A novel wearable device for automated real-time detection of epileptic seizures.

Mikael Habtamu, Keneni Tolosa, Kidus Abera, Lamesgin Demissie, Samrawit Samuel, Yeabsera Temesgen, Elbetel Taye Zewde, Ahmed Ali Dawud
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Abstract

Background: Epilepsy is a neurological disorder that has a variety of origins. It is caused by hyperexcitability and an imbalance between excitation and inhibition, which results in seizures. The World Health Organization (WHO) and its partners have classified epilepsy as a major public health concern. Over 50 million individuals globally are affected by epilepsy which shows that the patient's family, social, educational, and vocational activities are severely limited if seizures are not controlled. Patients who suffer from epileptic seizures have emotional, behavioral, and neurological issues. Alerting systems using a wearable sensor are commonly used to detect epileptic seizures. However, most of the devices have no multimodal systems that increase sensitivity and lower the false discovery rate for screening and intervention of epileptic seizures. Therefore, the objective of this project was, to design and develop an efficient, economical, and automatically detecting epileptic seizure device in real-time.

Methods: Our design incorporates different sensors to assess the patient's condition such as an accelerometer, pulsoxymeter and vibration sensor which process body movement, heart rate variability, oxygen denaturation, and jerky movement respectively. The algorithm for real-time detection of epileptic seizures is based on the following: acceleration increases to a higher value of 23.4 m/s2 or decreases to a lower value of 10 m/s2 as energy is absorbed by the body, the heart rate increases by 10 bpm from the normal heart rate, oxygen denaturation is below 90% and vibration should be out of the range of 3 Hz -17 Hz. Then, a pulsoxymeter device was used as a gold standard to compare the heart rate variability and oxygen saturation sensor readings. The accuracy of the accelerometer and vibration sensor was also tested by a fast-moving and vibrating normal person's hand.

Results: The prototype was built and subjected to different tests and iterations. The proposed device was tested for accuracy, cost-effectiveness and ease of use. An acceptable accuracy was achieved for the accelerometer, pulsoxymeter, and vibration sensor measurements, and the prototype was built only with a component cost of less than 40 USD excluding design, manufacturing, and other costs. The design is tested to see if it fits the design criteria; the results of the tests reveal that a large portion of the scientific procedures utilized in this study to identify epileptic seizures is effective.

Conclusion: This project is objectively targeted to design a medical device with multimodal systems that enable us to accurately detect epileptic seizures by detecting symptoms commonly associated with an episode of epileptic seizure and notifying a caregiver for immediate assistance. The proposed device has a great impact on reducing epileptic seizer mortality, especially in low-resource settings where both expertise and treatment are scarce.

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一种用于癫痫发作自动实时检测的新型可穿戴设备。
背景:癫痫是一种有多种病因的神经系统疾病。它是由过度兴奋性和兴奋与抑制之间的不平衡引起的,从而导致癫痫发作。世界卫生组织(世卫组织)及其合作伙伴将癫痫列为一项重大公共卫生问题。全球有5000多万人受到癫痫的影响,这表明如果癫痫发作得不到控制,患者的家庭、社会、教育和职业活动将受到严重限制。患有癫痫发作的患者有情绪、行为和神经问题。使用可穿戴传感器的警报系统通常用于检测癫痫发作。然而,大多数设备没有多模态系统,以增加敏感性和降低癫痫发作的筛查和干预的错误发现率。因此,本课题的目标是设计和开发一种高效、经济、实时自动检测癫痫发作的装置。方法:我们的设计采用不同的传感器来评估患者的病情,如加速度计、脉搏计和振动传感器,分别处理身体运动、心率变异性、氧变性和突然运动。实时检测癫痫发作的算法是基于:随着能量被身体吸收,加速度增加到23.4 m/s2的较高值或降低到10 m/s2的较低值,心率比正常心率增加10 bpm,氧变性低于90%,振动应不在3hz - 17hz的范围内。然后,使用脉搏计装置作为金标准来比较心率变异性和氧饱和度传感器读数。加速度计和振动传感器的准确性也通过一个快速移动和振动的普通人的手来测试。结果:构建了原型并进行了不同的测试和迭代。对该装置进行了准确性、成本效益和易用性测试。加速度计、脉搏计和振动传感器的测量精度达到了可接受的水平,并且原型机的组件成本低于40美元,不包括设计、制造和其他成本。对设计进行测试,看它是否符合设计标准;测试结果表明,在本研究中用于识别癫痫发作的大部分科学程序是有效的。结论:本项目的客观目标是设计一种具有多模式系统的医疗设备,使我们能够通过检测癫痫发作通常相关的症状并通知护理人员立即提供帮助来准确检测癫痫发作。该装置对降低癫痫发作死亡率有很大的影响,特别是在缺乏专业知识和治疗的低资源环境中。
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