ライフサイエンスコーパス: substrata

1 hen the cells are cultured on gelatinous ECM substrata.

2 nant and nonmalignant cells grown on plastic substrata.

3 s by passage in monolayer culture on plastic substrata.

4 heightened adhesiveness to type IV collagen substrata.

5 rsed as soon as the cells were detached from substrata.

6 able displacements of sufficiently compliant substrata.

7 elanoma cells before and after attachment to substrata.

8 nd prevented spreading of cells on noncoated substrata.

9 e they frequently dominate sunlit intertidal substrata.

10 e, and their interaction with siliceous rock substrata.

11 community changes on artificial and natural substrata.

12 RF rates while interacting with two distinct substrata.

13 ional to the elastic modulus of the adhesive substrata.

14 axon outgrowth on rigid, but not compliant, substrata.

15 of breast cancer cells to tamoxifen on soft substrata.

16 cal or chemical cues upon contact with solid substrata.

17 ional simulations of cells migrating on flat substrata.

18 ownstream of integrin-linked kinase on stiff substrata.

19 elasticity of the cells and their underlying substrata.

20 cultured ex vivo on two-dimensional plastic substrata.

21 ly-defined human-derived media additives and substrata.

22 lamellipodial protrusions on permissive ECM substrata.

23 omplex essential for adhesion of the cell to substrata.

24 ovary cells migrating on fibronectin-coated substrata.

25 cation and promotes dissolution of carbonate substrata.

26 f blood platelets and cells to extracellular substrata.

27 and proportionately distributed within five substrata.

28 cellular aggregates deposited on each of the substrata.

29 vealed enhanced proliferation on vitronectin substrata.

30 -embryonic retinal neurite outgrowth on LN-1 substrata.

31 ollagenous) and independent (noncollagenous) substrata.

32 of vascular smooth muscle cells on gradient substrata (0-4 kPa/100 mum, with absolute moduli of 1-80

33 an either fibronectin (23% and 16%) or glass substrata (7% and 1%) at shear rates of 30 and 60 dyne/c

34 l region characterised by different geologic substrata, a key locality to test the influence of both

35 in mediating the initial binding of cells to substrata, a novel role for an unconventional myosin.

36 The wild fish from sites with anoxic substrata accumulate metals (including As and Se) from t

37 stoma cell movement in 3D matrices and on 2D substrata across a range of collagen densities with syst

38 not express p125(FAK) but upon adherence to substrata activate the highly related calcium-dependent

39 urons were cultured on control substrata and substrata adsorbed with full-length native MAG extracted

40 ophage cell adhesion to extracellular matrix substrata and anti-integrin antibodies.

41 were also cultured on 2-dimensional plastic substrata and collagen I hydrogels for analysis, and the

42 ed motility as a sheet in 2-dimensional (2D) substrata and individually in confined spaces and invasi

43 ved on several types of extracellular matrix substrata and leads to elevated stability of focal adhes

44 beta(3) mediated close contact to fibrinogen substrata and led to the formation of ringlike patterns

45 that are both the initial colonizers of hard substrata and of great economic importance, are almost u

46 d hillock formation by cells on serum-coated substrata and prevented spreading of cells on noncoated

47 oval cell adhesion to CTGF and fibronection substrata and promoting transforming growth factor (TGF)

48 Primary rat neurons were cultured on control substrata and substrata adsorbed with full-length native

49 ed on profibrotic conditions including stiff substrata and TGF-beta1, and analyzed in terms of morpho

50 tes the rate of neurite extension on diverse substrata and within the intact spinal cord.

51 tions produced by traction forces in elastic substrata, and interference reflection microscopy reveal

52 the adherence of B. burgdorferi to a decorin substrata, and they did not recognize decorin in an extr

53 Artificial substrata are common features in the inter- and shallow

54 ile the interactions of cells with polymeric substrata are widely studied, the influence of cell-cell

55 ars adhere firmly but temporarily to various substrata as a result of underwater efficient adhesive s

56 rdance and increased closeness in epithelial substrata as driving features for an elevated risk of ma

57 ed neuron cultures only traveled across CSPG substrata as fasciculated axon bundles.

58 l adhesion on different extracellular matrix substrata as well as changes in cell-cell adhesion and c

59 lts for the limiting case of migration on 2D substrata as well as with recent experiments in 3D natur

60 vis growth cones extending on permissive ECM substrata assemble adhesive point contacts containing en

61 eosomal fragmentation in response to loss of substrata attachment.

62 igosaccharides reduces neutrophil rolling on substrata bearing E-, L-, and P-selectins and neutrophil

63 hat are typically expanded in vitro on stiff substrata before reimplantation.

64 ) (electrotaxis) as they navigate non-planar substrata but the relative potencies of electrotaxis and

65 binding domain, clustered upon attachment to substrata coated with CEC1-5.

66 and-dependent fashion when cells attached to substrata coated with the adhesive ectodomain of Xenopus

67 with Xenopus C-cadherin mutant molecules and substrata coated with the purified ectodomain of C-cadhe

68 collapse occurs upon contact with repulsive substrata, collapse of the VD growth cones may result fr

69 eir gills whereas those from sites with oxic substrata concentrate these elements through their diet

70 tripe assays of alternating CSPG and control substrata confirmed the nonpermissive nature of CSPGs fo

71 markedly reduced when plated on collagenous substrata, despite normal attachment and spreading.

