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جعفری, یاسمن, شیرزاد عراقی, الهام. (1404). پیش بینی سقوط سالمندان با استفاده از تک حسگر اینرسی در حین راه رفتن : یک مرور روایتی. , 1(3), 1-12. doi: 10.22059/jhae.2025.408090.1023
یاسمن جعفری; الهام شیرزاد عراقی. "پیش بینی سقوط سالمندان با استفاده از تک حسگر اینرسی در حین راه رفتن : یک مرور روایتی". , 1, 3, 1404, 1-12. doi: 10.22059/jhae.2025.408090.1023
جعفری, یاسمن, شیرزاد عراقی, الهام. (1404). 'پیش بینی سقوط سالمندان با استفاده از تک حسگر اینرسی در حین راه رفتن : یک مرور روایتی', , 1(3), pp. 1-12. doi: 10.22059/jhae.2025.408090.1023
جعفری, یاسمن, شیرزاد عراقی, الهام. پیش بینی سقوط سالمندان با استفاده از تک حسگر اینرسی در حین راه رفتن : یک مرور روایتی. , 1404; 1(3): 1-12. doi: 10.22059/jhae.2025.408090.1023

پیش بینی سقوط سالمندان با استفاده از تک حسگر اینرسی در حین راه رفتن : یک مرور روایتی

سالمندی سالم و ورزش
مقاله 1، دوره 1، شماره 3، آذر 1404، صفحه 1-12    اصل مقاله (589.42 K)
نوع مقاله: مطالعات مروری
شناسه دیجیتال (DOI): 10.22059/jhae.2025.408090.1023
نویسندگان
یاسمن جعفری1؛ الهام شیرزاد عراقی* 2
1گروه بیومکانیک، دانشکده مهندسی پزشکی، دانشگاه صنعتی امیرکبیر، تهران، ایران.
2گروه طب ورزشی و فناوری های نوین، دانشکده علوم ورزشی و تندرستی، دانشگاه تهران، تهران، ایران.
چکیده
مقدمه: سقوط در سالمندان چالش اصلی بهداشت عمومی است که منجر به آسیب‌های شدید و کاهش استقلال می‌شود. فناوری‌های پوشیدنی، به‌ویژه حسگرهای اینرسی ، ارزیابی دقیق خطر سقوط را فراهم می‌کنند. این مرور روایتی به بررسی کاربرد حسگرهای اینرسی در پیش‌بینی سقوط سالمندان می‌پردازد و شواهد مرتبط را تحلیل می‌کند.
روش پژوهش: یک مرور روایتی بر اساس جستجوی ساختارمند در پایگاه‌های اسکوپوس و Web of Science(۲۰۱۵-۲۰۲۵) انجام شد. معیارهای ورود شامل مطالعات پژوهشی با استفاده از حسگر اینرسی در سالمندان (۶۰ سال به بالا) بود. تعداد ۱۲ مطالعه نهایی تجزیه‌وتحلیل شد. داده‌ها با استفاده از فرم استاندارد شامل ویژگی‌های مطالعه، جمعیت‌شناسی، مشخصات حسگر، پروتکل‌های ارزیابی، و متغیرهای استخراج‌شده استخراج شد.
یافته ­ها: حسگرهای اینرسی محل‌شده در مناطق مرکزی بدن (مهره‌های پایین کمر) دقت ۷۶ تا ۸۹.۴% را در تمایز سقوط‌کنندگان از غیرسقوط‌کنندگان ارائه دادند. تست برخاستن و رفتن و محدودیت‌های پایداری هنگام‌ترکیب با شاخص‌های خطی و غیرخطی تمایز بهتری ایجاد کردند. مطالعات آینده‌نگر (دقت 6/81 درصد) برتری بالینی بیشتری نسبت به اعتبارسنجی متقابل داخلی (دقت 4/89 %) داشتند. نظارت در محیط واقعی اعتبار اکولوژیک بیشتری فراهم کرد.
نتیجه­ گیری: حسگرهای اینرسی با قرارگیری مناسب و استفاده از شاخص‌های ترکیبی، ابزارهای مؤثری برای ارزیابی خطر سقوط هستند. محدودیت‌های اصلی شامل حجم نمونه کم و عدم استانداردسازی است. راهکارهای آینده شامل ایجاد پایگاه داده عمومی، ترکیب حسگرهای متنوع، و توسعه الگوریتم‌های بهتر است.
کلیدواژه‌ها
حسگر اینرسی؛ ارزیابی ریسک سقوط؛ سالمندی؛ یادگیری ماشین؛ آنالیز راه رفتن
اصل مقاله

