Blood Sugar Monitor - Breathalyzer
Blood Sugar Monitor - Breathalyzer
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Developed a non-invasive diabetes breathalyzer prototype designed to detect acetone levels in exhaled breath as an indicator of blood glucose levels. The device leverages sensor technology to provide a quick, painless alternative to traditional blood glucose monitoring methods.
Developed a non-invasive diabetes breathalyzer prototype designed to detect acetone levels in exhaled breath as an indicator of blood glucose levels. The device leverages sensor technology to provide a quick, painless alternative to traditional blood glucose monitoring methods.
In this project, I served as the lead designer and developer, focusing on the integration of sensor technology and system calibration. I collaborated closely with a multidisciplinary team, including biomedical engineers, chemists, and software developers, to ensure accurate detection and data analysis. The project resulted in a functional prototype that successfully demonstrated the ability to measure acetone levels in breath, offering a promising alternative for non-invasive diabetes monitoring.
In this project, I served as the lead designer and developer, focusing on the integration of sensor technology and system calibration. I collaborated closely with a multidisciplinary team, including biomedical engineers, chemists, and software developers, to ensure accurate detection and data analysis. The project resulted in a functional prototype that successfully demonstrated the ability to measure acetone levels in breath, offering a promising alternative for non-invasive diabetes monitoring.
The images for this project showcase the design and development process of the diabetes breathalyzer, from initial concept sketches to the final functional prototype.
The images for this project showcase the design and development process of the diabetes breathalyzer, from initial concept sketches to the final functional prototype.
The first set of images highlights early models and drawings of the device, illustrating its ergonomic design for ease of use. Next, the process of finding an ideal solution mix is demonstrated, alongside data of initial results.
The first set of images highlights early models and drawings of the device, illustrating its ergonomic design for ease of use. Next, the process of finding an ideal solution mix is demonstrated, alongside data of initial results.
In this project, I served as the lead designer and developer, focusing on the integration of sensor technology and system calibration. I collaborated closely with a multidisciplinary team, including biomedical engineers, chemists, and software developers, to ensure accurate detection and data analysis. The project resulted in a functional prototype that successfully demonstrated the ability to measure acetone levels in breath, offering a promising alternative for non-invasive diabetes monitoring.
In this project, I served as the lead designer and developer, focusing on the integration of sensor technology and system calibration. I collaborated closely with a multidisciplinary team, including biomedical engineers, chemists, and software developers, to ensure accurate detection and data analysis. The project resulted in a functional prototype that successfully demonstrated the ability to measure acetone levels in breath, offering a promising alternative for non-invasive diabetes monitoring.
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