72 l and chemical composition of the underlying substrata elicit local Ca(2+) signals within growth cone

73 and minerals, usually considered as an inert substrata for microbial colonization.

74 n adaptation for adhesion to the most common substrata for mussels, i.e., calcareous materials.

75 l discs was incorporated into tissue culture substrata for the culture of the human neuronal cell lin

76 discoidin I or moving on discoidin I-coated substrata form fewer tandems, but the trailing cell stil

77 he ability to move over and colonize surface substrata has been linked to the formation of biofilms a

78 oped, but finding chemically defined, robust substrata has proven difficult.

79 s for cell migration on two-dimensional (2D) substrata have described how various molecular and cellu

80 cell cohesiveness in a series of copolymeric substrata having different levels of cell-substratum adh

81 and the interactions between them and their substrata help establish the early biofilm community.

82 s were plated onto serum-coated or noncoated substrata in serum-free medium.

83 examined by plating cells on collagen-coated substrata in the presence of the antibody.

84 uring development would not grow across CSPG substrata, in a concentration-dependent manner.

85 r advantage with CABG was also found in most substrata, including diabetes.

86 e of soluble pluripotency factors, compliant substrata inhibit the nuclear localization of YAP and pr

87 awling motion of Dictyostelium discoideum on substrata involves a number of coordinated events includ

88 In this report, we use hydrogel-based substrata matched to biological tissue stiffness to inve

89 Subconfluent cells on serum-coated substrata migrated together, forming aggregates, but cel

90 fficient differentiation of stem cells using substrata of biomatrix scaffolds, tissue-specific extrac

91 mals are unable to spread on or migrate into substrata of collagen IV and are deficient in spreading

92 th TGF-beta1 elicited distinct phenotypes on substrata of different stiffnesses.

93 ability to attach to and extend neurites on substrata of laminin-1 (LN-1) during late embryogenesis,

94 icant lead-ALS associations were observed in substrata of PINP and CTX levels.

95 These brain regions may represent the neural substrata of response inhibition independent of other co

96 odontitis, develops biofilm microcolonies on substrata of Streptococcus gordonii but not on Streptoco

97 eriodontitis, attaches and forms biofilms on substrata of Streptococcus gordonii.

98 imary rabbit corneal keratocytes on flexible substrata of varying stiffness in the presence (or absen

99 onectin- (FN) and Arg-Gly-Asp (RGD)-modified substrata of varying surface density.

100 e plasma membrane in cells cultured on stiff substrata or in collagen-rich regions of human breast tu

101 anical energies are more significant for the substrata possessing more flexible pillars.

102 Additionally, culture of cells on substrata presenting recombinant T-cadherin protein (ace

103 absence of neurogenic factors, the effective substrata produce neurons rapidly (2 wk) and more effici

104 cies strongly associated with carbonate-rich substrata; reef corals diversified dramatically; and the

105 ted collagen-I from each genotype as culture substrata, relative to r/r, we show that WT collagen-I p

106 , forming aggregates, but cells on noncoated substrata remained evenly dispersed.

107 achment of cells to a laminin or fibronectin substrata specifically modified the direction of gene ex

108 ts at deeper sites were replaced by unstable substrata such as fine sediments and rubble.

109 greater on plasma fibronectin than on other substrata such as laminin and merosin.

110 or byssus, opportunistically to a variety of substrata that are wet, saline, corroded, and/or fouled

111 where single or groups of cells are grown in substrata that have elements of basement membrane leadin

112 ugh neurites grew cathodally on both Plastek substrata, the frequency of anodal turning was greater o

113 tegrin-dependent motility on two-dimensional substrata to integrin-independent motion following entry

114 at can be harvested and deposited on various substrata to promote osteogenic differentiation.

115 y helps the zebra mussel to firmly attach to substrata underwater, thereby causing severe economic an

116 tile periphyton, leaves and natural benthic substrata using submerged electrified frames in three st

117 library" of structurally related copolymeric substrata varying in their adhesivity to cells and a lib

118 izing cell migration on two-dimensional (2D) substrata versus within three-dimensional (3D) matrices

119 ease of M(+) seed diaspores, which adhere to substrata via seed coat mucilage, thereby preventing dis

120 n or arginine-glycine-aspartate (RGD)-coated substrata, was enhanced significantly in these matrix-ad

121 ism, supported by liver extracellular matrix substrata; we envision that it will be used in the futur

122 In addition, migration rates over these substrata were two-fold higher and the level of focal ad

123 e glycol) content of a series of copolymeric substrata, whereas cell-cell cohesiveness was varied thr

124 Falcon tissue culture plastic or on laminin substrata, which are negatively charged, but neurites gr

125 We used a new silicone polymer to fabricate substrata whose compliance can be adjusted precisely by

126 thelial monolayers onto polydimethylsiloxane substrata with a range of viscosities and elasticities.

127 newal, and differentiation were inhibited on substrata with moduli of approximately 10 Pa.

128 nic cells were controlled on microfabricated substrata with regiospecific chemistry by confining atta

129 are protective against EMT, whereas stiffer substrata, with compliances characteristic of breast tum

130 Soft substrata, with compliances comparable to that of normal

131 Growth was oriented randomly on all substrata without an electric field.