Applicability of Clinical Decision Support in Management among Patients Undergoing Cardiac Surgery in Intensive Care Unit: A Systematic Review
Abstract
:1. Introduction
1.1. Background of Decision Support Systems
1.2. Objectives
2. Materials and Methods
2.1. Eligibility Criteria
2.2. Search Strategy
2.3. Study Selection
2.4. Data Extraction and Quality Assessment
2.5. Statistical Analysis
3. Results
3.1. Study Characteristics
3.2. Thematic Categories
3.2.1. Development Forecast
3.2.2. Medication Errors
3.2.3. Warning Systems: Early Detection and Early Action
3.2.4. Standardization and Compliance with Protocols
3.2.5. Precise Adjustment to Objectives
3.2.6. Cost Reduction
3.2.7. Acceptance
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Appendix A. Search Terms
Keywords | Mesh Terms |
Intensive Care Units | Intensive Care Units (Coronary Care Units; Intensive Care Units, Pediatric; Intensive Care Units, Neonatal) |
Critical Care | Critical Care (Early Goal-Directed Therapy; Intensive Care) |
Artificial Intelligence | Artificial intelligence (Computer Heuristics; Expert Systems; Fuzzy Logic; Knowledge Bases; Machine Learning) |
Big Data | Big Data |
Electronic Medical Records | Electronic Health Records (Health Information Exchange) |
Clinical Decision Support Systems | Decision Support Systems, Clinical |
Computerized Physician Order Entry | Medical Order Entry Systems |
Database | Database Management Systems |
Cardiogenic Shock | Shock, Cardiogenic |
Post-Cardiac | Post-Cardiac Arrest Syndrome |
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Reference | Country | Sample | Event Identified | Associated to | Description | |||||
---|---|---|---|---|---|---|---|---|---|---|
Type | Number | CDSS | CPOE | Database | EHR | Purpose of the Study | Main Findings | |||
Armada et al., 2014 [69] | Spain | Adult patients | 137 | Cardiogenic shock, acute coronary syndrome, and malignant arrhythmias | x | This study analyzed the effects of the Computerized Physician Order Entry (CPOE) system in cardiac patients by detecting medication errors and evaluating the use of electronic prescription by health professionals. | The results concluded that CPOE was safe in practice and was well received by health professionals, and its use reduced errors in the prescription. | |||
Aushev et al., 2018 [65] | USA | Adult patients | 75 | Cardiogenic shock and septic shock | x | The aim of the study was to identify clinical features that can predict mortality associated with cardiogenic or septic shock. | This study determined that the application of different models for prediction can prognosticate the risk of death in the acute phase of cardiogenic and septic shock. | |||
Banner et al., 2008 [51] | USA | Adult patients | 87 | Respiratory failure | x | This study aimed to validate the advisory system recommendation, compared to the experienced physician’s decision. | The results indicated that there were not significant differences in either system. The advisory system was well evaluated due to its forecasts in settings of pressure support ventilation (PSV). | |||
Campion et al., 2011 [52] | USA | Adult patients | 179,452 | Emergency general surgery, vascular surgery, and cardiac/thoracic surgery | x | The objective of this study was to determine the effects and conditions resulting from nurses’ override of clinical decision support system (CDSS) recommendations in ICUs. | The study concluded that the nurses accepted among 95% of dosing recommendations. The evaluation of the frequency, direction, and resistance of the intensive insulin therapy (IIT) of the CDSS overrides may be interesting for the health professionals and researchers. | |||
Denaï et al., 2009 [53] | United Kingdom | Adult patients | 7 | Impaired cardiac function | x | The aim of the study was to develop a CDSS for clinicians’ decision making in post-cardiac surgery patients weaned from cardiopulmonary bypass. | The study showed good feasibility for applying CDSS to control the cardiovascular system in post-surgery patient. | |||
Gouyon et al., 2017 [70] | France | Pediatric patients | 760 | Lower gestational age | x | x | This project evaluated the performance of the CDSS/CPOE combination, using the out-of-range dose rate. | The conclusion was that the CDSS/CPOE system was feasible for the prescription of all drugs in ICUs. This system allows for the evaluation and comparison of drugs. | ||
Hsu et al., 2013 [54] | Japan | Adult patients | 380 | Respiratory failure | x | The objective was to verify the effectiveness of a CDSS to predict and reduce the use of ventilator weaning. | This CDSS was effective in the identification of the earliest time of ventilator weaning for a patient to resume and sustain spontaneous breathing. | |||
Jalali et al., 2016 [55] | USA | Adult patients | 4000 | Cardiac surgery and infections | x | The study’s purpose was to develop a CDSS algorithm for predicting the prognostic of patients in ICUs. | The conclusions demonstrated that CDSSs can resolve complex situations in ICUs. | |||
Jalali et al., 2018 [56] | USA | Pediatric patients | 71 | Periventricular leukomalacia | x | The aim was to design a classifier adaptable to the patient and incorporated into the experts’ opinion in the classification process. | This project collected data from a highly reliable digital instrument with greater frequency, expanding the set of features, pre-classifying patients according to the diagnosis. | |||
Johnson et al., 2016 [66] | USA | Adult patients | 38597 | Coronary disease, cardiac surgery, trauma, and surgical procedure | x | This study wanted to determine the accessibility of the Medical Information Mart for Intensive Care III (MIMIC-III) database for the scientific community. | The study concluded that the MIMIC-III database allowed access to ICU data at an international level, improving the quality of academic and industrial research. | |||
