The Promise of mHealth

Access to rehabilitation services

Examples of daily care confounders can be found for any neurological disease as well as in the chronic pain, cardiovascular, pulmonary, and cancer literature. Stroke will serve as an exemplar. After inpatient stroke rehabilitation, outpatient training is needed by most patients. A 2005 Centers for Disease Control survey found that only 31% of stroke survivors received outpatient rehabilitation, ¹² significantly fewer than expected if clinical guidelines were followed.^13,14 Even when offered, these services are often unstructured, difficult to obtain, and not driven by progressive goals to enable independent walking in the community and functional use of an affected upper extremity or to lessen deconditioning.^15,16 Not only in the United States, but around the world, access to rehabilitation is very uneven, and expertise in solving problems related to sensorimotor impairments and disabilities seems limited. Some efforts are under way to develop affordable inpatient and outpatient systems that can reach more patients,^17-19 but new strategies for less expensive and more relevant home-based care are urgently needed to reduce disability after stroke as well as for most other neurological diseases.

Availability of home-based therapies

Home-based therapies after stroke usually lack coordination and a focus on higher levels of functioning. During a home-based therapeutic program directed by verbal instruction, physicians and therapists are unable to weigh a patient’s progress in terms of actual time and effort spent on prescribed activities, such as the number of repetitions and the quality of practiced movements. The ability of patients to self-monitor rehabilitation practice is probably even less reliable when more technical information is given about practice parameters, such as advice about ways to reduce gait deviations that impede balance. Counseling alone about the benefits of practice and physical activity has not been effective. ²⁰ For neurological diseases such as stroke, “the best and most cost effective way of increasing physical activity has not been found.”^21,22 On the other hand, the efficacy of highly supervised and rather intensive training to improve balance, walking speed, fitness, or use of the affected upper extremity after stroke is evident.^16,23,24 Indeed, a progressive, home-exercise program managed by therapists in the Locomotor Experience Applied Post-Stroke (LEAPS) clinical trial revealed walking-related gains that were equivalent to a much more walking-intensive physical therapy provided at clinics. ¹⁶ The problem is how to inexpensively make direct supervision available. In addition, although exercise for fitness and more functional mobility^25,26 may reduce falls, moderate the cardiovascular risk profile, and enable greater participation in usual roles,^27-31 outpatient therapy for these goals is usually not covered by medical insurance.^15,32,33 Wireless health strategies that enable monitoring and feedback by professionals from their offices as patients practice skills, walking, strengthening, and fitness in the home may be an efficient and effective alternative strategy for the delivery of needed care.

Complications of impairment and disability

Many motor-related errors of omission and commission can add to morbidity after stroke, such as contractures, pain, decubitus ulcers, nonuse of an upper extremity, and falls. For example, in the first year after stroke, 60% of disabled people suffer falls, ³⁴ and half have multiple falls ¹⁶ with frequent injuries and bone fractures. ³⁵ Fear of falling leads to a decline in physical activity followed by greater risk for cardiovascular morbidity and further loss of quality of life. Clearly, better recognition of mechanisms underlying imbalance and falls and more effective interventions are needed. ³⁶ Falls, of course, are common among older people and most of those with neurological diseases that cause ataxia or paresis.^37-40 Measurements by wearable sensors of balance during real-world activities and at the time of a fall may offer a more promising mechanistic approach to prevention.

Spasticity has many treatments, but their effect on impairment and disability in actual use of the hand, arm, or leg is unclear and not revealed by existing measures of outpatient activities.^41-47 Indeed, some studies question the clinical meaning of measures of spasticity, especially the Ashworth Scale. ⁴⁸ Measures for the upper extremity usually do not assess changes in voluntary movement.^49,50 Could assessment of the quantity and quality of purposeful everyday use of the affected arm or leg add a reliable measure of the efficacy of interventions?

