| scholarly article | Q13442814 |
| P356 | DOI | 10.1038/S41746-020-00334-Y |
| P698 | PubMed publication ID | 33083562 |
| P50 | author | Matthew D Czech | Q100752780 |
| Xuemei Cai | Q100752781 | ||
| Tomasz Adamusiak | Q47502893 | ||
| Fikret Isik Karahanoglu | Q57437348 | ||
| Koene R A Van Dijk | Q79373676 | ||
| P2093 | author name string | Charmaine Demanuele | |
| Hao Zhang | |||
| Shyamal Patel | |||
| Vesper Ramos | |||
| Monica Calicchio | |||
| Amey Kelekar | |||
| Dimitrios Psaltos | |||
| Andrew Messere | |||
| Mar Santamaria | |||
| P2860 | cites work | Quantity and quality of gait and turning in people with multiple sclerosis, Parkinson's disease and matched controls during daily living | Q92577959 |
| GaitPy: An Open-Source Python Package for Gait Analysis Using an Accelerometer on the Lower Back | Q113227839 | ||
| Walking speed: the functional vital sign | Q26821844 | ||
| Gait analysis using wearable sensors | Q26863641 | ||
| Instrumenting gait with an accelerometer: a system and algorithm examination | Q28390995 | ||
| Gait disorders in adults and the elderly : A clinical guide. | Q30361794 | ||
| Wearable accelerometry-based technology capable of assessing functional activities in neurological populations in community settings: a systematic review. | Q30577428 | ||
| How many days of monitoring predict physical activity and sedentary behaviour in older adults? | Q35089073 | ||
| Quantitative gait dysfunction and risk of cognitive decline and dementia | Q36015763 | ||
| Free-living gait characteristics in ageing and Parkinson's disease: impact of environment and ambulatory bout length | Q36899411 | ||
| Assessing the temporal relationship between cognition and gait: slow gait predicts cognitive decline in the Mayo Clinic Study of Aging | Q37015913 | ||
| Poor Gait Performance and Prediction of Dementia: Results From a Meta-Analysis | Q37656470 | ||
| Systematic review of the Hawthorne effect: new concepts are needed to study research participation effects | Q37671448 | ||
| Gait speed as a measure in geriatric assessment in clinical settings: a systematic review | Q38038130 | ||
| Potential of APDM mobility lab for the monitoring of the progression of Parkinson's disease | Q38731344 | ||
| Free-living monitoring of Parkinson's disease: Lessons from the field. | Q38907098 | ||
| Gait event detection in laboratory and real life settings: Accuracy of ankle and waist sensor based methods | Q39447594 | ||
| Wearable pendant device monitoring using new wavelet-based methods shows daily life and laboratory gaits are different. | Q40657660 | ||
| Comparative assessment of different methods for the estimation of gait temporal parameters using a single inertial sensor: application to elderly, post-stroke, Parkinson's disease and Huntington's disease subjects | Q40749460 | ||
| Validation of an Accelerometer to Quantify a Comprehensive Battery of Gait Characteristics in Healthy Older Adults and Parkinson's Disease: Toward Clinical and at Home Use. | Q41105148 | ||
| The association between retirement and age on physical activity in older adults | Q45064141 | ||
| Assessing physical activity in older adults: required days of trunk accelerometer measurements for reliable estimation. | Q45389338 | ||
| Toward automated, at-home assessment of mobility among patients with Parkinson disease, using a body-worn accelerometer | Q46663623 | ||
| The minimum number of days required to establish reliable physical activity estimates in children aged 2-15 years. | Q46948293 | ||
| Assessment of spatio-temporal gait parameters from trunk accelerations during human walking | Q47344156 | ||
| Cognitive functioning is more closely related to real-life mobility than to laboratory-based mobility parameters. | Q50530989 | ||
| Intra-individual variation and estimates of usual physical activity. | Q50653455 | ||
| Quantification of everyday motor function in a geriatric population. | Q51894216 | ||
| Improvement in usual gait speed predicts better survival in older adults. | Q51904548 | ||
| Accuracy, sensitivity and robustness of five different methods for the estimation of gait temporal parameters using a single inertial sensor mounted on the lower trunk. | Q53057905 | ||
| Bootstrap Methods: Another Look at the Jackknife | Q55950786 | ||
| Guidelines, criteria, and rules of thumb for evaluating normed and standardized assessment instruments in psychology | Q56852931 | ||
| Wavefunction Engineering of Type-I/Type-II Excitons of CdSe/CdS Core-Shell Quantum Dots | Q60915027 | ||
| Sources of variance in daily physical activity levels as measured by an accelerometer | Q74583594 | ||
| How humans walk: bout duration, steps per bout, and rest duration | Q83230105 | ||
| Assessment of spatio-temporal gait parameters using inertial measurement units in neurological populations | Q84566365 | ||
| Continuous Digital Monitoring of Walking Speed in Frail Elderly Patients: Noninterventional Validation Study and Longitudinal Clinical Trial | Q91486486 | ||
| Mapping Associations Between Gait Decline and Fall Risk in Mild Cognitive Impairment | Q92040603 | ||
| P304 | page(s) | 127 | |
| P577 | publication date | 2020-09-30 | |
| P1433 | published in | npj Digital Medicine | Q73908508 |
| P1476 | title | Age and environment-related differences in gait in healthy adults using wearables | |
| P478 | volume | 3 |
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