When embedded in a wearable or mobile device and enabled by algorithms, ECG and EKG biosensors open up a world of opportunities for consumers, as well as device manufacturers. ECG and EKG readings are painless and completely non-invasive. In biosensor form, ECGs and EKGs can enable incredibly valuable tracking tools (for humans and their four-legged friends!). While initially only available in medical environments or under the supervision of a healthcare provider, the rise of wearable technology equipped with ECG and EKG biosensors is making it possible for consumers to gain access to their personal data, using it to track their health and make necessary lifestyle changes over the long term. Einthoven would later win the Nobel prize for inventing the electrocardiograph.Īs the technology evolves, it is becoming easier than ever for device manufacturers-and the customers that buy their products-to make use of ECG and EKG. This process was transmitted to his lab from a hospital (a distance of nearly a mile!). Willem Einthoven recorded the first human electrocardiogram. A milestone moment in the evolution of this technology occurred in 1905, when Dutch physiologist Dr. The Evolution of ECG and EKGĮCG and EKG technology can feel very futuristic in a lot of ways, but-believe it or not-they actually began to be developed in the late 19th century. When paired with algorithms, an electrocardiogram biosensor can translate the data it collects from this electrical activity into actionable insight into an individual’s health. When a person has an ECG or EKG performed, they are having these electrical impulses measured and recorded. These electrical impulses are essential for ensuring your heart keeps a steady pace. This electrical impulse travels across the muscle cells of the heart and triggers contractions-more commonly known as your heart beat. For your heart to beat, its sinoatrial node (also known as an SA node) needs to send out an electrical impulse. When you dive a little deeper into how ECGs and EKGs work, you’ll discover a fascinating process.
With help from algorithms, this data can be used to provide insight on a wide assortment of biometrics, including: In the simplest of terms, ECGs and EKGs are used to measure electrical activity and collect data on the health of your heart. However, once you know the difference between an ECG and an EKG, you’ll be well on your way to discovering what makes them increasingly valuable tools for device manufacturers that want to create revolutionary products for consumer health and wellbeing.
If you’re not familiar with these abbreviations, it can be tricky to determine which is which.
When investigating applications for biosensors-particularly electrocardiograms-you’ll eventually come across two very common abbreviations: ECG and EKG.
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