regeneration of viable, functional and scalable artificial tissues. In this study, we developed a multiscale vascular network that can be patterned freely by using bioprinting technology. An endothelialized channel of several hundred micrometer scale was directly printed. The micro-vascular network consisting of tubular structures of several tens of micrometers was generated through the direction control of angiogenic sprouting using the chemotaxis effect. For this purpose, human umbilical vein endothelial cells (HUVEC) and angiogenic factor secreting cells, normal human dermal fibroblasts (NHDF), were co-patterned at 1 to 2 mm intervals using water soluble bio-ink and alginate based bio-ink, respectively. Then, a bridge pattern connecting the two patterned gels was made with fibrin gel. After printing, an endothelialized channel of about 800 ??m was formed by selective removal of water soluble bio-ink. The angiogenic sprouting was induced at about 200 ??m/day along the bridge pattern from the channel. It was also possible to fabricate a multiscale micro-vascular network with diagonal, wave and branch shapes using bridge patterns of various designs. In this study, we investigated the functionality of hepatocytes by co-culturing mouse primary hepatocytes after fabricating a vascular construct with hepatic lobule-shaped pattern to confirm the utility of the constructed process. As a result, we could confirm largely improved albumin and urea secretion. Based on these results, we confirmed that the tissue specific multiscale vascular network could be constructed. This technique should provide a useful tool for the development of functional and scalable vascularized tissues.clos

Modelling the development and arrangement of the primary vascular structure in plants

Background and Aims The process of vascular development in plants results in the formation of a specific array of bundles that run throughout the plant in a characteristic spatial arrangement. Although much is known about the genes involved in the specification of procambium, phloem and xylem, the dynamic processes and interactions that define the development of the radial arrangement of such tissues remain elusive. Methods This study presents a spatially explicit reaction-diffusion model defining a set of logical and functional rules to simulate the differentiation of procambium, phloem and xylem and their spatial patterns, starting from a homogeneous group of undifferentiated cells. Key Results Simulation results showed that the model is capable of reproducing most vascular patterns observed in plants, from primitive and simple structures made up of a single strand of vascular bundles (protostele), to more complex and evolved structures, with separated vascular bundles arranged in an ordered pattern within the plant section (e.g. eustele). Conclusions The results presented demonstrate, as a proof of concept, that a common genetic-molecular machinery can be the basis of different spatial patterns of plant vascular development. Moreover, the model has the potential to become a useful tool to test different hypotheses of genetic and molecular interactions involved in the specification of vascular tissue

An exploration of the potential utility of fetal cardiovascular MRI as an adjunct to fetal echocardiography

Objectives: Fetal cardiovascular magnetic resonance imaging (MRI) offers a potential alternative to echocardiography, although in practice, its use has been limited. We sought to explore the need for additional imaging in a tertiary fetal cardiology unit and the usefulness of standard MRI sequences. Methods: Cases where the diagnosis was not fully resolved using echocardiography were referred for MRI. Following a three‐plane localiser, fetal movement was assessed with a balanced steady‐state free precession (bSSFP) cine. Single‐shot fast spin echo and bSSFP sequences were used for diagnostic imaging. Results: Twenty‐two fetal cardiac MRIs were performed over 12 months, at mean gestation of 32 weeks (26–38 weeks). The majority of referrals were for suspected vascular abnormalities (17/22), particularly involving the aortic arch (n = 10) and pulmonary vessels (n = 4). Single‐shot fast spin echo sequences produced ‘black‐blood’ images, useful for examining the extracardiac vasculature in these cases. BSSFP sequences were more useful for intracardiac structures. Real‐time SSFP allowed for dynamic assessment of structures such as cardiac masses, with enhancement patterns also allowing for tissue characterisation in these cases. Conclusions: Fetal vascular abnormalities such as coarctation can be difficult to diagnose by using ultrasound. Fetal MRI may have an adjunctive role in the evaluation of the extracardiac vascular anatomy and tissue characterisation. © 2016 The Authors. Prenatal Diagnosis published by John Wiley & Sons, Ltd

Engineering Patterns to Study Vascular Biology

Proper growth of blood vessels is critical for development, wound healing and homeostasis. This process is regulated by a variety of microenvironmental cues including growth factor signaling, cell-cell contacts and mechanical and biochemical signals from the extracellular matrix. The work presented in this dissertation encompasses the application of engineering principles to the study of angiogenesis and vascular biology within the contexts of tissue engineering and vascular disease. In Chapter 2, we present a novel strategy for generating a spatially patterned vascular network in vivo. Future development of clinically viable engineered tissues hinges on the ability to generate functional vasculature capable of delivering blood to parenchymal cells deep within the tissue. The vascularization strategy described here utilizes tissue constructs that contain patterned ‘cords’ of endothelial cells. Implantation of these constructs into mice leads to the formation of stable capillaries in a spatially controlled geometry. The capillaries become perfused with host blood as early as 3 days post implantation, remain stable for at least 28 days in vivo, are largely comprised of implanted endothelial cells, and are invested by α-SMA positive pericytes. We further demonstrate that spatial patterning of vascular architecture improves the function of engineered hepatic tissues. Specifically, co-implantation of patterned endothelial cell cords with primary hepatocyte aggregates suggested that organized vascular architecture significantly improved albumin promoter activity within the tissues. In Chapter 3, we describe the development of an organotypic vascular wall model and show that pulmonary arterial smooth muscle cells (PASMCs) isolated from patients with idiopathic pulmonary arterial hypertension (IPAH) exhibit a hyperproliferative phenotype in culture. While normal control PASMCs display Rac1-mediated growth control, the higher proliferation in IPAH PASMCs is dependent on increased RhoA activity. We observed that focal adhesion assembly and focal adhesion kinase signaling are abnormally increased in IPAH PASMCs and show that antagonizing adhesion signaling by direct inhibition of FAK abrogates IPAH PASMC hyperproliferation in vitro. In summary, our strategy for rapidly inducing the formation of spatially controlled capillaries comprises a novel technique for spatial control of vessel growth in vivo. Functional studies with engineered hepatic tissues also demonstrate the potential of this technique to be used in vascularizing engineered solid organs. Findings from our investigation into aberrant IPAH SMC proliferation suggest that a mechanosensitive proliferative control mechanism underlies IPAH etiology

The concept of terminal vascular patterns

Thesis (M.A.)--Boston Universit