- Description
-
Pocket Clinic provides personalized therapy for patients with chronic conditions, disrupting the drug delivery market by combining cost-effective high-tech equipment with daily use gadgets like smartphones and smartwatches.
- Number of employees
- 2 - 10 employees
- Year established
- 2021
- Company website
- https://pocketclinic.life/
- Categories
- Mechanical engineering Chemical engineering Electrical engineering Software development Hardware
- Industries
- Hospital, health, wellness & medical
Recent projects
Secure Communication Protocols for Medical Devices
Pocket Clinic Corp. is seeking to enhance the security of its medical devices by developing robust cybersecurity protocols. The primary goal of this project is to ensure secure communication between the medical device, its mobile app, and the cloud. This involves defining security measures for the device, establishing a cybersecurity protocol for Bluetooth communication between the app and the device, and creating a protocol for secure data transmission from the mobile app to the cloud. The project will provide learners with an opportunity to apply their knowledge of cybersecurity and network protocols in a practical setting. By focusing on these specific areas, the project aims to protect sensitive medical data from unauthorized access and ensure patient privacy. The project is designed to be completed by a team of learners allowing them to gain hands-on experience in the field of medical device security.
Electrical Circuit Design for a Medical Device
Main Goal for the Project: The main goal of this project is to develop and refine the hardware and software components of the Pocket Clinic smart injector, ensuring it meets all functional and regulatory requirements. Problem Learners Will Be Solving: Learners will address the challenge of designing and coding the electronic boards for the smart injector. This involves creating schematics, selecting appropriate components, designing the PCB, and developing the firmware to ensure seamless operation of the device. Expected Outcome by the End of the Project: By the end of the project, learners are expected to achieve the following outcomes: Hardware Development: Design electronic boards that meet the specific requirements of the Pocket Clinic smart injector. Create detailed schematics and select the appropriate components for optimal performance. Successfully design and fabricate the printed circuit boards (PCBs). Software Development: Develop and debug firmware to ensure the smart injector operates efficiently and accurately. Implement coding solutions that enhance the functionality and reliability of the device. Ensure seamless integration between the hardware and software components for optimal performance. Overall, learners will gain comprehensive experience in both hardware and software aspects of medical device development, contributing to the successful creation of the Pocket Clinic smart injector.
ISO 13485 Implementation Plan
The Objective Implementation plan to achieve compliance with the ISO 13485:2016 standard (Medical devices — Quality management systems — Requirements for regulatory purposes). Primary Focus of the Project: Research and determination of the ISO 13485:2016 Compliance Requirements. Gap Analysis and determination of where we need to improve or implement new controls. Prepare documentation Requirements in ISO 13485
Electrical Circuit Design for a Medical Device
We are developing a biosensor for various chronic diseases. Currently, we are looking for a team of students who can get involved in a smaller part of the project where we need to develop the mechanical assembly along with the required electronics and software. The goal of this project is to improve upon a currently existing and operational (but not optimized) electrical system within a hardware product and assist in the assembly and testing of a new electronic hardware product. The product is a smart injector with sensors and a microprocessor for drug delivery. We hope the student will learn more about electronics design, testing protocols, and quality assurance. The improvements will be evaluated by a number of factors including safety of the design, regulatory compliance, cost reduction, simplification (reduction in component numbers or size), and quality of components/suppliers chosen.