ライフサイエンスコーパス: biomedical engineering

1 e fields such as architectural acoustics and biomedical engineering.

2 cted considerable interest in biophysics and biomedical engineering.

3 controlled drug delivery, and other areas of biomedical engineering.

4 is a ubiquitous problem in biotechnology and biomedical engineering.

5 ctronics in sports, military, aerospace, and biomedical engineering.

6 real-world applications of bioinformatic and biomedical engineering.

7 ations including energy, photocatalysis, and biomedical engineering.

8 eaning, fluid mixing and emulsification, and biomedical engineering.

9 weather forecasting, structural dynamics or biomedical engineering.

10 different as soft robotics, aeronautics, or biomedical engineering.

11 their applications as implantable devices in biomedical engineering.

12 in energy, sensing, analytical chemistry and biomedical engineering.

13 nce alloys for applications in aerospace and biomedical engineering, among others.

14 due to their suitability for applications in biomedical engineering and environmental remediation.

15 a versatile cell chassis for biotechnology, biomedical engineering and living therapeutics.

16 ts microbial EPSs have a promising future in biomedical engineering and medicine, especially as an al

17 e their potential for future applications in biomedical engineering and microrobotics, marking a step

18 presenting a promising therapeutic avenue in biomedical engineering and nanomedicine.

19 treatment modalities, combining advances in biomedical engineering and neurotechnology development w

20 tion with the Center for Medical Physics and Biomedical Engineering and the Department of Ophthalmolo

21 l remediation (such as CO(2) sequestration), biomedical engineering, and energy storage where fast cr

22 l breakthroughs in treatment modalities from biomedical engineering, and in our ability to conduct we

23 s in fields, such as medicine, biocomputing, biomedical engineering, and measurement science.

24 provide reliable tools for neuroscience and biomedical engineering applications, the maturity of thi

25 ing, with applicability to soft robotics and biomedical engineering applications.

26 Here, we review biomedical engineering approaches that harness the power

27 armacy, Occupational Therapy, Logopedia, and Biomedical Engineering As a whole, the basic concepts of

28 nique opportunities to advance materials and biomedical engineering, as well as fundamental understan

29 f Radiobiology and Biomedical Imaging and of Biomedical Engineering at Yale School of Medicine (New H

30 s review, the potential uses of LbL films in biomedical engineering based mainly on the assembly of p

31 with a special focus on drug development and biomedical engineering, big data and information technol

32 The unmet chemistry and biomedical engineering challenge to develop controlled r

33 -optical chips in photonics, photochemistry, biomedical engineering, chemical engineering, and beyond

34 uraging, the initial methods reported in the biomedical engineering community to construct home-built

35 st for applications in materials science and biomedical engineering due to its natural abundance, des

36 ersatile tools in both materials science and biomedical engineering due to their tunable properties a

37 -depth analysis of bibliometric data for 186 biomedical engineering faculty members and from extensiv

38 noisy background in microfluidic devices of biomedical engineering fields.

39 s Viewpoint provides guidelines conscious to biomedical engineering for institutions looking to expan

40 Recent approaches in biomedical engineering have employed intelligent systems

41 Recent advances in developmental biology and biomedical engineering have significantly improved the e

42 Recent advancements in the field of biomedical engineering have underscored the pivotal role

43 ng and detection (LiDAR), machine vision and biomedical engineering; however, bulky system size and s

44 e the use of hybrid nanomaterials to advance biomedical engineering in the context of nanomedicine, r

45 fluids are rising in the areas of energy and biomedical engineering including smart (functional) coat

46 In a recent issue of Nature Biomedical Engineering, Ingrole et al. explore a new app

47 All biomedical engineering journals, and the 5 basic science

48 wider application of this technology outside biomedical engineering laboratories.

49 earch has applications in materials science, biomedical engineering, multiphase fluid dynamics, among

50 d finally their applications in the field of biomedical engineering, particularly biosensing, cell an

51 ossible by contributions from electrical and biomedical engineering, physics, mathematics and compute

52 ndamental knowledge, and the applications in biomedical engineering related to in-cell structural bio

53 (Au) colloids are becoming ubiquitous across biomedical engineering, solar energy conversion, and nan

54 Attention must be paid to providing biomedical engineering support and to directing resource

55 There is an unmet need for biomedical engineering support in Syrian trauma hospital

56 ication areas, including tissue engineering, biomedical engineering, sustainable manufacturing, and s

57 n continuous progress in the development for biomedical engineering systems of hybrid muscle generate

58 In a recent issue of Nature Biomedical Engineering, Tang et al. introduced Cas12a kn

59 ancer engineering is an emerging subfield of biomedical engineering that unifies engineering and canc

60 applications in data storage, catalysis, and biomedical engineering through an added surface function

61 The most visible contributions of biomedical engineering to clinical practice involve inst

62 ications range from functional textiles over biomedical engineering to high-performance filtering and

63 ell biology-will greatly expand the scope of biomedical engineering to tackle challenges in molecular

64 tional design and construction of 2D-GAs for biomedical engineering, which are believed to promote th

65 tional Work-Conference on Bioinformatics and Biomedical Engineering, which was held on line, during S