Introduction

Falls in the elderly population represent a critical public health challenge with severe consequences including injuries, loss of independence, and increased mortality. Falls are the second leading cause of accidental deaths and affect approximately 40% of elderly individuals in daily activities. In Canada, falls are the primary cause of injury in older adults, with 33% of hospitalized cases transferred to long-term care facilities. Risk factors encompass intrinsic elements (physiological and psychological) and extrinsic factors (environmental).

Traditional assessment tools such as the Timed Up and Go (TUG) test and Berg Balance Scale provide qualitative fall risk evaluation, whereas wearable sensors offer quantitative assessment. Inertial measurement units (IMUs) provide precise measurement of movement pattern changes and body posture during walking. Research activity has increased substantially since 2013, with significant advances in machine learning applications. Bibliometric analysis identified 221 studies in this field from 2000–2024, with the Journal of Neurology and IEEE Transactions publishing the most articles.

Methods

This narrative review analyzed evidence regarding inertial sensor applications in elderly fall risk assessment. A narrative approach was selected due to the heterogeneous nature of research in this emerging technology field, enabling deep qualitative analysis of diverse methodologies.

Structured searches were conducted in Web of Science and Scopus using keywords: (wearable sensor OR inertial measurement unit OR IMU OR accelerometer) AND (fall risk OR fall prediction OR fall detection) AND elderly. Time frame: 2015–2025; English language. Inclusion criteria: cross-sectional, case-control, prospective cohort, validation, and algorithm development studies using IMUs in elderly (≥60 years) reporting fall-related outcomes. Exclusion criteria: review studies, conference abstracts, non-wearable sensors, populations <60 years, simulations, and animal studies. Twelve studies met criteria and underwent detailed analysis.

Data extraction included: study characteristics, demographics, sensor specifications (type, placement location, sampling frequency), assessment protocols, extracted variables (stride length, gait speed, Lyapunov exponent, entropy), analytical methods, and outcomes (prediction accuracy, sensitivity/specificity).

Results

Sensor Placement

IMUs positioned in core body regions, particularly lower lumbar vertebrae (3rd–5th), demonstrated optimal effectiveness. Wang et al. (2024) achieved 88% area under receiver operating characteristic curve, the best discrimination between high and low-risk groups. Buisseret et al. (2022) achieved 76% accuracy with 4th lumbar vertebral placement. This location's superiority stems from high sensitivity to trunk changes and body stability during position transitions. Liu (2012) achieved 86.7% sensitivity with sternum placement versus 73% for foot-based sensors (Neira, 2023), due to time-series analysis independent of step detection, eliminating errors in shuffling gait patterns common in elderly. However, Saadeh et al. achieved 98% prediction accuracy with thigh sensors but had limited generalizability due to small sample size (20 subjects) and lack of prospective validation.

Assessment Protocols

The TUG test was used in 7 of 12 studies and revealed specific deficits when instrument-augmented. Qiu et al. integrated three assessment domains (TUG, stability limits test, five-time sit-to-stand) achieving 89.4% accuracy using Support Vector Machine, substantially outperforming simpler approaches using only gait speed analysis (Bautmans: 2011 variance analysis only).

