Stanford researchers put Apple Watch to AF test
November 13, 2018
Researchers at Stanford University's School of Medicine have completed enrolment of a large-scale study using the Apple Watch to determine whether wearable technology can identify atrial fibrillation.
The study rationale and design published in the American Heart Journal describes the design of this clinical trial, said to be the largest screening study on atrial fibrillation ever done.
The results of the study, which has enrolled over 400,000 participants, will provide initial evidence of the smartwatch's ability to identify pulse irregularity that may be consistent with previously unknown atrial fibrillation, or atrial flutter, collectively known as AF.
"The advantage of the app that uses the optical sensor is that it can check for an irregular pulse multiple times throughout the day in the background, without needing the user to actively engage the application," said Marco Perez, assistant professor of cardiovascular medicine at Stanford and one of the principal investigators of the study.
With a strong demand for health-centric devices, using smart phones, watches and other wearables has become a routine experience for many Americans, with over three-quarters of the population owning a smartphone. The ability of a smartwatch potentially to identify an arrhythmia, which is when the heart beats too slowly, too fast or in an irregular way, is of significant public health interest: AF affects between three and six million people in the USA; if left undiagnosed or untreated, AF can lead to the development of heart failure or other complications, including stroke.
It is estimated that 700,000 people in the USA may have previously unknown atrial fibrillation.
The study aims to understand whether wearable technology can identify irregular heart rhythms suggestive of AF by analysing pulse-rate data from the optical sensor on the Apple Watch. To determine the pulse reading, the smartwatch uses LED lights and light-sensitive photodiodes to measure the changes in the volume of blood flow passing through the user's wrist to generate a photoplethysmogram that is used to estimate the pulse. The intervals are then used to create a tachogram (pulse rate over time), which can be used to measure pulse irregularity that may signify AF.
If AF is suspected, participants are alerted through a notification system on the Apple Watch and the Apple Heart app. Following an irregular pulse notification, study participants proceed to telehealth video visits with a study doctor – all through the app – and receive an ECG monitoring patch to be worn to confirm the diagnosis of AF.
In the event of urgent symptoms such as chest pain or shortness of breath, participants are directed to their local urgent care or emergency room facility for medical evaluation. The nation-wide implementation of this study gave participants access to medical attention if needed, helping ensure participant safety.
"We now have access to high-quality sensors that can measure and detect changes in our bodies in entirely new and insightful ways without even needing to go to the doctor, but we need to rigorously evaluate them," said Mintu Turakhia, associate professor of cardiovascular medicine at Stanford and the other principal investigator of the study.
The study will determine how many participants who receive irregular pulse notifications are found to have atrial fibrillation, determine how many among those who received an irregular pulse notification go on to get medical attention, and determine the accuracy of irregular pulse-detection on the watch. The study has entered the final phase of data collection and will be completed early next year.