TY - JOUR
T1 - The use of artificial intelligence and robotics in regional anaesthesia
AU - McKendrick, M.
AU - Yang, S.
AU - McLeod, G. A.
N1 - Funding Information:
We thank the Asimov Institute, Utrecht, The Netherlands, for permission to use their images of artificial neural networks. MM and GM have received grants from B. Braun and Philips to conduct research studies. MM is CEO of Optomize Ltd, a psychology and eye tracking company. GM is a member of the European Scientific Advisory Board of B. Braun/Philips. He received payment to present research on their behalf at ESRA 2018, Dublin and ESRA 2019, Bilbao. GM is a member of the advisory board of the Medical Device Manufacturing Centre, Heriot Watt University, Edinburgh, UK. No other competing interests declared.
Publisher Copyright:
© 2021 Association of Anaesthetists
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
PY - 2021/1
Y1 - 2021/1
N2 - The current fourth industrial revolution is a distinct technological era characterised by the blurring of physics, computing and biology. The driver of change is data, powered by artificial intelligence. The UK National Health Service Topol Report embraced this digital revolution and emphasised the importance of artificial intelligence to the health service. Application of artificial intelligence within regional anaesthesia, however, remains limited. An example of the use of a convoluted neural network applied to visual detection of nerves on ultrasound images is described. New technologies that may impact on regional anaesthesia include robotics and artificial sensing. Robotics in anaesthesia falls into three categories. The first, used commonly, is pharmaceutical, typified by target-controlled anaesthesia using electroencephalography within a feedback loop. Other types include mechanical robots that provide precision and dexterity better than humans, and cognitive robots that act as decision support systems. It is likely that the latter technology will expand considerably over the next decades and provide an autopilot for anaesthesia. Technical robotics will focus on the development of accurate sensors for training that incorporate visual and motion metrics. These will be incorporated into augmented reality and visual reality environments that will provide training at home or the office on life-like simulators. Real-time feedback will be offered that stimulates and rewards performance. In discussing the scope, applications, limitations and barriers to adoption of these technologies, we aimed to stimulate discussion towards a framework for the optimal application of current and emerging technologies in regional anaesthesia.
AB - The current fourth industrial revolution is a distinct technological era characterised by the blurring of physics, computing and biology. The driver of change is data, powered by artificial intelligence. The UK National Health Service Topol Report embraced this digital revolution and emphasised the importance of artificial intelligence to the health service. Application of artificial intelligence within regional anaesthesia, however, remains limited. An example of the use of a convoluted neural network applied to visual detection of nerves on ultrasound images is described. New technologies that may impact on regional anaesthesia include robotics and artificial sensing. Robotics in anaesthesia falls into three categories. The first, used commonly, is pharmaceutical, typified by target-controlled anaesthesia using electroencephalography within a feedback loop. Other types include mechanical robots that provide precision and dexterity better than humans, and cognitive robots that act as decision support systems. It is likely that the latter technology will expand considerably over the next decades and provide an autopilot for anaesthesia. Technical robotics will focus on the development of accurate sensors for training that incorporate visual and motion metrics. These will be incorporated into augmented reality and visual reality environments that will provide training at home or the office on life-like simulators. Real-time feedback will be offered that stimulates and rewards performance. In discussing the scope, applications, limitations and barriers to adoption of these technologies, we aimed to stimulate discussion towards a framework for the optimal application of current and emerging technologies in regional anaesthesia.
KW - artificial intelligence
KW - regional anaesthesia
KW - robotics
KW - technology
KW - ultrasonography
UR - http://www.scopus.com/inward/record.url?scp=85099106444&partnerID=8YFLogxK
U2 - 10.1111/anae.15274
DO - 10.1111/anae.15274
M3 - Review article
C2 - 33426667
AN - SCOPUS:85099106444
SN - 0003-2409
VL - 76
SP - 171
EP - 181
JO - Anaesthesia
JF - Anaesthesia
IS - S1
ER -