Diverse assessment methods showed significant differences. Lockhart's 10-meter walk test with prospective design (6-month follow-up) achieved 81.6% predictive accuracy with better generalizability than Neira's 15-minute free walking (73% accuracy, case-control). Real-world monitoring provided greater validity: van Schooten et al. (2015) conducted one-week ambulatory monitoring using logistic regression, while Handelzalts et al. (2020) identified 18 of 22 trip events (82%) in daily-life conditions. In contrast, Rivolta et al. (2019) achieved 89% laboratory accuracy with artificial neural networks but lacked real-world applicability.

Gait Parameters and Feature Extraction

Linear spatiotemporal gait parameters consistently discriminated fallers from non-fallers: gait speed in 9 of 12 studies, variability indices in 6 of 12, and step frequency in 7 of 12. Liu's combined approach using linear features (step timing) with nonlinear indices (multiscale entropy and recurrence quantification analysis) achieved 81.6% prospective accuracy, outperforming purely linear approaches (Bautmans, van Schooten). Nonlinear indices demonstrate superior sensitivity to subtle gait deterioration. Howcroft achieved 84% accuracy using maximum Lyapunov exponent in a neural network. Qiu achieved 89.4% using frequency-domain features in Support Vector Machine frameworks.

However, linear variability measures depend on accurate step detection and fail in shuffling gait patterns. Frequency-domain features are environment-sensitive, as Wang demonstrated with superior discrimination in stair descent versus level walking.

Algorithm Comparison

Ensemble tree methods (Random Forest) and margin-based methods (Support Vector Machine) provide optimal balance between accuracy and generalizability. Rivolta's neural network was trained on Tinetti scores, an imperfect criterion not fully reflecting real-world fall occurrence.

Prospective vs. Retrospective Validation

Prospective studies demonstrated superior clinical prediction validity. Liu's Random Forest algorithm with 6-month prospective follow-up achieved 81.6% accuracy and proved more clinically reliable than Qiu's Support Vector Machine (89.4%) based on internal cross-validation without external testing. Neira's Support Vector Machine using foot sensors (73% accuracy) was limited by retrospective case-control design, reducing predictive power for future falls. Real-world monitoring advantages are evident: Handelzalts' ecological validity (82% sensitivity) versus simplified laboratory environments demonstrates superior clinical utility, though with limitations such as missed events (4 of 22 self-reported trips undetected).

Conclusion

IMUs positioned optimally in core body regions, particularly lower lumbar spine (3rd–5th vertebrae), represent effective fall risk assessment tools achieving 76–89.4% accuracy. Combined TUG and stability limit tests with linear (speed, stride length, variability) and nonlinear indices (multiscale entropy, Lyapunov exponent) provide superior discrimination. Machine learning algorithms including Support Vector Machine and Random Forest demonstrate higher performance than decision trees. Prospective studies (Liu: 81.6% over 6 months) show superior validity compared to internal cross-validation (Qiu: 89.4%), while real-world monitoring provides greater ecological validity.

Primary limitations include small sample sizes causing model overfitting, lack of standardization regarding sensor placement and parameters, and poor data quality (mostly simulated laboratory falls). Future directions include: establishing public databases with standardized protocols, integrating diverse sensors for comprehensive monitoring, utilizing Internet of Things with personalized feedback, and developing advanced analytical methods (deep reinforcement learning, recurrent neural networks) for detecting dynamic fall risk patterns in real-world environments.

 

 

 

 

 

Footnotes

Authors’ contribution

Study concept and design: E. SH.; Analysis and interpretation of data: Y. D..; Drafting of the manuscript: Y. D..; Critical revision of the manuscript: E. SH.

Funding

Non.

Conflict of interest

According to the authors, this article has no conflict of interest.