Limitations of assessment tools

Clinical researchers have been limited to performing assessments in the clinic or laboratory. Laboratory measures in most clinical trials indirectly assess the outcomes that are most meaningful to the investigators and perhaps to the participants. Indeed, the extent to which the limitations of existing rating scales are to blame for the failure of clinical trials to deliver better treatments, while unknown, is a source of discomfort for all trialists. ⁵¹ Researchers have long sought direct, ecologically valid measures of upper- and lower-extremity activities. Inexpensive interval and ratio measures of real-world functioning could offer higher face validity for valued outcomes than ordinal, self-reported scales or timed laboratory tasks. Optimal activity-based outcome measures would also be agnostic, in the sense that they would not be disease centric. Rather, the tools would help integrate the domains of sensorimotor impairment, disability, activity, and participation, regardless of pathology.

Walking

Everyday sensing measures may offer greater validity and accuracy about outcomes of interventions than laboratory-based tests, which must be supplemented by questionnaires of self-reported daily activity to discern real-world behavior. For example, short-distance (6-15 m) walking speed on a flat indoor surface is the primary outcome measure of most clinical trials of interventions to improve walking after stroke, multiple sclerosis, Parkinson disease, and spinal cord injury and for neuropediatrics.^16,52-63 Walking capacity, that is, the distance walked in 3 to 6 minutes, is a common secondary outcome and may serve as an indicator of overall health, at least in older people. ⁶⁴ These walking tasks under ideal conditions cannot, however, reveal how much, how fast, and how well people ordinarily walk in the home and community when faced with the constraints of their environments and impairments. Pedometers can count the number of steps, but no more. On the other hand, wireless sensor data about the range of walking speeds used in the home and community, distances walked in each bout, actual leg exercise time and energy expended on a stationary bicycle, and alterations in spatiotemporal parameters of gait under varying demands could complement laboratory tests and ordinal scales of walking, disability, and activity-related quality of life.

Functional use of the upper extremity

Ordinal scales of upper-extremity impairment and disability are commonly used but are limited by floor and ceiling effects, examiner expertise and bias, interrater reliability across trial sites, and uncertain face validity. ⁵¹ Timed tasks such as the Wolf Motor Function Test (WMFT) are often used as the primary outcome in clinical trials of rehabilitation interventions such as constraint-induced movement therapy, bimanual therapy, and brain stimulation.^24,65-75 The WMFT and complementary ordinal scales are the de facto outcomes for most robotic, functional neuromuscular stimulation, and neurostimulation trials as well.^76-84 Interpretation of the WMFT improves when combined with a structured interview, such as the Motor Activity Log, about the amount of upper-extremity activity. ⁸⁵ Like all self-report tools, the Motor Activity Log has some inherent weaknesses, including recall bias, subjectivity, demand characteristics, and experimenter bias. Thus, available tools do not give an investigator a direct measure of the variety and quantity of purposeful movements performed in everyday reaching, self-care, skills practice, and exercise.

Sensors

Single biaxial accelerometers have been commercially available (Actigraph, RT3, and Omron) to count movements of the arm or leg during reaching or stepping.^55,86,87 Several types of biaxial and triaxial accelerometers have also been used in laboratory-based research. ⁸⁶ A triaxial piezoresistant accelerometer, fastened over the L3 spinous process (DynaPort MiniMod, McRoberts) can define gait stance and swing times as well as walking speeds >0.5 m/s. ⁸⁸ A system of 5 wired biaxial accelerometers (IDEEA, Minisun) placed over the thigh, sole, and sternum can quantify spatiotemporal aspects of gait and discriminate between specific activities, such as walking versus stair climbing, but the algorithms do not detect walking speeds <0.4 m/s.^89,90 The intraclass correlation coefficient for repeatability and reliability of acceleration-based gait analysis, however, is very high for detecting cadence, speed, step length, and asymmetry in stance and swing times along with irregularities associated with turns and changes in speed in healthy participants and hemiparetic patients after stroke. ⁹¹ A central problem for the deployment of commercial devices by rehabilitation researchers is that they use proprietary data analysis systems to detect a small repertoire of movements, mostly in healthy individuals. In addition, they are too expensive to be distributed widely among outpatients for trials, with prices ranging from $1000 (BioSensics) per accelerometer to $4000 (MiniSun) for a set.

