ライフサイエンスコーパス: bioinspired material

1 rt with implications for biogeochemistry and bioinspired materials.

2 lar-level insight into the dynamics of these bioinspired materials, and a flexible tool to obtain str

3 ed to determine the suitability of the novel bioinspired material architecture for use in running sho

4 gs have implications for the design of novel bioinspired material architectures for minimizing impact

5 Examples of current bioinspired materials are also introduced for each eleme

6 Bioinspired material can be developed with electrospun c

7 Bioinspired materials chemistry of organic electronics p

8 s remain a popular source of inspiration for bioinspired materials design and engineering.

9 nessing phase separation for applications in bioinspired materials design.

10 in complex biological assemblies and inform bioinspired materials design.

11 Here, we report a bioinspired material, engineered fusogen and targeting m

12 c mortar, the potential for optimizing these bioinspired materials for damage tolerance has still not

13 shed themselves as promising self-assembling bioinspired materials in a wide range of medical fields.

14 understanding related chemical phenomena of bioinspired materials in diverse technological and funda

15 ing multifunctionality and could thus inform bioinspired material innovations.

16 ng inspiration in living organisms to create bioinspired materials is the subject of intensive resear

17 A long-standing challenge in bioinspired materials is to design and synthesize synthe

18 Bioinspired materials possess many advantages, such as b

19 Through modeling, we design bioinspired materials systems that spontaneously form sh

20 st two decades and afforded many examples of bioinspired materials that are able to reversibly alter

21 rfaces are an important and growing class of bioinspired materials that combine the structural and fu

22 t these assemblies provide a new approach to bioinspired materials that have unique electro-optic fun

23 Although ice-templating can create bioinspired materials, the achievable structures remain

24 also indicate the feasibility of artificial bioinspired materials using tunable carrier systems to m

25 pportunities arising from the combination of bioinspired materials with biological and computational

26 ese insights provide a roadmap for designing bioinspired materials with self-organizing capabilities,

27 how size effects can be exploited to create bioinspired materials with superior mechanical propertie