FALLS IN OLDER ADULTS

There is a lack of objective evidence on "how" and "why" falls occur in older adults, and this is a barrier to fall prevention.

This project involves the collection and analysis of video footage of real-life falls experienced by older adults residing in two partnering long-term care homes in the Vancouver area. The videos are analyzed with structured questionnaires and by digitizing the time-varying movements of the body. Specific areas of focus include the causes of imbalance and activities leading to the fall, and the factors that influence risk for injury during falls.

Key publications:
Komisar V, Dojnov A, Yang Y, Shishov N, Chong H, Yu Y, Bercovitz I, Cusimano MD, Becker C, Mackey DC & Robinovitch SN. Injuries from falls by older adults in long-term care captured on video: Prevalence of impacts and injuries to body parts. BMC Geriatr, 22, 343, 2022.

Shishov N, Elabd K, Komisar V, Chong H & Robinovitch SN. Accuracy of Kinovea software in estimating body segment movements during falls captured on standard video: Effects of fall direction, camera perspective and video calibration technique. PLoS One, 16, e0258923, 2021.

Komisar V & Robinovitch SN. The Role of Fall Biomechanics in the Cause and Prevention of Bone Fractures in Older Adults. Curr Osteoporos Rep, 19, 381-390, 2021.

Yang Y, Komisar V, Shishov N, Lo B, Korall AM, Feldman F & Robinovitch SN. The Effect of Fall Biomechanics on Risk for Hip Fracture in Older Adults: A Cohort Study of Video-Captured Falls in Long-Term Care. J Bone Miner Res, 35, 1914-1922, 2020.

Kuo C, Shishov N, Elabd K, Komisar V, Chong H, Phu T, Anderson L, Hoshizaki B, Laing A, Cripton P & Robinovitch S. Estimating Trunk and Neck Stabilization for Avoiding Head Impact during Real-World Falls in Older Adults. Annu Int Conf IEEE Eng Med Biol Soc, 2020, 4823-4826, 2020.

Yang Y, van Schooten KS, Sims-Gould J, McKay HA, Feldman F & Robinovitch SN. Sex Differences in the Circumstances Leading to Falls: Evidence From Real-Life Falls Captured on Video in Long-Term Care. J Am Med Dir Assoc, 19, 130-135 e1, 2018.

Woolrych R, Zecevic A, Sixsmith A, Sims-Gould J, Feldman F, Chaudhury H, Symes B & Robinovitch SN. Using video capture to investigate the causes of falls in long-term care. Gerontologist, 55, 483-94, 2015.

Robinovitch SN, Feldman F, Yang Y, Schonnop R, Leung PM, Sarraf T, Sims-Gould J & Loughin M. Video capture of the circumstances of falls in elderly people residing in long-term care: an observational study. Lancet, 381, 47-54, 2013.

Yang Y, Schonnop R, Feldman F & Robinovitch SN. Development and validation of a questionnaire for analyzing real-life falls in long-term care captured on video. BMC Geriatr, 13, 40, 2013.

Schonnop R, Yang Y, Feldman F, Robinson E, Loughin M & Robinovitch SN. Prevalence of and factors associated with head impact during falls in older adults in long-term care. CMAJ, 185, E803-10, 2013.

"Hip protectors" are a type of protective clothing designed to cushion a fall and prevent hip fracture. Our research examines the biomechanical and clinical value of hip protectors, and barriers and facilitators to use of hip protectors. 

To improve the performance and market regulation of hip protectors, we worked with the Canadian Standards Association (CSA) in a multi-disciplinary committee to develop a standard (CSA Z325:20) for biomechanical testing of hip protectors. The standard guides users in the selection of hip protectors, and industry in the design, evaluation and marketing of hip protectors. 

In the area of user acceptance, we worked with partners in the Fraser Health region of British Columbia to show that a hip protector implementation strategy resulted in 60% of residents of 14 long-term homes care wearing hip protectors on a regular basis. In additional studies, we showed that individuals who wore hip protectors had a 3-fold lower risk for hip fracture in the event of a fall. Building on this success, we are working to develop implementation strategies to increase the use of hip protectors in Ontario. In additional studies, we are designing and testing unobtrusive head gear (e.g., padded hats and wigs) for protecting the brain during falls that result in head impact.

Key publications:
Hip Protectors. CSA Z325:20. CSA Group; 2020. https://www.csagroup.org/store/product/2427790/

Korall AMB, Feldman F, Yang Y, Cameron ID, Leung PM, Sims-Gould J & Robinovitch SN. Effectiveness of Hip Protectors to Reduce Risk for Hip Fracture from Falls in Long-Term Care. J Am Med Dir Assoc, 20, 1397-1403 e1, 2019.