Research groups are beginning to publish reports of sensor-based algorithms that better identify purposeful upper-extremity and walking movements for highly impaired reaching and walking.^7,8,92 Other pilot studies found that wearable accelerometers can substitute for traditional force-plate measures to reveal postural sway and anticipatory postural adjustments.^93-95 Chest and waist triaxial accelerometers, using threshold-based algorithms, can discriminate between a fall and daily activities.^94,96,97 In general, these devices have only been put to use in a laboratory setting.

The Wireless Health Institute at the University of California Los Angeles developed and tested a complete architecture for activity pattern recognition, called the Medical Daily Activity Wireless Network (MDAWN).^5,98,99 The MDAWN includes components for automated sensor data collection, transport to a remote and secure repository, individualized subject modeling, and activity state classification based on multiple sensor, data-fusion methods. ⁹⁹ Data obtained from triaxial accelerometers (Gulf Coast Data Concepts, $230 per set) placed just above each lateral malleolus are uploaded to a computer by USB port or to a smartphone by Bluetooth, then sent opportunistically via WiFi or cell connection to the MDAWN server. Analyzed data are automatically sent to a clinical trial database or to a participant for feedback.

Machine-learning algorithms in MDAWN primarily use Bayesian sensor fusion to generate an individual activity template based on the movements of interest made by each participant.^99-101 About 10 repetitions of a movement or 2 timed walks of 10 m at more than 1 speed fulfill the requirements for pattern recognition to identify walking or calculate walking or exercise parameters.^5,102 The template is a set of statistically unique features derived from frequencies, amplitudes, waveforms, time average of acceleration, and derivatives of these across all 3 gravity-sensitive axes from both ankles. The training data take into account the peculiarities of each person’s movements and motor control. Once a person’s template has been defined, further data collections during everyday activities are evaluated by the MDAWN system for periods of activity with features that match it.^5,103,104

Sensor-derived algorithms can potentially be trained to recognize most real-world daily activity patterns, such as reaching, eating, washing, exercising with equipment, standing up, walking at any speed, and climbing stairs. The optimal placement of the accelerometers depends on the activities to be captured. By merging the activity data with GPS, voice notation, or on-demand photo/video using a tiny camera hanging from the neck, the environs of the participant or the object/task being managed can be distinguished. In addition, for less than $15, torque sensors and Bluetooth can be integrated into inexpensive exercise equipment such as elastic resistance bands and cycling apparatus to add the capability of recording and transmitting the actual forces or repetitions exerted by participants. An important next step is to test existing sensors in real-world settings across neurological diseases to demonstrate their reliability, validity, and responsiveness to measure purposeful activities at several ICF levels.

Data analyses

The use of Bayesian fusion to combine data from multiple body sites and different types of sensors provides the opportunity to implement a wide range of analytic techniques to compare community-based activities with laboratory- or clinic-based testing. For example, the coefficient of variation of stride-to-stride fluctuations can be assessed with an accelerometer on each ankle, ⁹⁰ Other promising methods for modeling fluctuations in spatiotemporal and foot pressure measurements during stance and gait,^105,106 such as high stride and swing time variances, may help predict falls across neurological diseases as well as freezing of gait in Parkinson disease. ¹⁰⁷ mHealth technology also offers repeated measures that are easy to acquire, enabling researchers to use time-series methodology to single-participant and group data. Additional analytic tools such as trend estimation, structural modeling, and bioinformatics will also lend themselves to the large clinical and sensor data sets obtained in trials.