Pre-Emption of Affliction Severity Using HRV Measurements from a Smart Wearable; Case-Study on SARS-Cov-2 Symptoms.

Dhananjay Singh,Ritu Chauhan,Gatha Varma,Madhusudan Singh

doi:10.3390/s20247068

Abstract

Smart wristbands and watches have become an important accessory to fitness, but their application to healthcare is still in a fledgling state. Their long-term wear facilitates extensive data collection and evolving sensitivity of smart wristbands allows them to read various body vitals. In this paper, we hypothesized the use of heart rate variability (HRV) measurements to drive an algorithm that can pre-empt the onset or worsening of an affliction. Due to its significance during the time of the study, SARS-Cov-2 was taken as the case study, and a hidden Markov model (HMM) was trained over its observed symptoms. The data used for the analysis was the outcome of a study hosted by Welltory. It involved the collection of SAR-Cov-2 symptoms and reading of body vitals using Apple Watch, Fitbit, and Garmin smart bands. The internal states of the HMM were made up of the absence and presence of a consistent decline in standard deviation of NN intervals (SSDN), the root mean square of the successive differences (rMSSD) in R-R intervals, and low frequency (LF), high frequency (HF), and very low frequency (VLF) components of the HRV measurements. The emission probabilities of the trained HMM instance confirmed that the onset or worsening of the symptoms had a higher probability if the HRV components displayed a consistent decline state. The results were further confirmed through the generation of probable hidden states sequences using the Viterbi algorithm. The ability to pre-empt the exigent state of an affliction would not only lower the chances of complications and mortality but may also help in curbing its spread through intelligence-backed decisions.

Highlights

IntroductionThe IoT-enabled products have made a foray into our daily lives in a multitude of forms.These forms could vary in size and mobility [1,2,3]
The IoT-enabled products have made a foray into our daily lives in a multitude of forms.These forms could vary in size and mobility [1,2,3]
Since we focused on heart rate variability (HRV) as an important factor among the body vitals, we studied research done over its applicability to health monitoring

Summary

Introduction

The IoT-enabled products have made a foray into our daily lives in a multitude of forms.These forms could vary in size and mobility [1,2,3]. With constantly evolving semiconductor technology, it is possible to host IoT-based intelligence on an even smaller scale Such advances have popularized smart devices that can be worn in the form of a fitness band, a smart garment implanted with sensors, or something as futuristic as a chip implanted into the skin like a tattoo [4]. Some relevant examples include a chest belt that monitored body temperature, heart, and breathing rates to alert against Sudden Infant Death Syndrome [26] Another innovation involved a Micro-Electro-Mechanical Systems (MEMS) technology integrated with a mobile application to protect against ankle sprains [27]. For serious afflictions like heart ailments, a touch device was developed to track bio-parameters like an electrocardiogram; it tracked SpO2 , skin temperature, and the physical activity of the patient [12]. A low-cost assistive wearable was developed to inhibit the bio-mechanical feedback loop between the brain and the hand to reduce the hand tremors and thereby improve the patient’s gripping capability

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Conclusion