Monitoring surgical nociception using multisensor physiological models
成果类型:
Article
署名作者:
Subramanian, Sandya; Tseng, Bryan; del Carmen, Marcela; Goodman, Annekathryn; Dahl, Douglas M.; Barbieri, Riccardo; Brown, Emery N.
署名单位:
Harvard University; Massachusetts Institute of Technology (MIT); Broad Institute; Massachusetts Institute of Technology (MIT); Harvard University; Harvard University Medical Affiliates; Massachusetts General Hospital; Polytechnic University of Milan
刊物名称:
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
ISSN/ISSBN:
0027-10205
DOI:
10.1073/pnas.2319316121
发表日期:
2024-10-01
关键词:
skin-conductance
postoperative pain
general-anesthesia
assess emergence
stress index
remifentanil
analgesia
propofol
stimulation
sevoflurane
摘要:
Monitoring nociception, the flow of information associated with harmful stimuli through the nervous system even during unconsciousness, is critical for proper anesthesia care during surgery. Currently, this is done by tracking heart rate and blood pressure by eye. Monitoring objectively a patient's nociceptive state remains a challenge, causing drugs to often be over- or underdosed intraoperatively. Inefficient management of surgical nociception may lead to more complex postoperative pain management and side effects such as postoperative cognitive dysfunction, particularly in elderly patients. We collected a comprehensive and multisensor prospective observational dataset focused on surgical nociception (101 surgeries, 18,582 min, and 49,878 nociceptive stimuli), including annotations of all nociceptive stimuli occurring during surgery and medications administered. Using this dataset, we developed indices of autonomic nervous system activity based on physiologically and statistically rigorous point process representations of cardiac action potentials and sweat gland activity. Next, we constructed highly interpretable supervised and unsupervised models with appropriate inductive biases that quantify surgical nociception throughout surgery. Our models track nociceptive stimuli more accurately than existing nociception monitors. We also demonstrate that the characterizing signature of nociception learned by our models resembles the known physiology of the response to pain. Our work represents an important step toward objective multisensor physiology- based markers of surgical nociception. These markers are derived from an in- depth characterization of nociception as measured during surgery itself rather than using other experimental models as surrogates for surgical nociception.