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CV.pdf

<aside> <img src="/icons/looped-square_yellow.svg" alt="/icons/looped-square_yellow.svg" width="40px" /> A B O U T M E

Hello! I’m Sanjoy, a passionate bioengineer currently diving deep into lymphatics, biomaterials and stem cell research at the University of Notre Dame. I’m engrossed in pioneering research, and in my free time, I switch gears to indulge in my personal passions, like photography, traveling, and whipping up new recipes in the kitchen. Whether you’re here for a deep dive into the latest in bioengineering or to catch a glimpse of the world through my lens and tastes, I hope you find something that piques your interest.

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What They Say

“…As a Graduate Research Assistant at the University of Notre Dame, Sanjoy led cutting-edge research resulting in impactful publications focused on Biomaterials for Lymphatic Endothelial Cells (LEC) and Stem Cell differentiation. He is in charge of our stem cell culture, which requires daily maintenance and dedication. His leadership was instrumental in spearheading the development of a pending patent for novel Biomaterials, showcasing his pioneering contributions in the field. Sanjoy's ability to develop and maintain relationships with industry professionals and researchers reflects his commitment to collaboration for research projects. Thus far, Sanjoy has published 3 research papers and have 2 additional manuscripts under review and in preparation. I already benefited from his hard work and dedication, because one of the articles was selected as a front cover in journal Biomaterials Science…”

Donny Hanjaya- Putra, University of Notre Dame

“I have worked with Sanjoy for over 4 years in the Hanjaya-Putra Lab at the University of Notre Dame. During that time, we collaborated on multiple projects and he is incredibly helpful, knowledgeable, and hard working. He is able to clearly communicate ideas, is skilled in data interpretation and analysis, and is able to juggle multiple projects at the same time.”

*Eva Hall, University of Notre Dame*

Professional Background

Key Projects

<aside> <img src="/icons/package_green.svg" alt="/icons/package_green.svg" width="40px" /> P A T E N T S

  1. Multi-parameter Tunable Synthetic Matrix for Engineering Lymphatic Vessels. Application No.PCT/IB2024/057334
  2. Synthetic Hyaluronic Acid Coating Preserves the Phenotypes of Lymphatic Endothelial Cells. Application No.PCT/US2024/040065
  3. Robust Differentiation of Human Pluripotent Stem Cells into Lymphatic Endothelial Cells Using Transcription Factors [in submission]
  4. Granular Hydrogels for Promoting Lymphatic Tube Sprouting. [in preparation] </aside>

<aside> <img src="/icons/square-two-fourths_green.svg" alt="/icons/square-two-fourths_green.svg" width="40px" /> R E C E N T P U B L I C A T I O N S

  1. Tuning the Morphological Properties of Granular Hydrogels to Control Lymphatic Capillary Formation Advanced Material Interfaces . April 24, 2025
  2. Robust Differentiation of Human Pluripotent Stem Cells into Lymphatic Endothelial Cells Using Transcription Factors Cells Tissues Organs · August 28, 2024
  3. Multi-parameter tunable synthetic matrix for engineering lymphatic vessels Communications Biology Communications Biology*· October 4, 2024*
  4. The Effects of Preeclamptic Milieu on Cord Blood Derived Endothelial Colony-Forming Cells ****bioRxiv · Dec 3, 2023
  5. Synthetic Hyaluronic Acid Coating Preserves the Phenotypes of Lymphatic Endothelial Cells Biomaterials Science · Sep 19, 2023
  6. Reduced Cell–ECM Interactions in the EpiSC Colony Center Cause Heterogeneous Differentiation Cells · Jan 15, 2023 </aside>

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U P C O M I N G

  1. Calcium Signaling and Membrane Potential Dynamics Govern iPSC-to-Endothelial Differentiation.
  2. Numerical Modeling of Fluid Exchange Between a Collecting Lymphatic Vessel and the Surrounding Tissue.
  3. Metabolically Driven iPSC Differentiation to Generate Robust and Functional Lymphatic Endothelial Cells.
  4. Synthetic Hyaluronic Acid Coating Enhances Lymphatic Endothelial Cell Maturation Response to Oscillatory Shear Stress.
  5. Enhancing the Targeting Efficacy of Endothelial Colony Forming Cells for Renal Regeneration via Kidney-Targeted Liposomal Nanoparticles. </aside>