Towards data-driven stroke rehabilitation via wearable sensors and deep
learning
- URL: http://arxiv.org/abs/2004.08297v3
- Date: Thu, 18 Jun 2020 22:24:10 GMT
- Title: Towards data-driven stroke rehabilitation via wearable sensors and deep
learning
- Authors: Aakash Kaku, Avinash Parnandi, Anita Venkatesan, Natasha Pandit, Heidi
Schambra and Carlos Fernandez-Granda
- Abstract summary: In preclinical models of stroke, high doses of rehabilitation training are required to restore functional movement to the affected limbs of animals.
In humans, however, the necessary dose of training to potentiate recovery is not known.
Here, to develop a measurement approach, we took the critical first step of automatically identifying functional primitives.
- Score: 13.839058010830971
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Recovery after stroke is often incomplete, but rehabilitation training may
potentiate recovery by engaging endogenous neuroplasticity. In preclinical
models of stroke, high doses of rehabilitation training are required to restore
functional movement to the affected limbs of animals. In humans, however, the
necessary dose of training to potentiate recovery is not known. This ignorance
stems from the lack of objective, pragmatic approaches for measuring training
doses in rehabilitation activities. Here, to develop a measurement approach, we
took the critical first step of automatically identifying functional
primitives, the basic building block of activities. Forty-eight individuals
with chronic stroke performed a variety of rehabilitation activities while
wearing inertial measurement units (IMUs) to capture upper body motion.
Primitives were identified by human labelers, who labeled and segmented the
associated IMU data. We performed automatic classification of these primitives
using machine learning. We designed a convolutional neural network model that
outperformed existing methods. The model includes an initial module to compute
separate embeddings of different physical quantities in the sensor data. In
addition, it replaces batch normalization (which performs normalization based
on statistics computed from the training data) with instance normalization
(which uses statistics computed from the test data). This increases robustness
to possible distributional shifts when applying the method to new patients.
With this approach, we attained an average classification accuracy of 70%.
Thus, using a combination of IMU-based motion capture and deep learning, we
were able to identify primitives automatically. This approach builds towards
objectively-measured rehabilitation training, enabling the identification and
counting of functional primitives that accrues to a training dose.
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