ライフサイエンスコーパス: photopolymerization

1 d molecular precision of the two-dimensional photopolymerization.

2 s that of materials produced by conventional photopolymerization.

3 are the molecular structure before and after photopolymerization.

4 xyethyl methacrylate) (pHEMA) by ultraviolet photopolymerization.

5 with use of single- or two-photon absorption photopolymerization.

6 ght is used simultaneously to deactivate the photopolymerization.

7 adient is established, it is immobilized via photopolymerization.

8 , UV-transparent fused-silica capillaries by photopolymerization.

9 fabricated inside microfluidic channels via photopolymerization.

10 protein sizing-were fabricated in situ using photopolymerization.

11 lymer hologram created by two-photon-induced photopolymerization.

12 desired direction, so to allow topochemical photopolymerization.

13 n micropatterned epoxy channels, followed by photopolymerization.

14 brushes were generated via surface-initiated photopolymerization and sequentially functionalized usin

15 lycol) (PEG) hydrogels formed by "thiol-ene" photopolymerization and tested as a cell-based neurotoxi

16 Photopolymerizations are widely used in medicine to crea

17 used to fabricate polymeric microchips, the photopolymerization-based method used with the copolymer

18 Photopolymerization can be used to construct materials w

19 Photopolymerization efficacies of the two self-etch adhe

20 namic or static application), to investigate photopolymerization efficacy on dentin, and to understan

21 ains were fixed at the oil interface through photopolymerization, enabling direct visualization of or

22 idity of these modeling studies, transdermal photopolymerization first was applied to tissue engineer

23 on and test the applicability of transdermal photopolymerization for drug release devices, albumin, a

24 nning calorimetry, we monitored the rates of photopolymerization for various experimental conditions.

25 A unified patterning strategy via frontal photopolymerization (FPP) that is robust to a wide range

26 tiators, permitting simultaneous and dynamic photopolymerization from positive sites to 0.5-nM target

27 olvent transfer-induced phase separation and photopolymerization have exceptionally high nanoparticle

28 Conditions for photopolymerization, hybridization, and denaturation are

29 d in polycarbonate microfluidic channels via photopolymerization in a polyacrylamide matrix.

30 characteristics were produced by solid-state photopolymerization in the presence of template molecule

31 etrates tissue including skin, could cause a photopolymerization indirectly.

32 stabilize the monolayer, in situ ultraviolet photopolymerization induces covalent bonding between nei

33 age makes the NHC-boryl sulfides good type I photopolymerization initiators for the polymerization of

34 ad zone" (persistent liquid interface) where photopolymerization is inhibited between the window and

35 Photopolymerization kinetic studies demonstrate that the

36 The platform combines liquid-phase photopolymerization, lithography, and laminar flow to al

37 substrate surfaces using controlled radical photopolymerization, maintaining the advantages of class

38 We describe a novel photopolymerization method to coat quantum dots (QDs) wi

39 Besides traditional photopolymerization methods, namely free radical and cat

40 These photopolymerizations occur by directly exposing material

41 frits made of macroporous polymers by the UV photopolymerization of a solution of glycidyl methacryla

42 icated in fused-silica capillaries by the UV photopolymerization of a solution of glycidyl methacryla

43 JP) concept with simultaneously performed UV photopolymerization of a specifically prepared acrylamid

44 e, and laser flash photolysis in addition to photopolymerization of acrylates were performed to eluci

45 This analysis indicates that the photopolymerization of appropriately designed LUV can de

46 In each case, photopolymerization of bis-SorbPC lowered the critical f

47 ficiencies of the sulfonium salts toward the photopolymerization of cyclohexene oxide depend on the c

48 anical injector is implemented using in situ photopolymerization of fluorinated acrylates inside wet-

49 r (sodium diethyl dithiocarbamate) initiated photopolymerization of functional monomer (2,4,6-trisacr

50 mobilization were prepared by direct in situ photopolymerization of glycidyl methacrylate and ethylen

51 er was prepared in a microfluidic channel by photopolymerization of glycidyl methacrylate and trimeth

52 ation involved constructing frits by in situ photopolymerization of glycidyl methacrylate and trimeth

53 heavy water, the chemical conversion during photopolymerization of hydrogel precursor formulations c

54 ation of methacrylate-based monomers and the photopolymerization of methyl methacrylate and made it p

55 The first bulk photopolymerization of multifunctional alkyne and azide

56 We also demonstrate the photopolymerization of plugs containing different DNA pr

57 id monomer bearing three photoreactive arms, photopolymerization of the crystalline monomers by [4 +

58 This emission, however, disappears upon photopolymerization of the NPs.

59 ed beforehand, or in-situ by evanescent-wave photopolymerization on the fiber.

60 Compression followed by photopolymerization on the interface provides the two-di

61 onal gradients using perfusion-based frontal photopolymerization (PBFP).

62 o-initiators in increasing the efficiency of photopolymerization (polymer chains formed per excitatio

63 The photopolymerization process is accompanied by a large ma

64 A films can be prepared based on chemical or photopolymerization processes.

65 Bulk photopolymerization produces stratified three-dimensiona

66 y the smectic layering dramatically enhanced photopolymerization rates; for HDDA, termination rates w

67 al and mechanical characteristics during the photopolymerization reaction is desired.

68 heating hood enable the characterization of photopolymerization reactions at elevated temperatures,

69 In photopolymerization reactions, mostly multifunctional mo

70 The first photopolymerization step uses a thiolene-based resin wit

71 gle-cell sorting method using two sequential photopolymerization steps that enables sorting based upo

72 AM techniques covered include vat photopolymerization (stereolithography), powder bed fusi

73 Current photopolymerization strategies used to prepare hydrogels

74 incoherent forms spontaneously in a nascent photopolymerization system.

75 A gel photopolymerization technique is introduced to produce m

76 articular, by taking advantage of two-photon photopolymerization techniques to make knot-shaped micro

77 lent interactions to template a topochemical photopolymerization that yields a polydiphenyldiacetylen

78 Upon photopolymerization, the director field can be faithfull

79 posome fusion was dependent on the extent of photopolymerization, the temperature, and the pH.

80 mpared to other traditional step-growth bulk photopolymerization, this approach readily provides cros

81 show that C4N2 ices undergo condensed-phase photopolymerization (tholin formation) at wavelengths as

82 The monomer was solidified via photopolymerization to form the above-mentioned membrane

83 he fundamental principle of oxygen-inhibited photopolymerization to generate a continual liquid inter

84 ated into PEG hydrogels via a thiol-acrylate photopolymerization to render an otherwise inert PEG hyd

85 lymer monoliths were cast in the channels by photopolymerization to serve as a robust and uniform sta

86 The second photopolymerization uses (poly)ethylene glycol diacrylat

87 ingle crystal analysis have been prepared by photopolymerization using digital light projection stere

88 Photopolymerization was used to attach the microspots to

89 Using two-photon photopolymerization, we fabricate colloidal microparticl

90 copolymer template enhances the topochemical photopolymerization, which is complete within a 20 s exp

91 se nonuniform temperature changes and uneven photopolymerization within the resin restoration.

92 in PEG hydrogel spheres by reverse emulsion photopolymerization, yielding spheres with a size range

93 Single step surface-initiated photopolymerization yields a covalently attached polymer