University of California San Francisco

Dr. Tammy Chang large headshot
Tammy T.
Chang
MD, PhD

Professor of Surgery
Division of General Surgery

 

Address

513 Parnassus Avenue, HSW, #1607
San Francisco, CA 94143
United States

Email: [email protected]
Phone: 415-502-0339
Fax: 415-476-8694

Biography

Tissue engineering and regeneration are the next evolutionary step in surgical practice. Today, surgeons resect, reconstruct, and transplant to treat a diverse array of diseases. In the near future, our armamentarium will increase to include using our surgical skills to induce tissue regeneration in situ or to implant ex vivo engineered organs. Accelerating advances in biotechnology, stem cell biology, and minimally invasive surgery are ripe for convergence, which will lead to the creation of novel surgical treatments to replace diseased or dysfunctional tissues. Our lab's goal is to make significant contributions to bringing these regenerative surgical therapies from the lab into the operating room.

In order to translate regenerative surgery from concept to therapeutic reality, our lab focuses on a complex and vital solid organ, the liver, for several reasons. First, there is great clinical need to develop alternative therapies for end stage liver disease, which is currently treated by liver transplantation and severely limited by the shortage of donor organs. Second, the liver has enormous innate capacity to regenerate in response to injury and metabolic demand, a feature that can be exploited to facilitate development of regenerative surgical approaches. Finally, building a solid organ such as the liver ex vivo remains the most challenging goal in tissue engineering and a problem of sufficient difficulty that is worthy of intense focus.

Our lab has 3 major areas of investigation aimed at advancing the field of liver tissue engineering:

1) Understanding the role of the physical environment and mechano-signal transduction in regulating hepatocyte function in healthy and diseased liver.
2) Elucidating the importance of dimensionality in promoting the generation of highly-functional human stem cell-derived liver organoids.
3) Developing surgical strategies for efficient orthotopic engraftment of hepatocytes and hepatic organoids into the liver.

Education

Education

1990-1992, California State University, Los Angeles, Early Entrance Program
1992-1994, University of California, Los Angeles, Bachelor of Science, Biology
1994-2003, Harvard Medical School and Harvard Graduate School of Arts and Sciences, M.D., Ph.D. Combined Degree

Residencies

2003-2004 University of California, San Francisco, Surgery, Intern
2004-2009 University of California, San Francisco, Surgery, Resident
2009-2010 University of California, San Francisco, Surgery, Chief Resident

Board Certifications

American Board of Surgery

Collaboration Interests

I am interested in:

  • physician scientist

Clinical Expertise

Hernia Repair
Complex Abdominal Surgery
Recurrent Hernia
Laparoscopic Inguinal Hernia Repair
Gastrointestinal Cancer
Intra-abdominal Sepsis
Pancreas Surgery
Soft Tissue Infections
Enterocutaneous Fistula

Program Affiliations

Gastrointestinal Surgery
Acute Care Surgery Program
UCSF Liver Center

Grants and Funding

  • The Role of Matrix Rigidity and Hepatocyte Mechanotransduction in Fibrotic Liver Disease | NIH | 2017-07-15 - 2022-06-30 | Role: Principal Investigator
  • Defining the mechanism of function and engraftment potential of human hepatocyte organoids | American College of Surgeons | 2017-07-01 - 2022-06-30 | Role:
  • Liver tissue engineering in space | NSF/CASIS | 2018-09-01 - 2021-08-31 | Role: Principal Investigator
  • Pioneering regenerative surgery - Mechanisms of cell death and regeneration in liver treated with non-thermal irreversible electroporation (NTIRE) | NIH | 2018-01-01 - 2020-12-31 | Role: Principal Investigator
  • Using organoids to determine gravity effects on organogenesis and vasculogenesis | NASA | 2018-09-01 - 2020-08-31 | Role: Principal Investigator
  • Innovating a method of in situ decellularization followed by organoid engraftment | Open Philanthropy Project | 2017-07-01 - 2020-06-30 | Role: PI

Research Narrative

Liver transplantation is currently the only treatment for patients with end-stage liver disease (ESLD), which is the 12th leading cause of death by disease in the U.S.  The shortage of donor organs remains a major treatment limitation.  Alternatives such as hepatocyte transplantation have shown promise in treating metabolic liver disorders, but low engraftment efficiency and poor long-term efficacy are barriers to broader clinical application.

