ライフサイエンスコーパス: biocatalysis

1 dvances in activating enzymes for nonaqueous biocatalysis.

2 ro NAD(P)H regeneration system for reductive biocatalysis.

3 approaches have found novel applications in biocatalysis.

4 ented by interfacing chemical catalysis with biocatalysis.

5 a key technology for enzyme engineering and biocatalysis.

6 and encompasses both enzymatic and microbial biocatalysis.

7 hanging the rules of the game for industrial biocatalysis.

8 the analysis of single-cell stereoselective biocatalysis.

9 cs of the natural coenzymes NAD(P)H in redox biocatalysis.

10 he design of multicapable systems that mimic biocatalysis.

11 etabolic engineering, synthetic biology, and biocatalysis.

12 nt of water, remains a fundamental puzzle in biocatalysis.

13 te engineering in PKS functional studies and biocatalysis.

14 stems for sustainable chemical catalysis and biocatalysis.

15 tation of these enzymes in bioremediation or biocatalysis.

16 nd (as we focus on here) for exploitation in biocatalysis.

17 s of this enzyme with improved stability for biocatalysis.

18 nt molecules that can be synthesized through biocatalysis.

19 or as artificial cell factories for in situ biocatalysis.

20 and stereoselectivity that is a hallmark of biocatalysis.

21 n of regioselective C-H functionalization in biocatalysis.

22 h heat treatments, chemical modifications or biocatalysis.

23 tform for immobilizing enzymes in industrial biocatalysis.

24 ential biological platform for methane-based biocatalysis.

25 se-1 is shown to play a vital role in tuning biocatalysis.

26 ll as the applications of these materials in biocatalysis.

27 complexation play critical roles in driving biocatalysis.

28 e, particularly in the context of industrial biocatalysis.

29 '-O-glucosides through the use of whole-cell biocatalysis.

30 icrowave irradiation can be used to regulate biocatalysis.

31 nvironmental pollutants to energy-generating biocatalysis.

32 py and molecular analyses showed evidence of biocatalysis activity on metal-free cathodes.

33 enes and Genomes and University of Minnesota Biocatalysis and Biodegradation Database.

34 Microbial reactions play key roles in biocatalysis and biodegradation.

35 e environment and are potentially useful for biocatalysis and bioremediation.

36 aminases are valuable enzymes for industrial biocatalysis and enable the preparation of optically pur

37 eering applications, such as bioremediation, biocatalysis and microbial fuel cells.

38 Here, by combining biocatalysis and molecular self-assembly, we have shown

39 make them ideal candidates for the study of biocatalysis and protein thermostability at extremely hi

40 erate X-X bonds could both provide tools for biocatalysis and synthetic biology, as well as guide eff

41 microorganisms is central to strategies for biocatalysis and the bioremediation of contaminated envi

42 s broad implications in the areas of applied biocatalysis and understanding of oxidative protein modi

43 molecular design in pharmaceutical research, biocatalysis, and agrochemical development.

44 r applications in drug delivery, bioimaging, biocatalysis, and cell mimicry.

45 applications in bioseparation, immunoassays, biocatalysis, and drug delivery.

46 mes, used extensively in immunochemistry and biocatalysis applications.

47 We describe a chemomimetic biocatalysis approach that draws from small-molecule cat

48 he literature on organic enzyme cofactors in biocatalysis, as well as automatically collected informa

49 ial for molecular targeting, recognition and biocatalysis, as well as molecular information storage.

50 ld provide a platform for the realization of biocatalysis at high temperatures or in anhydrous solven

51 Notably, biocatalysis at silicon was observed.

52 During the last decades, biocatalysis became of increasing importance for chemica

53 The University of Minnesota Biocatalysis/Biodegradation Database (UM-BBD) began in 1

54 The University of Minnesota Biocatalysis/Biodegradation Database (UM-BBD) is a websi

55 les are based on the University of Minnesota biocatalysis/biodegradation database and the scientific

56 The University of Minnesota Biocatalysis/Biodegradation Database begins its fifth ye

57 The University of Minnesota Biocatalysis/Biodegradation Database first became availa

58 Likewise, the University of Minnesota Biocatalysis/Biodegradation Database focuses on novel en

59 The University of Minnesota Biocatalysis/Biodegradation Database provides curated in

60 The University of Minnesota Biocatalysis/Biodegradation Database provides curated in

61 As the University of Minnesota Biocatalysis/Biodegradation Database starts its second d

62 pathway data of the University of Minnesota Biocatalysis/Biodegradation Database.

63 rain, chemical and reference data related to biocatalysis, biotransformation, biodegradation and bior

64 etabolic engineering, synthetic biology, and biocatalysis, but it has rarely been applied to bioelect

65 efore raises the question concerning whether biocatalysis can be undertaken in the absence of a prote

66 Biocatalysis can be used in both simple and complex chem

67 s that innovative developments in chemo- and biocatalysis can have on the synthesis of pharmaceutical

68 In particular, recent developments in biocatalysis combined with novel process engineering are

69 Targeted advances in biocatalysis could provide affordable and sustainable tr

70 s nonredox electrochemical approach based on biocatalysis-coupled proton transfer at the mu-ITIES arr

71 low-cost, and easy-to-operate biosensing and biocatalysis devices.

72 ected material assembly, structural biology, biocatalysis, DNA computing, nanorobotics, disease diagn

73 undational organism for archaeal research in biocatalysis, DNA replication, metabolism, and the disco

74 gy of chemical synthesis and ENGase-mediated biocatalysis enabled the first synthesis of a glycoprote

75 Biocatalysis engineering concerns the development of enz

76 use of protein engineering, other aspects of biocatalysis engineering, such as substrate, medium, and

77 is lies at the heart of our understanding of biocatalysis, enzyme evolution, and drug development.

