Toward mitigating pressure injuries: Detecting patient orientation from vertical bed reaction forces

Wong, Gordon; Gabison, Sharon; Dolatabadi, Elham; Evans, Gary W.; Kajaks, Tara; Holliday, Pamela J.; Alshaer, Hisham; Fernie, Geoff; Dutta, Tilak

doi:10.1177/2055668320912168

Cited by 8 publications

(16 citation statements)

References 28 publications

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“…The instrumentation was set up in a similar manner to Wong et al (12). Data was collected in CareLab, a simulated patient care environment located within Toronto Rehabilitation Institute (TRI), using a Carroll hospital bed (Carroll Hospital Group, Kalamazoo, MI).…”

Section: Methodsmentioning

confidence: 99%

“…The proof-of-concept work was able to detect healthy participant position (supine, left-side, or right-side) with 94.2% accuracy (n=20). When Wong et al’s (12) model was tested on the data collected from nine older adults sleeping in their own beds at home, the accuracy dropped to ∼88.5%. The drop in accuracy was suspected to be due to the large variations of sleeping positions that can be adopted.…”

Section: Introductionmentioning

confidence: 99%

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Detecting Patient Position Using Bed-Reaction Forces and Monitoring Skin-Bed Interface Forces for Pressure Injury Prevention and Management

Pupic

Gabison

Evans

et al. 2022

Preprint

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Pressure injuries are largely preventable, yet they affect one in four Canadians across all healthcare settings. A key best practice to prevent and treat pressure injuries is to minimize prolonged tissue deformation by ensuring at-risk individuals are repositioned regularly (typically every 2 hours). However, adherence to repositioning is poor in clinical settings and expected to be even worse in homecare settings. Our team has designed a position detection system for home use that uses machine learning approaches to predict a patient's position in bed using data from load cells under the bed legs. The system predicts the patient's position as one of three position categories: left-side lying, right-side lying, or supine. The objectives of this project were to: i) determine if measuring ground truth patient position with an inertial measurement unit can improve our system accuracy (predicting left-side lying, right-side lying, or supine) ii) to determine the range of transverse pelvis angles (TPA) that fully offloaded each of the great trochanters and sacrum and iii) evaluate the potential benefit of being able to predict the individual's position with higher precision (classifying position into more than three categories) by taking into account a potential drop in prediction accuracy as well as the range of TPA for which the greater trochanters and sacrum were fully offloaded. Data from 18 participants was combined with previous data sets to train and evaluate classifiers to predict the participants' TPA using four different position bin sizes (~70°), 45°, ~30°, and 15°) and the effects of increasing precision on performance, where patients are left side-lying at -90°, right side-lying at 90° and supine at 0°). A leave-one-participant-out cross validation approach was used to select the best performing classifier, which was found to have an accuracy of 84.03% with an F1 score of 0.8399. Skin-bed interface forces were measured using force sensitive resistors placed on the greater trochanters and sacrum. Complete offloading for the sacrum was only achieved for the positions with TPA angles <-90° or >90°, indicating there was no benefit to predicting with greater precision than with three categories: left, right, and supine.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Detecting Patient Position Using Bed-Reaction Forces and Monitoring Skin-Bed Interface Forces for Pressure Injury Prevention and Management

Pupic

Gabison

Evans

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

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“…The filtfilt function was used to bandpass filter the sum of the LH and RH signals ensuring a zero-phase shift. Our data was processed similar to Wong et al [18]. Each data point used for training/testing our machine learning classifiers was the average of a 45 s moving window that contained 2250 observations, where a new value was computed by shifting the window by 15 s. Ground Truth Participant Position Labels -Three members of the research team independently reviewed the time-lapse images for each data point and assigned a label indicating the participant was in one of three positions: right-side-lying, left-side-lying, or supine for each 45 s. The most common label from the three reviewers was selected as the final ground truth label.…”

Section: Data Processingmentioning

confidence: 99%

“…This validation approach was selected to maximize the number of training observations that were used for each classifier. Incremental Learning -An incremental learning approach was used to evaluate the ability of the classifier to adapt to the data from the left-out participant in a similar manner as described in Wong et al [18]. The machine learning classifier was iteratively trained using different percentages of the left-out participant's data (c, with c = 0%, 10%, 20%, or 30%).…”

Section: Data Analysesmentioning

confidence: 99%

“…Sensors collect force data and features are extracted from the data. Using advanced machine learning algorithms, we have been able to predict an individual’s position in bed as either supine, right-side-lying or left-side-lying with 94.2% accuracy in an controlled laboratory environment [18]. Our ultimate goal is to build on this position detection system to develop a repositioning prompting system that will continuously monitor an patient’s position in bed and alert a caregiver when the patient has remained in the same position for too long (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Measuring Repositioning in Home Care for Pressure Injury Prevention and Management

Gabison

Pupic

Evans

et al. 2022

Preprint

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A critical best practice for prevention and management of pressure injuries is regularly repositioning individuals who are at risk of these injuries are when they are in bed. However, despite the widespread agreement of the need for regular repositioning (typically every two hours), adherence to repositioning schedules remains poor in the clinical environment and there are some indications that the situation in home environment is even worse.Our team has recently developed a non-contact system that can continuously determine an individual’s position in bed (left-side lying, right-side lying or supine) using data from a set of inexpensive load cells placed under the bed frame. A proof of principle study showed that our system was able to detect whether healthy participants were supine, left-side lying or right-side lying with 94.2% accuracy in the lab environment.The objective of the present work was to deploy our system into the home environment to evaluate how well the system was able to detect the position of individuals sleeping in their own beds overnight by comparing to ground truth time-lapse camera images using eight machine learning classifiers. Nine participants were recruited for this study and we found our system was able to detect an individual’s position in bed with 98.1% accuracy and an F1 score of 0.982 using the XGBoost classifier.Future work will include using this system to evaluate interventions focused on improving adherence to 2-hour repositioning schedules for pressure injury prevention or management as well as incorporating this technology in a repositioning prompting system to alert caregiver when a patient has remained in the same position for too long.

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Application of Machine Learning Algorithms to Diagnosis and Prognosis of Chronic Wounds

Dabas,

Gefen

2024

Big Data Analysis and Artificial Intelligence for Medical Sciences

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Toward mitigating pressure injuries: Detecting patient orientation from vertical bed reaction forces

Cited by 8 publications

References 28 publications

Detecting Patient Position Using Bed-Reaction Forces and Monitoring Skin-Bed Interface Forces for Pressure Injury Prevention and Management

Detecting Patient Position Using Bed-Reaction Forces and Monitoring Skin-Bed Interface Forces for Pressure Injury Prevention and Management

Measuring Repositioning in Home Care for Pressure Injury Prevention and Management

Application of Machine Learning Algorithms to Diagnosis and Prognosis of Chronic Wounds

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