Another strategy that holds great promise is ex vivo tissue engineering of a functional liver unit that can be implanted and then induced to further expand by host factors after incorporation.  Progress towards building three-dimensional (3D) tissue structure with biocompatible scaffolds has been hindered because these materials prevent normal cell-cell and cell-to-extracellular matrix (ECM) interactions.

The slow scaffold degradation rates also prevent remodeling and vascularization of the implant by the local host milieu. Moreover, it is increasingly clear that the surrounding environment is critically important for the durable function of hepatocytes. In particular, evidence shows that three factors independently improve and prolong primary hepatocyte differentiated functions ex vivo: 1) contact with ECM, 2) interaction with stromal cells (fibroblasts and endothelium), and 3) 3D cell-cell contact.

Dr. Chang's previous work showed that hepatocytes cultured in solid-body rotational bioreactors, which provide minimal shear stress with maximal 3D spatial freedom, produced self-aggregated spheroids with optimal metabolic and synthetic gene expression and function as compared to those cultured in two-dimensional (2D) monolayers.

Research in the The Chang Laboratory for Liver Tissue Engineering builds upon those observations and aims to generate "micro-liver-tissues" with endogenous ECM scaffolds and built-in microvascular networks through co-culture of hepatocytes with stromal cells within solid-body rotational bioreactors. Findings from this research are expected advance the field of tissue engineering by increasing our understanding of hepatocyte cellular response to matrix composition and heterotypic 3D cell contact. It will form the basis for the long-term goal of creating ex vivo engineered liver tissue for therapeutic implantation in patients with ESLD.

