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Dr. Leili Rouhani

Academic researcher in Stem Cell Engineering and Regenerative Medicine, affiliated with MIT (Boston) in a bioengineering context.

Scheduled reopening at the end of January 2026.

Contact Research Overview
Launch time uses Helsinki time (EET): 2026-01-31 23:59:59 +02:00

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About

A professional academic profile and central hub for research themes, selected publications, and contact details.

Dr. Leili Rouhani is a researcher in Stem Cell Engineering and Regenerative Medicine, with a focus on engineering cell fate and tissue function using quantitative bioengineering approaches. Her work integrates stem cell biology, biomaterials, and translational design to develop robust model systems and therapeutic strategies. This website will serve as an official reference point for academic record, collaborations, and public-facing research summaries.

Profile summary

  • Education
    Ph.D. in Bioengineering (placeholder); M.S./B.S. in related biomedical discipline (placeholder)
  • Current role
    Researcher at MIT (Boston), collaborating across bioengineering and regenerative medicine initiatives
  • Core expertise
    Stem cell platforms, biomaterials, organoid systems, quantitative assays, translational bioengineering

Research approach

  • Mechanistic and quantitative framing of cell-state transitions
  • Design of reproducible experimental platforms and benchmarks
  • Model-to-translation pathway planning (preclinical relevance)
  • Collaborative, interdisciplinary development and validation
Content is intentionally concise during maintenance; expanded materials will be available upon launch.

Research

Selected themes reflecting ongoing and prior work in stem cell engineering and regenerative medicine.

Bioengineering • Regenerative Medicine • Translation

Stem cell engineering

Engineering controllable microenvironments and cues to guide cell fate, maturation, and functional stability.

Biomaterials & matrices

Designing material interfaces that support reproducible cell behavior and enable quantitative perturbation studies.

Organoid and tissue models

Building organoid and engineered tissue systems to study development, disease mechanisms, and functional readouts.

Regenerative therapeutics

Translational strategies for repair and regeneration, focusing on safety, efficacy, and deployable workflows.

Quantitative bioengineering

Data-driven experimental design and analysis to improve reproducibility and interpretability across platforms.

Additional project summaries, figures, and collaboration notes will be published upon launch.

Publications (Selected)

Representative entries are provided during maintenance.

  1. Engineering tunable stem cell microenvironments for reproducible lineage commitment
    2025 — Placeholder Journal of Bioengineering
    2025
  2. Quantitative profiling of organoid maturation under defined biomaterial constraints
    2024 — Nature (placeholder)
    2024
  3. Biomaterial-guided control of stem cell state transitions: design principles and benchmarks
    2023 — Springer Series in Regenerative Medicine (placeholder)
    2023
  4. Scalable assay frameworks for evaluating regenerative therapeutics in engineered tissues
    2022 — Translational Bioengineering Reports (placeholder)
    2022
  5. Standardized metrics for functional maturation in stem cell-derived tissue models
    2021 — Journal of Regenerative Systems (placeholder)
    2021

Full list will be available upon launch.

Contact

For collaboration inquiries, speaking invitations, or academic correspondence.

leili.rouhani@mit.edu
LinkedIn Google Scholar ResearchGate

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