ライフサイエンスコーパス: prosthetics

1 ing deep brain stimulation (DBS) and sensory prosthetics.

2 that have important implications for neural prosthetics.

3 e a potential substrate for brain-controlled prosthetics.

4 ous literature on the analysis of failed hip prosthetics.

5 s, from neurorehabilitation robots to neural prosthetics.

6 ficial tactile perception to manipulators or prosthetics.

7 al on metal junction utilized in modular hip prosthetics.

8 : skin-attachable electronics, robotics, and prosthetics.

9 of surrounding environment for robotics and prosthetics.

10 te the development of robotics, haptics, and prosthetics.

11 nal or subcutaneous microphones for auditory prosthetics.

12 ides a new logic for enhanced-acuity retinal prosthetics.

13 al to the design of effective auditory brain prosthetics.

14 stic imitation of human skin in robotics and prosthetics.

15 icable for bridging injured sites and active prosthetics.

16 a key determinant of the success of cochlear prosthetics.

17 hophysical vestibular testing and vestibular prosthetics.

18 o maximize patient susceptibility to sensory prosthetics.

19 applicability and ease of operation of motor prosthetics.

20 ctrical stimulation in the context of visual prosthetics.

21 several new topics in the arena of cortical prosthetics.

22 chlear optogenetics in auditory research and prosthetics.

23 bination of soft tissue repair and synthetic prosthetics.

24 aries during color matching in maxillofacial prosthetics.

25 ntial for safe and autonomous cortical motor prosthetics.

26 ia cell-type-specific optical neural control prosthetics.

27 y might help to increase the lifetime of the prosthetics.

28 of occlusion observed with smaller-diameter prosthetics.

29 dermatoses in patients with limb loss using prosthetics.

30 or network-can thus aid the future design of prosthetics(7), robot grasping tools and human-robot int

31 autonomous intelligent robots and biomimetic prosthetics, among other applications.

32 With the development of newer prosthetics and approaches to the ventral hernia repair,

33 onics and energy harvesting devices to smart prosthetics and human-machine interfaces.

34 devices could have profound implications for prosthetics and medicine.

35 urgical procedures enhance recovery, and new prosthetics and neural interfaces can replace missing li

36 n, conversion and harvesting, soft robotics, prosthetics and optomechanics.

37 hat can be applied to bio-inspired robotics, prosthetics and rehabilitation medicine, while also prov

38 esture-based interaction models in robotics, prosthetics and rehabilitation.

39 nsory systems with potential applications in prosthetics and robotics.

40 y, synaptic and neuromorphic bio-interfaces, prosthetics and robotics.

41 ials are necessary for advances in robotics, prosthetics and smart clothing.

42 as interactive wearable devices, artificial prosthetics and smart robots.

43 preliminary results demonstrate that emotion prosthetics and somatosensory interfaces offer new possi

44 uch as in minimally invasive surgery, active prosthetics, and automation tasks involving delicate irr

45 rategies for improved integration of retinal prosthetics, and for stem cell therapies, particularly t

46 ve subtle tactile sensation for robotics and prosthetics, and further be applied to haptic-based virt

47 the implant level, peri-implant soft tissue, prosthetics, and patient satisfaction.

48 improved referral for supportive counseling, prosthetics, and reconstruction.

49 s applications such as wearable electronics, prosthetics, and soft robotics.

50 ve garments, skin-like sensors for robots or prosthetics, and user interfaces in contaminated environ

51 Subretinal prosthetics are designed to electrically stimulate secon

52 es have demonstrated that the newer biologic prosthetics are reasonable options for hernia repair in

53 ant promise for applications in HCI, such as prosthetics, assistive technology, rehabilitation, and h

54 As retinal cell replacement therapies and prosthetics become increasingly viable, we must understa

55 litate semicircular canal (angular velocity) prosthetics but inhibit approaches with the otolith (lin

56 ential to simplify the manufacture of ocular prosthetics, but existing approaches just replace to var

57 e poor quality of vision returned by retinal prosthetics by reducing the signal-to-noise ratio of pro

58 r, AI in rehabilitation devices and advanced prosthetics can provide individualized support, as well

59 mulation, with future applications in neural prosthetics, chip scale neural engineering, and extensio

60 lth and establishing control interfaces with prosthetics, computer systems and wearable robotic devic

61 echnique for augmenting biomedical research, prosthetics design, and preoperative surgical assessment

62 f implantable therapeutic devices-oculomotor prosthetics-designed to modify eye movements dynamically

63 Implantable neural prosthetics devices offer a promising opportunity for th

64 ve the quality of vision elicited by retinal prosthetics, elicited neural activity should resemble ph

65 on with motor control, biologically embedded prosthetics enhance user capabilities and may elicit fee

66 oundations for using technology as cognitive prosthetics even during neurodegenerative illnesses.

