ライフサイエンスコーパス: smart material

1 l for the development of biologically based "smart materials".

2 ide expands its technological potential as a smart material.

3 at may ultimately lead to the development of smart materials.

4 of a new class of anion-coordination-driven smart materials.

5 stimuli is crucial for developing versatile smart materials.

6 closer to the application of mechanochromic smart materials.

7 uld enable previously impossible devices and smart materials.

8 ld has great potential in the development of smart materials.

9 in order to access an entirely new class of smart materials.

10 roperties with potential for applications as smart materials.

11 been an essential motivation in the study of smart materials.

12 logical change in protein-based mu3D-printed smart materials.

13 lecules which can lead to stimuli-responsive smart materials.

14 ng task-specific properties is a step toward smart materials.

15 macromolecules that can be crafted into new smart materials.

16 romote the development of new generations of smart materials.

17 acid-based nanostructures and functionalized smart materials.

18 ve nanocages that might find applications as smart materials.

19 solid state remains an enormous challenge in smart materials.

20 rsatility for reconfigurable multifunctional smart materials.

21 ts that can be incorporated as components in smart materials.

22 tly hindered the further development of such smart materials.

23 arch areas spanning from chemical biology to smart materials.

24 rocesses, control photochemistry, and design smart materials.

25 H, which have been used as triggers for many smart materials.

26 plications ranging from synthetic biology to smart materials.

27 mations present an entirely new approach to 'smart' materials.

28 eld nanotextures opens new possibilities for smart materials(15), unconventional computing(2,16), par

29 Shape memory materials are a class of smart materials able to convert heat into mechanical str

30 The shape-change of 3D printed smart materials adds an active dimension to the configur

31 hanical functions is essential for advancing smart materials and bioengineering.

32 suggests an approach for the development of smart materials and devices that autonomously reconfigur

33 There has been a recent surge of interest in smart materials and devices with stimuli-responsive prop

34 cus on the structure-property correlation in smart materials and functional devices.

35 sing direction for designing next-generation smart materials and large-scale robotic swarms.

36 Smart materials and magnetic separation further improve

37 on potential in areas including adaptive and smart materials and mechanical logic, wherein concepts f

38 telemedicine, flexible and wearable sensing, smart materials and metamaterials.

39 on surfaces, with potential applications in smart materials and molecular electronic devices.

40 ing challenges in colloidal self-assembly of smart materials and provide a perspective on their furth

41 des a new and robust approach for delivering smart materials and structures for self-powered wireless

42 with potential applications in the design of smart materials and surfaces.

43 table interest due to the growing demand for smart materials and therapeutics necessitating benign st

44 extensively studied in display technologies, smart materials, and energy storage applications.

45 est stabilization, drug delivery, catalysis, smart materials, and many other related fields.

46 emistry, single-molecule force spectroscopy, smart materials, and molecular machines.

47 application of this process in nanomedicine, smart materials, and reagent trafficking.

48 The goals are knowledge, tools, smart materials, and therapies.

49 r platform is used to generate pH-responsive smart materials, and to easily control various sizes, sh

50 Smart materials are created in nature at interfaces betw

51 eprint for developing the next generation of smart materials, autonomous micromachinery and artificia

52 nd could pave the way for the development of smart materials by incorporating fundamental principles

53 using the organic linkers as antennae, novel smart materials can be developed, acting as sensors and

54 push the frontiers of microrobots and where smart materials can have a major impact on such future a

55 Smart materials can respond to stimuli and adapt their r

56 The bistable electroactive polymer is a new smart material capable of large strain, rigid-to-rigid a

57 nts in these four categories and discuss how smart materials contribute to the progress in the exciti

58 etic cells and tissues, to the generation of smart material devices in medicine.

59 xers of liquids, based on electro-responsive smart materials (dielectric elastomer actuators).

