ABSTRACT
BACKGROUND: Patients in acute care wards who deteriorate and are emergently transferred to intensive care units (ICUs) have poor outcomes. Early identification of patients who are decompensating might allow for earlier clinical intervention and reduced morbidity and mortality. Advances in bedside continuous predictive analytics monitoring (ie, artificial intelligence [AI]-based risk prediction) have made complex data easily available to health care providers and have provided early warning of potentially catastrophic clinical events. We present a dynamic, visual, predictive analytics monitoring tool that integrates real-time bedside telemetric physiologic data into robust clinical models to estimate and communicate risk of imminent events. This tool, Continuous Monitoring of Event Trajectories (CoMET), has been shown in retrospective observational studies to predict clinical decompensation on the acute care ward. There is a need to more definitively study this advanced predictive analytics or AI monitoring system in a prospective, randomized controlled, clinical trial. OBJECTIVE: The goal of this trial is to determine the impact of an AI-based visual risk analytic, CoMET, on improving patient outcomes related to clinical deterioration, response time to proactive clinical action, and costs to the health care system. METHODS: We propose a cluster randomized controlled trial to test the impact of using the CoMET display in an acute care cardiology and cardiothoracic surgery hospital floor. The number of admissions to a room undergoing cluster randomization was estimated to be 10,424 over the 20-month study period. Cluster randomization based on bed number will occur every 2 months. The intervention cluster will have the CoMET score displayed (along with standard of care), while the usual care group will receive standard of care only. RESULTS: The primary outcome will be hours free from events of clinical deterioration. Hours of acute clinical events are defined as time when one or more of the following occur: emergent ICU transfer, emergent surgery prior to ICU transfer, cardiac arrest prior to ICU transfer, emergent intubation, or death. The clinical trial began randomization in January 2021. CONCLUSIONS: Very few AI-based health analytics have been translated from algorithm to real-world use. This study will use robust, prospective, randomized controlled, clinical trial methodology to assess the effectiveness of an advanced AI predictive analytics monitoring system in incorporating real-time telemetric data for identifying clinical deterioration on acute care wards. This analysis will strengthen the ability of health care organizations to evolve as learning health systems, in which bioinformatics data are applied to improve patient outcomes by incorporating AI into knowledge tools that are successfully integrated into clinical practice by health care providers. TRIAL REGISTRATION: ClinicalTrials.gov NCT04359641; https://clinicaltrials.gov/ct2/show/NCT04359641. INTERNATIONAL REGISTERED REPORT IDENTIFIER (IRRID): DERR1-10.2196/29631.
ABSTRACT
PURPOSE: Describe patient-, clinician-, system-, and community-level interventions for pain management developed and employed by 9 healthcare systems across the United States and report on lessons learned from the implementation of these interventions. SUMMARY: The high cost associated with pain coupled with the frequent use of opioid analgesics as primary treatment options has made novel pain management strategies a necessity. Interventions that target multiple levels within healthcare are needed to help combat the opioid epidemic and improve strategies to manage chronic pain. Patient-level interventions implemented ranged from traditional paper-based educational tools to videos, digital applications, and peer networks. Clinician-level interventions focused on providing education, ensuring proper follow-up care, and establishing multidisciplinary teams that included prescribers, pharmacists, nurses, and other healthcare professionals. System- and community-level interventions included metric tracking and analytics, electronic health record tools, lockbox distribution for safe storage, medication return bins for removal of opioids, risk assessment tool utilization, and improved access to reversal agents. CONCLUSION: Strategies to better manage pain can be implemented within health systems at multiple levels and on many fronts; however, these changes are most effective when accepted and widely used by the population for which they are targeted.