Kallet et al., 2007 [57] | Canada | Adult patients | NA | Pulmonary and cardiac surgery | x | This paper reviewed the use of the National Institutes of Health acute respiratory distress syndrome (ARDS) network positive end-expiratory pressure (PEEP)/ inspired oxygen fraction (FIO2) titration tables to the treatment of patients with ARDS. | The study determined that the PEEP/FIO2 tables were a good option for the treatment of ARDS. | |||
May et al., 2014 [58] | USA | Adult patients | 114 | Cardiac surgery | x | This project’s purpose was to determine if CDSSs will facilitate better compliance with project measures and improve healthcare. | Through CDSSs, compliance with national surgical quality was improved. | |||
Rojas et al., 2018 [68] | USA | Adult patients | 24885 | Medical, surgical, and coronary care | x | The aim was to use an automatic learning technique to derive an ICU readmission model with electronic medical record variables in real time. | The study developed and validated readmission prediction modeling of ICUs through a novel machine modeling technique. | |||
Ross et al., 2009 [59] | United Kingdom | Adult patients | 3 | Cardiac surgery | x | The study determined whether the CDSS process provides clinical decision-making advice to anesthesiologists. | CDSSs developed proposed real-time diagnostic and therapeutic advice based on the continuous monitoring of cardiovascular hemodynamic patients. | |||
Saeed et al., 2011 [67] | USA | Adult patients | 22,870 | Cardiac diseases and coronary problems | x | The study’s purpose was to develop an ICU research database through automated techniques to aggregate high-resolution diagnostic and therapeutic data in ICU adult patients. | The study concluded that the MIMIC-II database is a resource that supports decision making. | |||
Sintchenko et al., 2006 [60] | Australia | Specialists Intensive Care | 31 | None | x | The aim was to examine the impact of CDSSs for ICU antibiotic prescribing. | The study concluded that CDSSs are an important factor in the process of complex decisions; it supported decision making and the functionality of different tasks. | |||
Sondergaard et al., 2012 [61] | Sweden | Adult patients | 24 | Pancreatic cancer, heart transplants, and intestinal carcinoid diseases | x | The study’s purpose was to research the performance of CDSSs in achieving some parameters in patients with major abdominal surgery. | The results demonstrated that there was a concordance between the recommend treatments of CDSSs and the treatments of anesthetists. | |||
Thompson et al., 2008 [62] | USA | All adult and pediatric patients | 148 | Pulmonary, neurological, cardiovascular, gastrointestinal, and multisystem diseases | x | The aim was to determine the effectiveness, satisfaction, and acceptance of eProtocol-insulin in ICUs. | eProtocol-insulin was generally accepted in ICUs. This study demonstrated that it can be a decision-support tool and a method for use in practices and clinical research. | |||
Vardi et al., 2007 [71] | Israel | Pediatric patients | 105 | Congenital heart diseases, metabolic diseases, multiple traumas, head traumas, respiratory diseases, and sepsis | x | x | The objective was to determine the impact of CDSS/CPOE in the preventions of medical errors in medication resuscitation orders. | The project considered that this warning system is a support tool in drug treatment, leading to medical error reductions. | ||
Warrick et al., 2011 [63] | United Kingdom | Pediatric patients | NA | None | x | The study wanted to determine the effect of electronic prescribing (EP) on prescribing errors and doses in pediatric ICUs. | The study determined that EP increases medication safety in pediatric ICUs. | |||
Wulff et al., 2018 [72] | Germany | Pediatric patients | 16 | None | x | x | The aim was to develop and evaluate an open electronic health record (EHR) for systemic inflammatory response syndrome (SIRS) detection in pediatric ICUs. | The study found that the inclusion of an open EHR in a CDSS can bridge the interoperability gap between local infrastructure in said CDSS. | ||
Zaslansky et al., 2014 [64] | Germany | Adults patients | 40,898 | Pain | x | The aim was to develop and validate a medical registry to measure and identify some aspects regarding pain. | This pain-related CDSS provides health professionals with easy access to data on the clinical management of pain, supporting the decision-making process. |
Patient | Application Area |
---|---|
Before admission | Forecast and evolutionary prediction |
During admission | Reduction in medical errors |
Alerts, fast detection of alterations, and treatment settings | |
Achievement of objectives and maintenance in established ranges | |
After admission | Reduction in health costs |
Level of satisfaction in health personnel |
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Pereira, M.; Concheiro-Moscoso, P.; López-Álvarez, A.; Baños, G.; Pazos, A.; Pereira, J. Applicability of Clinical Decision Support in Management among Patients Undergoing Cardiac Surgery in Intensive Care Unit: A Systematic Review. Appl. Sci. 2021, 11, 2880. https://doi.org/10.3390/app11062880
Pereira M, Concheiro-Moscoso P, López-Álvarez A, Baños G, Pazos A, Pereira J. Applicability of Clinical Decision Support in Management among Patients Undergoing Cardiac Surgery in Intensive Care Unit: A Systematic Review. Applied Sciences. 2021; 11(6):2880. https://doi.org/10.3390/app11062880
Chicago/Turabian StylePereira, Miguel, Patricia Concheiro-Moscoso, Alexo López-Álvarez, Gerardo Baños, Alejandro Pazos, and Javier Pereira. 2021. "Applicability of Clinical Decision Support in Management among Patients Undergoing Cardiac Surgery in Intensive Care Unit: A Systematic Review" Applied Sciences 11, no. 6: 2880. https://doi.org/10.3390/app11062880
APA StylePereira, M., Concheiro-Moscoso, P., López-Álvarez, A., Baños, G., Pazos, A., & Pereira, J. (2021). Applicability of Clinical Decision Support in Management among Patients Undergoing Cardiac Surgery in Intensive Care Unit: A Systematic Review. Applied Sciences, 11(6), 2880. https://doi.org/10.3390/app11062880