60 d to be one of the most interesting soft and smart materials due to their ability to construct polyme

61 Because of the "smart" material ECM, this scaffold may have the potentia

62 essly integrates additive manufacturing with smart materials, enabling the creation of multiscale obj

63 Although many artificial smart materials exhibit non-directional, nastic behaviou

64 Miniaturized passive fliers based on smart materials face challenges in precise control of sh

65 programming, with implications for designing smart materials for cell fate engineering.

66 orbent but proposes a new route to construct smart materials for efficient separations.

67 e rapidly gaining traction as a new class of smart materials for energy conversion, however, they are

68 s versatility, the application of artificial smart material in the field of heterogeneous photocataly

69 Emerging applications of these dynamic smart materials in the contexts of molecular recognition

70 3D materials reveals a powerful approach to smart materials in which the capabilities of multifuncti

71 uch as biosensors, genetic logic gates, and "smart" materials, in which highly responsive behavior is

72 erted to devices upon functionalization with smart materials, including self-organized electronics, p

73 rs have also been used in the development of smart materials, including stimuli-responsive coatings,

74 e how the unique and versatile properties of smart materials may be exploited in a wide range of appl

75 th monitoring at molecular levels related to smart materials mostly limited to single use, issues of

76 Herein, we report the generation and use of "smart materials", namely molecularly imprinted polymers

77 and performance of a novel type of advanced smart materials, namely, biocomputing agents.

78 Although recent soft robots using smart materials offer advantages, difficulties remain in

79 ly into robust and reliable high-performance smart materials often involves crystalline ordering in c

80 strate great potential in the development of smart materials owing to their attractive dynamic proper

81 The tailoring of smart material properties is one of the challenges in ma

82 ropyl acrylamide) (PNIPAAm) is a well-known 'smart' material responding to external stimuli such as t

83 e as well as their promising applications in smart materials, sensing and diagnostics.

84 agrochemicals, derives from the benefits of smart materials (SMs), data science, and nanosensors.

85 has recently been focused on a new class of smart materials--so-called left-handed media--that exhib

86 In parallel, the incorporation of advanced smart materials, such as metal-organic frameworks (MOFs)

87 sites could enable a new generation of truly smart material systems that can change their appearance

88 s (EMSCs) are reported to serve as a living, smart material that creates a permissive, all-in-one nic

89 Switchable MOFs are a type of smart material that undergo distinct, reversible, chemic

90 both in vivo and ex vivo; and production of smart materials that are able to drive cell fate.

91 Developing bio-compatible smart materials that assemble in response to environment

92 polymers provides a strategy for generating smart materials that can respond to environmental stimul

93 Smart materials that can respond to external stimuli are

94 aterials are emerging as the next generation smart materials that have shown promise in advancing a w

95 Smart materials that mimic the ability of living systems

96 olymers have emerged as a promising class of smart materials that possess the unique ability to under

97 ynamic shape-morphing applications including smart materials that process mechanical information acco

98 rfaces of the body, comprises an inherently "smart" material that gives hard bones added strength und

99 nts that help stabilize bodily functions to 'smart' materials that regulate energy usage.

100 ew and effective way to design molecules for smart materials through mimicking a sophisticated biofun

101 holds promise for applications ranging from smart materials to integrated biophysical models for syn

102 d materials, with applications spanning from smart materials to optoelectronics to quantum computatio

103 his model system suggests the possibility of smart materials where aging or mechanical damage trigger

104 in developing reconfigurable multifunctional smart materials, which can exhibit remarkable behaviors

105 alves, for cellular environments composed of smart materials whose size, shape, permeability, stiffne

106 ce properties, biosensing, nanomedicine, and smart materials will widen their application.

107 erties represent a new class of actuators or smart materials with a set of properties that include hi

108 ms can provide a novel form of functional or smart materials with capability for evolutionary adaptat

109 rtensitic materials are an emerging class of smart materials with enormous tunability in physicochemi

110 They are a unique class of smart materials with great potential in a broad range of

111 Bioinspired smart materials with synergistic allochroic luminescence

112 crystals carry a great potential as new soft smart materials, with a plethora of recent examples over