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1 of the peripapillary retina revealed a dense microvascular network.
2 of transport costs may be prioritized by the microvascular network.
3 ndothelial cell apoptosis within the mucosal microvascular network.
4 cosal injury requires reestablishment of the microvascular network.
5 cale blood flow in physiologically realistic microvascular networks.
6 on of neovascular tufts in postnatal retinal microvascular networks.
7 distributions at bifurcations in dichotomous microvascular networks.
8 ess using a ligation strategy for mesenteric microvascular networks.
9 to-cell electrotonic transmission within the microvascular networks.
10 and functional characteristics of the native microvascular network, allowing efficient recellularizat
11               Model simulations suggest that microvascular network anatomy can affect the optimal hem
12 ct the degree of organization of the hepatic microvascular network and are correlated to the severity
13 patterned ECMs used for engineering perfused microvascular networks and functional epidermis and for
14         This rapid formation of long-lasting microvascular networks by postnatal progenitor cells obt
15 ), the 3D construct containing the lymphatic microvascular network can be analyzed by microscopy (sta
16 muscle-mimicking microenvironments through a microvascular network concentrically wrapped with mural
17 in a polymer coating via a three-dimensional microvascular network embedded in the substrate.
18 dicine applications based on implantation of microvascular networks expanded ex vivo or the generatio
19 ells can serve to generate highly functional microvascular networks for tissue engineered bone grafts
20 EGF-A and alphaVbeta3 on fibroblast-mediated microvascular network formation.
21 he microdevice features self-organized human microvascular networks formed over 4-5 d, after which th
22 ity-mediated response may expand the mucosal microvascular network, foster immune cell recruitment, a
23 ells (RBCs) are performed in three realistic microvascular networks from the mouse cerebral cortex.
24 and is capable of incorporating realistic 3D microvascular network geometries.
25 reporter protein expression across a dynamic microvascular network in an adult mammal.
26      The bMFA consists of an endothelialized microvascular network in communication with a tissue com
27 of prenatal alcohol exposure on the cortical microvascular network in human controls and fetal alcoho
28 showed the absence of a radial peripapillary microvascular network in these 12 eyes.
29  2D cultures and the formation of a complete microvascular network in vitro in 3D cultures.
30 of prenatal alcohol exposure on the cortical microvascular network in vivo and ex vivo and the action
31 o augment the formation and stabilization of microvascular networks in a previously uncharacterized t
32 and pericytes, and can self-organize to form microvascular networks in an engineered matrix.
33                                Remodeling of microvascular networks in mammals is critical for physio
34                         The success of these microvascular networks in recapitulating these phenomena
35                    We have engineered living microvascular networks in three-dimensional tissue scaff
36                                            A microvascular network is critical for the survival and f
37  flow and pressure distribution in realistic microvascular networks is needed for improving our under
38 her vascular smooth muscle cells in cultured microvascular networks maintain the ability to constrict
39 lular organisation, extracellular matrix and microvascular network mimic human heart tissue.
40 l integration also requires consideration of microvascular network morphology in relation to local co
41                                        These microvascular networks (muVNs) allow for multiweek cultu
42 letion, substantial disruption of the luteal microvascular network occurred and was associated with a
43 liomas are indistinguishable on imaging, the microvascular network of pilomyxoid astrocytoma, a subty
44                                          The microvascular network of the left frontal cortex was eva
45 ns confirmed the presence of a peripapillary microvascular network only in MGS cases supports the hyp
46 r signals, and cellular behaviors to predict microvascular network patterning events.
47  simulations in realistic representations of microvascular networks should provide a theoretical fram
48                          Sample results in a microvascular network show an enhancement of diffusive s
49 ystems that mimic the vasculature (synthetic microvascular networks) showed that rod-shaped nanoparti
50 nsions (3D) between epithelial tissues and a microvascular network since vascularization is vital for
51 tissue and organ applications, incorporating microvascular networks, structures for transport and fil
52                                              Microvascular networks support metabolic activity and de
53                                          The microvascular network supported viability and function o
54   We study occlusive dynamics within a model microvascular network: the embryonic zebrafish trunk.
55 te the fabrication of three-dimensional (3D) microvascular networks through direct-write assembly of
56 ygen transport from a three-dimensional (3D) microvascular network to the surrounding tissue in the p
57 technique to study the responses of cerebral microvascular networks to single and repeated cocaine ad
58 sly undescribed strategy for creating stable microvascular networks to support engineered tissues of
59 cs involved in angiogenesis within an intact microvascular network using time-lapse imaging.
60                     In normal discs, a dense microvascular network was visible on OCT angiography.
61          At peak disease (postnatal day 18), microvascular networks were analyzed to examine intraret
62                      On Day 0 and Day 3 live microvascular networks were visualized with FITC conjuga
63                          We envisage that 3D microvascular networks will provide an enabling platform
64 T-synthase-deficient brains formed a chaotic microvascular network with distorted capillary lumens an
65 e is useful more generally for investigating microvascular networks within 3D engineered tissues with
66 d after implantation reveals highly branched microvascular networks within the implants that connect

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