78 Biocatalysis exploits the versatility of enzymes to cata

79 model system for studies of membrane protein biocatalysis, folding, stability, and structure.

80 o bioremediation and potential future use in biocatalysis for chemical production.

81 Further development of biocatalysis for green chemistry and high productivity p

82 Given the recent developments in biocatalysis for non-natural chemistries and the renaiss

83 critical review presents an introduction to biocatalysis for synthetic chemists.

84 omise for the future development of designer biocatalysis for the selective late-stage modification o

85 Combinatorial biocatalysis harnesses the natural diversity of enzymati

86 Biocatalysis has always been a key focus area in biotech

87 ion, and their potential for applications in biocatalysis has attracted increasing attention.

88 Biocatalysis has become an important method in the pharm

89 t artificial catalysts that can compete with biocatalysis has been an enduring challenge which has ye

90 ent of dehalogenating enzymes for industrial biocatalysis has been limited, but significant advances

91 Biocatalysis has grown rapidly in recent decades as a so

92 f biological situations, their occurrence in biocatalysis has not been widely appreciated.

93 Biocatalysis has widened its scope and relevance since n

94 However, to date, advances in methane biocatalysis have been constrained by the low-productivi

95 modes promises to expand the applications of biocatalysis in chemical synthesis and will enhance our

96 emisynthetic approach and the application of biocatalysis in enabling the semisynthesis of paclitaxel

97 he state of the art on the design and use of biocatalysis in flow reactors.

98 nology will further expand the repertoire of biocatalysis in the coming years to new chemistries and

99 The importance of biocatalysis in the context of green and sustainable che

100 Important recent advances in combinatorial biocatalysis include iterative derivatization of small m

101 nd enzyme-substrate couplings in interfacial biocatalysis induce spatial correlations beyond the capa

102 Biocatalysis inherently offers the prospect of clean ind

103 Combinatorial biocatalysis is a powerful addition to the expanding arr

104 Combinatorial biocatalysis is an emerging technology in the field of d

105 Consequently, biocatalysis is being widely applied in the production o

106 green chemistry and sustainable development, biocatalysis is both a green and sustainable technology.

107 Biocatalysis is continuing to gain momentum and is now b

108 Biocatalysis is currently employed to produce known subs

109 n laccase-based, N-hydroxy compound-mediated biocatalysis is discussed.

110 Increasing attention to applied biocatalysis is motivated by its numerous economic and e

111 and how of enzyme immobilisation for use in biocatalysis is presented.

112 Nonaqueous biocatalysis is rapidly becoming a desirable tool for ch

113 approach for engineering multi-step cascade biocatalysis is useful for developing other new types of

114 ogeneous, heterogeneous, organocatalysis and biocatalysis--is discussed.

115 The area of biocatalysis itself is in rapid development, fueled by b

116 enhance understanding of basic biochemistry, biocatalysis leading to speciality chemical manufacture,

117 e strategy not only for applications such as biocatalysis, live-cell vaccines, and protein engineerin

118 als for applications in vaccine development, biocatalysis, materials science, and synthetic biology.

119 y of this flavoenzyme, which is critical for biocatalysis of enantiomerically pure amino acids.

120 crobium buryatense, we demonstrate microbial biocatalysis of methane to lactate, an industrial platfo

121 ions involved the formation of H2O2 by FcAOx biocatalysis of substrate alcohol followed by HRP-cataly

122 Advances in biocatalysis of the past 5 years illustrate the breadth

123 evelopment of new systems for drug delivery, biocatalysis, or materials synthesis.

124 scuss advances in developing halogenases for biocatalysis, potential untapped sources of such biocata

125 The potential of biocatalysis relative to mature (nonselective ion exchan

126 olecular mechanisms of the physical steps in biocatalysis remain elusive due to the difficulties of c

127 tease structure and function unifies 50 y of biocatalysis research, providing a framework for the con

128 model system for studies of membrane protein biocatalysis, stability, folding, and misfolding.

129 cting as transferases are interesting from a biocatalysis standpoint, and knowledge about the interco

130 ow these demands are being addressed to make biocatalysis successful, particularly by the use of micr

131 vel type of remote controlled phase-boundary biocatalysis that involves remotely directed binding to

132 nase superfamily enzymes for stereoselective biocatalysis, the amenability of carbapenem biosynthesis

133 ecules in liquids and for monitoring in situ biocatalysis, the use of atomic force microscopy as a fo

134 strictions on merging chemical catalysis and biocatalysis to create highly active, productive, and se

135 This work underscores the maturation of biocatalysis to enable efficient, economical, and enviro

136 onalizations of terminal alkenes via cascade biocatalysis to produce chiral alpha-hydroxy acids, 1,2-

137 proven useful in a variety of settings from biocatalysis to vaccinology.

138 Biocatalysis using flavin-containing Baeyer-Villiger mon

139 highlighted, as is the discussion concerning biocatalysis versus nonbiological catalysis in synthetic

140 Whether biocatalysis will have a significant technological impac

141 ty to act as supports for enzymes for use in biocatalysis with a particular focus on the ability to t

142 moiety of caffeic acid can be polymerized by biocatalysis with laccase or horseradish peroxidase.

143 In situ formation of mineral particles by biocatalysis would be advantageous for occluding dentin