Taiwan's highest care-to-patient ratio is 1:16, meaning that one caregiver is responsible for 16 patients, far exceeding the internationally recognized optimal care-to-patient ratio.
Source: CommonWealth Magazine
Even with full personal protective equipment, the risk of contracting COVID-19 for frontline healthcare professionals is at least three times higher than that of the general population.
Source: CommonWealth Magazine
The rise and development of AI digital technology allows us to prevent diseases and assist in counseling services, reducing the risk of infection, medical expenses, and social costs.
Source: Electronic Commerce Times
● | Inefficiency due to the shortage of in-hospital medical resources and manpower. |
● | High risk of infection among frontline healthcare professionals. |
● | Inability to track the health status of discharged patients and patients who need to return to the hospital. |
Users can set the measurement frequency to automatically measure the physiological data at regular intervals, and automatically upload the data through mobile APPs or WiFi Gateway, which is convenient and fast.
Real-time monitoring/reducing healthcare costs/chronic disease management/improving patient engagement/remote healthcare consulting... etc., with various impacts and benefits.
Remote physiological monitoring enables hospitals to monitor patients' physiological data in real time, including pulse rate, blood oxygen saturation and blood pressure levels. This helps to detect changes in the patient's physiological status in a timely manner and improves the ability to cope with acute illnesses.
For patients suffering from chronic diseases, remote physiological monitoring provides a more effective way of management. Hospitals can track patients' physiological data in real time through remote monitoring to detect potential problems in advance and prevent the condition from deteriorating.
In-hospital to out-of-hospital care improves patient engagement and makes it easier for family and friends to be involved in each other's health management. Patients can take a more active role in the collection and monitoring of physiological data to better understand and manage their health status.
● | Highly efficient acquisition of physiological signals. |
● | Bluetooth transmission for automated continuous monitoring and simultaneous uploading to mobile devices. |
● | Wristwatch-like design for wireless comfort and freedom of movement. |
● | Easy-to-operate interface, no need for personal guidance, suitable for home use. |
● | Stringent development process to ensure the accuracy of physiological parameters. |
● | A large amount of data from clinical validation. |
● | Strict validation process to ensure reliability. |
● | Measurement scope based on medical standards. |
● | Dedicated APP and software to receive and transmit data. |
● | Graphical data of physiological parameters to assist medical judgment. |
● | Automated continuous monitoring and synchronized uploading to the cloud and central monitoring station. |
● | Real-time alarm notification for medical care to be provided at the first time. |
● | Automated physiological data recording and analysis, reducing paper-based recording errors. |
● | Contactless remote real-time monitoring to minimize contact infection. |
● | Multi-bed management, synchronized alarm notification and manpower allocation to where it is needed. |
● | Systematized physiological information management, automatic report generation for easy tracking and creation of diagnostic references. |
Biophotonic TechnologyBiophotonic technology utilizes the properties of light, such as reflection, refraction, scattering, and absorption, to measure physical or chemical parameters in biological tissues. These parameters help to understand the structure, function, and metabolism of biological tissues, such as oxygen saturation, pulse rate, and respiration rate. The application of biophotonics in wearable devices offers the advantages of non-invasiveness, high sensitivity, and multi-functionality, making it a promising technology. Additionally, it can be integrated with other sensing technologies to enable physiological signal monitoring and health management. |
Optical-Electromechanical Integration DesignBiophotonics and electro-mechanical integration design is one of the key technologies for medical wearable products. In order to make the products efficient, accurate, durable, cost-effective, and provide a better user experience, product development and design need to consider the integration of technologies such as optics, mechanism, electronics, and software. In addition to improving product performance and efficiency to meet different medical needs and application scenarios, the ability to integrate opto-mechanical-electronic design is also an important factor for innovation and competitiveness. |
Medical AlgorithmMedical algorithms play a crucial role in modern medicine, requiring not only a rigorous development process to ensure the accuracy of physiological parameters, but also the use of a large amount of clinical evidence data and a strict validation process to ensure their reliability. Therefore, medical algorithms can be applied to various aspects of diagnosis, prediction, treatment planning, and monitoring in smart healthcare to provide better medical services and healthcare. |
The big data for health and epidemic prevention management platform (oCareHC.com) provides a multi-level management model that can individually differentiate between administrators, departments, doctors, nurses, and patients. Different management levels can also be linked to share patient records, the backend records and the maintenance records of each account, which is flexible and can be customized for special needs.
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Wearable medical devices have the advantages of easy operation, long-term use, non-invasiveness, and real-time monitoring, among others. With the growing concept of preventive medicine and personal health care, more and more people are starting to use wearable medical devices to