Responsible for supporting development of the next generation of Magnetic Resonance Conditional (MRC) active implantable medical devices, i.e., Neuromodulation devices for Spinal Cord Stimulation-SCS, Deep Brain Stimulation-DBS, Dorsal Root Ganglion-DRG, Thermal Ablation devices.

Clients: Medtronic, Boston Scientific, Smith & Nephew, Becton Dickinson

Demonstrated experience with impactful results in the medical device industry in the areas of new product introduction, new product development, verification, and validation (V&V) methods, risk management, remediation, and continuous quality improvement. Reviewed design history files (DHF), Design history records (DHR), Design Verification/Design Reviews (DR), standard operating procedures (SOPs), and component drawings. Supported quality Design Assurance activities for class II and class III medical devices (percutaneous, implantable pulse generator) by remediating the design history files that includes customer requirements, hazard analysis. Design FMEA and process FMEA. Familiar with FMECA (Failure, Mode, Effect, Critical Analysis). Also, worked as a CAPA (Corrective and Preventive Maintenance) owner. Performed Root Cause Analysis (RCA) for the testing in the QA environment and developed remediation plans to run through the CAPA system.

Designed innovative and novel multi-perforated needle designs using finite element methods to have better infusion for Type-1 Diabetes patients. The Clinical trials on Swine are going on at Sidney Kimmel Medical College at Thomas Jefferson University, Pennsylvania with NIH grant project of California based medical start-up company Capillary Biomedical Inc.

To reduce tissue damage from reperfusion injury and provides localized cooling through specially designed infusion catheters (two-lumen and four-lumen design) for heart stroke patients. This project is in association with an NIH grant project of company Focal Cool, LLC.

Research work involves designing a patient specific modelling approach using computational software’s for “Medical Imaging Based Interventions” in “Breast Cancer Treatment” using magnetic nanoparticles induced Hyperthermia. It is projected by using computational Software’s/tools to design the future Hyperthermia Treatment Planning Protocols to study the Biological Heat Transfer in Cancerous tissues (Breast Cancer) at the nanoscale. A-ACHIEVING, MMAINTAINING, M-MONITORING of temperature and Dose distribution patterns and for mapping the simulation results with Clinical outcomes of In-vitro phantom based studies or real patient specific In-vivo trials. The sole purpose is to increase the survival prognosis of breast cancer patients. These preoperative simulations will be an add on to Targeted Drug Delivery/ Computational Surgeries to pre-analyze the results before actual surgical treatments and Hyperthermia treatments.

To perform computational modelling of deep, interstitial, and superficial hyperthermia applicators to perform 3D simulations of heating patterns in anatomical patient models to facilitate the development of 3D patient-specific treatment planning protocols.

To provide clinical professional service while ensuring that right amount of radiation dose to be delivered at right location as part of treatment planning, patient-specific plan verification measurements/ calculations thereby ensuring safety, quality assurance and assisting the interdisciplinary medical physics team with the development of customized software tools.

Completed two months Industrial Training at M/s SML Isuzu Ltd. (Formerly Swaraj Mazda Ltd.) in Bus body project.

• Completed two months Industrial Training at PGIMER, Chandigarh as a Refrigeration Engineer in RAC (Engineering Department) as part of minor project in Master’s studies.