67 Cortical neural prosthetics extract command signals from the brain with

68 Recent development of neural prosthetics for assisting paralyzed patients has focused

69 monkey research is the development of neural prosthetics for assisting paralyzed patients.

70 s with [(18)F]fluoride require (18)F-labeled prosthetics for bioconjugation more often with cysteine

71 ical microcircuits and the promise of neural prosthetics for patients with neurological and psychiatr

72 europsychiatric illness; powerful control of prosthetics for restorative function in degenerative dis

73 In addition to robotics and prosthetics, future applications include smart textiles

74 Retinal prosthetics have been designed to interface with the neu

75 trends in the device development for neural prosthetics have focused on establishing stimulus locali

76 Current prosthetics, however, are still very limited in the visi

77 In WT and RCS rats with active prosthetics, implant-driven responses were found in 100%

78 ing to ventral hernia repairs and the use of prosthetics in herniorrhaphy.

79 This may inspire similar approaches to prosthetics in other species by exploiting knowledge of

80 nd have implications for neuromodulation and prosthetics in patients with malignant gliomas.

81 movement provided the foundation for neural prosthetics in which brain-controlled interfaces are use

82 mb soft-tissue envelope change in lower-limb prosthetics is precise and can be used to detect the eff

83 rove the efficacy of microelectronic retinal prosthetics it will be necessary to better understand th

84 For robotics and prosthetics, large-area integration on 3D surfaces in a

85 tions that require variable color, including prosthetics, medical models, and indicators, among other

86 regularly shaped flexure bearings, compliant prosthetics, morphing structures, and soft robots.

87 For prosthetics, neural interfacing electrodes are of high i

88 Retinal prosthetics offer hope for patients with retinal degener

89 tients who receive implanted devices such as prosthetics or fixator pins.

90 y understand the properties of the available prosthetics or the circumstances that warrant the use of

91 ay with brain-machine interfaces, for bionic prosthetics, or biologically with hand replacement surge

92 ent sham surgery, implantation with inactive prosthetics, or no treatment.

93 es the quality of vision returned by retinal prosthetics, paving the way to novel clinical applicatio

94 Unfortunately, these prosthetics release significant levels of cobalt ions, w

95 y for motor control, the development of hand prosthetics remains a major challenge.

96 nsory characteristics in artificial skin and prosthetics remains challenging.

97 These prosthetics seek to mimic natural activity patterns to a

98 ction, and adaptive control in exoskeletons, prosthetics, smart wheelchairs, and navigation systems.

99 this new technology into neural stimulation prosthetics, such as cochlear implants for the deaf, wit

100 This has important implications for neural prosthetics, suggesting that accurate operation of a bra

101 Potential applications include prosthetics, surgical robots, and wearable devices, as w

102 rce for cognitive control signals for neural prosthetics that assist paralyzed patients.

103 Retinal prosthetics that can restore vision in animal models may

104 e pivotal for the design of advanced retinal prosthetics that elicit both percept and color.

105 opens up possibilities for high-level neural prosthetics that use hippocampal representations.

106 Neural prosthetics that use simultaneously a variety of cogniti

107 ecessary for the proper function of cochlear prosthetics, therefore, it is of great interest to under

108 strategy to "encode color" in future retinal prosthetics through a predictive computational tool to s

109 Motor prosthetics to date have typically used the motor cortex

110 s a promising approach in rehabilitation and prosthetics to model the series of transformations from

111 alysis of body fluids, (ii) smart gloves and prosthetics to realise the sensation of touch and pain,

112 s, aid rehabilitation, and provide symbiotic prosthetics to replace limbs.

113 physicians, who implant life-changing penile prosthetics, to understand the most recent advances in t

114 een the synthetics, composites, and biologic prosthetics used for ventral hernia repair in terms of m

115 orrosion mechanisms of metal based implanted prosthetics utilized in modern surgical procedures.

116 such as SMA, as well as for next generation prosthetics, utilizing in vitro phenotypic models would

117 fields such as healthcare, robotic systems, prosthetics, visual realities, professional sports, ente

118 ithms can improve the performance of retinal prosthetics where substantial irregularities arise at th

119 Recent efforts to develop smart prosthetics, which exploit rigid and/or semi-flexible pr

120 g implies that, with current methods, visual prosthetics will have a limited dynamic range available

121 tect and repair damage, or robotic skins and prosthetics with a realistic sense of touch.

122 tics, and the development of next-generation prosthetics with neuromorphic tactile feedback.

123 on, P3HT NPs provide a new avenue in retinal prosthetics with potential applications not only in reti