 

مراجع

 

  1. Batumalai P, Thazhakkattu Vasu D, Selvakumar K, Choon Hian G. A bibliometric analysis of wearable sensors for fall-risk assessment in the elderly population. Medicine (Baltimore). 2025;104(35):e44118.10.1097/MD.0000000000044118
  2. Cui Y, Choi M, editors. Assessment of the daily living activities of older people (2004–2023): A bibliometric and visual analysis. Healthcare; 2024: MDPI;
  3. Shishov N, Komisar V, Marigold DS, Blouin JS, Robinovitch SN. Interactions during falls with environmental objects: evidence from real-life falls in long-term care captured on video. BMC Geriatr. 2024;24(1):726.10.1186/s12877-024-05306-5
  4. Majumder S, Mondal T, Deen MJ. Wearable Sensors for Remote Health Monitoring. Sensors (Basel). 2017;17(1):130.10.3390/s17010130
  5. Subramaniam S, Faisal AI, Deen MJ. Wearable Sensor Systems for Fall Risk Assessment: A Review. Front Digit Health. 2022;4:921506.10.3389/fdgth.2022.921506
  6. Marquez G, Veloz A, Minonzio JG, Reyes C, Calvo E, Taramasco C. Using Low-Resolution Non-Invasive Infrared Sensors to Classify Activities and Falls in Older Adults. Sensors (Basel). 2022;22(6):2321.10.3390/s22062321
  7. McCarthy M. Falls are leading cause of injury deaths among older people, US study finds. British Medical Journal Publishing Group; 20
  8. Perell KL, Nelson A, Goldman RL, Luther SL, Prieto-Lewis N, Rubenstein LZ. Fall risk assessment measures: an analytic review. J Gerontol A Biol Sci Med Sci. 2001;56(12):M761-6.10.1093/gerona/56.12.m761
  9. Shumway-Cook A, Baldwin M, Polissar NL, Gruber W. Predicting the probability for falls in community-dwelling older adults. Phys Ther. 1997;77(8):812-9.10.1093/ptj/77.8.812
  10. Muir SW, Berg K, Chesworth B, Speechley M. Use of the Berg Balance Scale for predicting multiple falls in community-dwelling elderly people: a prospective study. Phys Ther. 2008;88(4):449-59.10.2522/ptj.20070251
  11. Bohlke K, Redfern MS, Rosso AL, Sejdic E. Accelerometry applications and methods to assess standing balance in older adults and mobility-limited patient populations: a narrative review. Aging Clin Exp Res. 2023;35(10):1991-2007.10.1007/s40520-023-02503-x
  12. Najafi B, Aminian K, Loew F, Blanc Y, Robert PA. Measurement of stand-sit and sit-stand transitions using a miniature gyroscope and its application in fall risk evaluation in the elderly. IEEE Trans Biomed Eng. 2002;49(8):843-51.10.1109/TBME.2002.800763
  13. Howcroft J, Kofman J, Lemaire ED. Review of fall risk assessment in geriatric populations using inertial sensors. J Neuroeng Rehabil. 2013;10(1):91.10.1186/1743-0003-10-91
  14. Hsu Y-C, Zhao Y, Huang K-H, Wu Y-T, Cabrera J, Sun T-L, et al. A novel approach for fall risk prediction using the inertial sensor data from the timed-up-and-go test in a community setting. IEEE sensors journal. 2020;20(16):9339-50
  15. Seel T, Raisch J, Schauer T. IMU-based joint angle measurement for gait analysis. Sensors (Basel). 2014;14(4):6891-909.10.3390/s140406891
  16. Guimarães V, Ribeiro D, Rosado L, editors. A smartphone-based fall risk assessment tool: measuring one leg standing, sit to stand and falls efficacy scale. 2013 IEEE 15th International Conference on e-Health Networking, Applications and Services (Healthcom 2013); 2013: IEEE;
  17. Yu L, Zhao Y, Wang H, Sun TL, Murphy TE, Tsui KL. Assessing elderly's functional balance and mobility via analyzing data from waist-mounted tri-axial wearable accelerometers in timed up and go tests. BMC Med Inform Decis Mak. 2021;21(1):108.10.1186/s12911-021-01463-4