Korall AMB, Loughin TM, Feldman F, Cameron ID, Leung PM, Sims-Gould J, Godin J & Robinovitch SN. Determinants of staff commitment to hip protectors in long-term care: A cross-sectional survey. Int J Nurs Stud, 82, 139-148, 2018.

Korall AMB, Godin J, Feldman F, Cameron ID, Leung PM, Sims-Gould J & Robinovitch SN. Validation and psychometric properties of the commitment to hip protectors (C-HiP) index in long-term care providers of British Columbia, Canada: a cross-sectional survey. BMC Geriatr, 17, 103, 2017.

Sims-Gould J, McKay HA, Feldman F, Scott V & Robinovitch SN. Autonomy, choice, patient-centered care, and hip protectors: the experience of residents and staff in long-term care. J Appl Gerontol, 33, 690-709, 2014.

Safe movement environments can promote mobility and prevent injuries from falls. An obvious strategy for high-risk environments, such as long-term care and hospitals, is to reduce the stiffness of the floor. But how much reduction in stiffness is required to prevent injuries? 

Through a 4-year prospective randomized study, we examined how falls and injuries were affected by the installation of a specific type of compliant flooring. We found that falls were not increased by compliant flooring. However, there was no difference in the risk for injury when falling on compliant flooring versus control (rigid) flooring. The reasons may relate to the high use of hip protectors in the long-term care site that we studied, or the need for compliant flooring to be even softer in order to prevent injuries.   

Key publications:
Mackey DC, Lachance CC, Wang PT, Feldman F, Laing AC, Leung PM, Hu XJ & Robinovitch SN. The Flooring for Injury Prevention (FLIP) Study of compliant flooring for the prevention of fall-related injuries in long-term care: A randomized trial. PLoS Med, 16, e1002843, 2019.

Lachance CC, Korall AMB, Russell CM, Feldman F, Robinovitch SN & Mackey DC. Hand forces exerted by long-term care staff when pushing wheelchairs on compliant and non-compliant flooring. Appl Ergon, 71, 95-101, 2018.

Lachance CC, Jurkowski MP, Dymarz AC, Robinovitch SN, Feldman F, Laing AC & Mackey DC. Compliant flooring to prevent fall-related injuries in older adults: A scoping review of biomechanical efficacy, clinical effectiveness, cost-effectiveness, and workplace safety. PLoS One, 12, e0171652, 2017.

Unobtrusive wearable sensors have the potential to detect falls for care delivery, and provide valuable information on the cause of falls. 

We have combined miniature sensors with custom-designed data analysis algorithms to create wearable fall recorders that can accurately detect falls, and record key characteristics associated with the initiation, descent, and impact stages of falls. We found that the accuracy of the system in detecting and classifying the fall depends on the number and location of sensors. Furthermore, machine learning algorithms (or hybrid approaches) provide better accuracy that threshold-based strategies for detecting and classifying falls.

Key publications:
Ejupi A, Galang C, Aziz O, Park EJ & Robinovitch S. Accuracy of a wavelet-based fall detection approach using an accelerometer and a barometric pressure sensor. Annu Int Conf IEEE Eng Med Biol Soc, 2017, 2150-2153, 2017.

Aziz O, Robinovitch SN & Park EJ. Identifying the number and location of body worn sensors to accurately classify walking, transferring and sedentary activities. Annu Int Conf IEEE Eng Med Biol Soc, 2016, 5003-5006, 2016.

Aziz O, Russell CM, Park EJ & Robinovitch SN. The effect of window size and lead time on pre-impact fall detection accuracy using support vector machine analysis of waist mounted inertial sensor data. Annu Int Conf IEEE Eng Med Biol Soc, 2014, 30-3, 2014.

Klenk J, Chiari L, Helbostad JL, Zijlstra W, Aminian K, Todd C, Bandinelli S, Kerse N, Schwickert L, Mellone S, Bagala F, Delbaere K, Hauer K, Redmond SJ, Robinovitch S, Aziz O, Schwenk M, Zecevic A, Zieschang T, Becker C, Consortium F & the FM-DCG. Development of a standard fall data format for signals from body-worn sensors : the FARSEEING consensus. Z Gerontol Geriatr, 46, 720-6, 2013.

Lee JK, Park EJ & Robinovitch SN. Estimation of Attitude and External Acceleration Using Inertial Sensor Measurement During Various Dynamic Conditions. IEEE Trans Instrum Meas, 61, 2262-2273, 2012.

Aziz O & Robinovitch SN. An analysis of the accuracy of wearable sensors for classifying the causes of falls in humans. IEEE Trans Neural Syst Rehabil Eng, 19, 670-6, 2011.