  18. van Schooten KS, Pijnappels M, Rispens SM, Elders PJ, Lips P, van Dieen JH. Ambulatory fall-risk assessment: amount and quality of daily-life gait predict falls in older adults. J Gerontol A Biol Sci Med Sci. 2015;70(5):608-15.10.1093/gerona/glu225
  19. Howcroft J, Lemaire ED, Kofman J. Wearable-Sensor-Based Classification Models of Faller Status in Older Adults. PLoS One. 2016;11(4):e0153240.10.1371/journal.pone.0153240
  20. Riva F, Toebes M, Pijnappels M, Stagni R, Van Dieën J. Estimating fall risk with inertial sensors using gait stability measures that do not require step detection. Gait & posture. 2013;38(2):170-4
  21. Iijima H, Takahashi M. State of the Field of waist-mounted sensor algorithm for gait events detection: A scoping review. Gait Posture. 2020;79:152-61.10.1016/j.gaitpost.2020.03.021
  22. Wang X, Cao J, Zhao Q, Chen M, Luo J, Wang H, et al. Identifying sensors-based parameters associated with fall risk in community-dwelling older adults: an investigation and interpretation of discriminatory parameters. BMC Geriatr. 2024;24(1):125.10.1186/s12877-024-04723-w
  23. Buisseret F, Catinus L, Grenard R, Jojczyk L, Fievez D, Barvaux V, et al. Timed up and go and six-minute walking tests with wearable inertial sensor: one step further for the prediction of the risk of fall in elderly nursing home people. Sensors. 2020;20(11):3207
  24. Liu J, Zhang X, Lockhart TE. Fall risk assessments based on postural and dynamic stability using inertial measurement unit. Saf Health Work. 2012;3(3):192-8.10.5491/SHAW.2012.3.3.192
  25. Rafanelli M, Walsh K, Hamdan MH, Buyan-Dent L. Autonomic dysfunction: Diagnosis and management. Handb Clin Neurol. 2019;167:123-37.10.1016/B978-0-12-804766-8.00008-X
  26. Neira‐Álvarez M, Jimenez-Ruiz AR, Neira-Garcia G, Huertas-Hoyas E, Espinoza-Cerda MT, Pérez-Delgado L, et al. Assessing falls in the elderly population using G-STRIDE foot-mounted inertial sensor. 2023
  27. Saadeh W, Butt SA, Altaf MAB. A Patient-Specific Single Sensor IoT-Based Wearable Fall Prediction and Detection System. IEEE Trans Neural Syst Rehabil Eng. 2019;27(5):995-1003.10.1109/TNSRE.2019.2911602
  28. Bautmans I, Jansen B, Van Keymolen B, Mets T. Reliability and clinical correlates of 3D-accelerometry based gait analysis outcomes according to age and fall-risk. Gait Posture. 2011;33(3):366-72.10.1016/j.gaitpost.2010.12.003
  29. Qiu H, Rehman RZU, Yu X, Xiong S. Application of wearable inertial sensors and a new test battery for distinguishing retrospective fallers from non-fallers among community-dwelling older people. Scientific reports. 2018;8(1):16349
  30. Jutharee W, Paengkumhag C, Limpornchitwilai W, Mo WT, Chan JH, Jennawasin T, et al. Fall risk assessment dataset: older-adult participants undergoing the time up and go test. Data Brief. 2023;51:109653.10.1016/j.dib.2023.109653
  31. Handelzalts S, Alexander NB, Mastruserio N, Nyquist LV, Strasburg DM, Ojeda LV. Detection of Real-World Trips in At-Fall Risk Community Dwelling Older Adults Using Wearable Sensors. Front Med (Lausanne). 2020;7:514.10.3389/fmed.2020.00514
  32. Rivolta MW, Aktaruzzaman M, Rizzo G, Lafortuna CL, Ferrarin M, Bovi G, et al. Evaluation of the Tinetti score and fall risk assessment via accelerometry-based movement analysis. Artif Intell Med. 2019;95:38-47.10.1016/j.artmed.2018.08.005
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