Research Interests

Liver Tissue Engineering

Publications

MOST RECENT PUBLICATIONS FROM A TOTAL OF 35
  1. Hepatocyte Rho-associated kinase signaling is required for mice to survive experimental porphyria-associated liver injury.
    Herrera JM, Weng Y, Lieberthal TJ, Paoletti M, Chang TT| | PubMed
  2. Metastatic melanoma to small bowel: metastasectomy is supported in the era of immunotherapy and checkpoint inhibitors.
    Wong P, Wisneski AD, Tsai KK, Chang TT, Hirose K, Nakakura EK, Daud AI, Maker AV, Corvera CU| | PubMed
  3. Irreversible Electroporation of the Liver Increases the Transplant Engraftment of Hepatocytes.
    Han S, Dicker ML, Lopez-Ichikawa M, Vu NK, Rubinsky B, Chang TT| | PubMed
  4. Isochoric Supercooling Organ Preservation System.
    Nastase G, Botea F, Be?chea GA, Câmpean ?I, Barcu A, Neac?u I, Herlea V, Popescu I, Chang TT, Rubinsky B, ?erban A| | PubMed
  5. An exploratory study on isochoric supercooling preservation of the pig liver.
    Botea F, Nastase G, Herlea V, Chang TT, ?erban A, Barcu A, Rubinsky B, Popescu I| | PubMed
  6. Self-Assembled Matrigel-Free iPSC-Derived Liver Organoids Demonstrate Wide-Ranging Highly Differentiated Liver Functions.
    Weng Y, Han S, Sekyi MT, Su T, Mattis AN, Chang TT| | PubMed
  7. Pancreatic islets implanted in an irreversible electroporation generated extracellular matrix in the liver.
    Zhang Y, Lv Y, Wang Y, Chang TT, Rubinsky B| | PubMed
  8. Self-assembled Matrigel-free iPSC-derived liver organoids demonstrate wide-ranging highly-differentiated liver functions
    Yun Weng, Simon Han, Maria T Sekyi, Tao Su, Aras N Mattis, Tammy T Chang| | UCSF Research Profile
  9. Neutrophils are important for the development of pro-reparative macrophages after irreversible electroporation of the liver in mice.
    Lopez-Ichikawa M, Vu NK, Nijagal A, Rubinsky B, Chang TT| | PubMed
  10. Focal adhesion kinase (FAK) promotes cholangiocarcinoma development and progression via YAP activation.
    Song X, Xu H, Wang P, Wang J, Affo S, Wang H, Xu M, Liang B, Che L, Qiu W, Schwabe RF, Chang TT, Vogl M, Pes GM, Ribback S, Evert M, Chen X, Calvisi DF| | PubMed
35
View all 35 Publications
MOST RECENT PUBLICATIONS FROM A TOTAL OF 35
  1. Hepatocyte Rho-associated kinase signaling is required for mice to survive experimental porphyria-associated liver injury.
    Herrera JM, Weng Y, Lieberthal TJ, Paoletti M, Chang TT| | PubMed
  2. Metastatic melanoma to small bowel: metastasectomy is supported in the era of immunotherapy and checkpoint inhibitors.
    Wong P, Wisneski AD, Tsai KK, Chang TT, Hirose K, Nakakura EK, Daud AI, Maker AV, Corvera CU| | PubMed
  3. Irreversible Electroporation of the Liver Increases the Transplant Engraftment of Hepatocytes.
    Han S, Dicker ML, Lopez-Ichikawa M, Vu NK, Rubinsky B, Chang TT| | PubMed
  4. Isochoric Supercooling Organ Preservation System.
    Nastase G, Botea F, Be?chea GA, Câmpean ?I, Barcu A, Neac?u I, Herlea V, Popescu I, Chang TT, Rubinsky B, ?erban A| | PubMed
  5. An exploratory study on isochoric supercooling preservation of the pig liver.
    Botea F, Nastase G, Herlea V, Chang TT, ?erban A, Barcu A, Rubinsky B, Popescu I| | PubMed
  6. Self-Assembled Matrigel-Free iPSC-Derived Liver Organoids Demonstrate Wide-Ranging Highly Differentiated Liver Functions.
    Weng Y, Han S, Sekyi MT, Su T, Mattis AN, Chang TT| | PubMed
  7. Pancreatic islets implanted in an irreversible electroporation generated extracellular matrix in the liver.
    Zhang Y, Lv Y, Wang Y, Chang TT, Rubinsky B| | PubMed
  8. Self-assembled Matrigel-free iPSC-derived liver organoids demonstrate wide-ranging highly-differentiated liver functions
    Yun Weng, Simon Han, Maria T Sekyi, Tao Su, Aras N Mattis, Tammy T Chang| | UCSF Research Profile
  9. Neutrophils are important for the development of pro-reparative macrophages after irreversible electroporation of the liver in mice.
    Lopez-Ichikawa M, Vu NK, Nijagal A, Rubinsky B, Chang TT| | PubMed
  10. Focal adhesion kinase (FAK) promotes cholangiocarcinoma development and progression via YAP activation.
    Song X, Xu H, Wang P, Wang J, Affo S, Wang H, Xu M, Liang B, Che L, Qiu W, Schwabe RF, Chang TT, Vogl M, Pes GM, Ribback S, Evert M, Chen X, Calvisi DF| | PubMed
  11. Jejunal prolapse and incarceration following feeding tube exchange.
    Conroy PC, Colley A, Bongiovanni T, Chang TT, Harris H| | PubMed
  12. Liver epithelial focal adhesion kinase modulates fibrogenesis and hedgehog signaling.
    Weng Y, Lieberthal TJ, Zhou VX, Lopez-Ichikawa M, Armas-Phan M, Bond TK, Yoshida MC, Choi WT, Chang TT| | PubMed
  13. Intra-Vital Imaging Demonstrates Robust Recruitment of Neutrophils after Irreversible Electroporation Tissue Ablation.
    Maya A. Lopez-Ichikawa, Tammy T. Chang| | UCSF Research Profile
  14. Normal and fibrotic liver parenchyma respond differently to irreversible electroporation.
    Lyu C, Lopez-Ichikawa M, Rubinsky B, Chang TT| | PubMed
  15. Liver Fibrosis: Current Approaches and Future Directions for Diagnosis and Treatment.
    Jennifer Y. Chen, Dhruv Thakar, Tammy T. Chang| | UCSF Research Profile
  16. Molecular and histological study on the effects of non-thermal irreversible electroporation on the liver.
    Zhang Y, Lyu C, Liu Y, Lv Y, Chang TT, Rubinsky B| | PubMed
  17. Using non-thermal irreversible electroporation to create an in vivo niche for exogenous cell engraftment.
    Chang TT, Zhou VX, Rubinsky B| | PubMed
  18. Reply.
    Chang TT| | PubMed
  19. Direct orthotopic implantation of hepatic organoids.
    Zhou VX, Lolas M, Chang TT| | PubMed
  20. Force-dependent breaching of the basement membrane.
    Chang TT, Thakar D, Weaver VM| | PubMed
  21. Hepatic Focal Adhesion Kinase Signaling Modulates Development of Liver Fibrosis.
    Tammy T. Chang, Vivian X. Zhou| | UCSF Research Profile
  22. Gastrointestinal Zygomycosis Masquerading as Acute Appendicitis.
    Choi WT, Chang TT, Gill RM| | PubMed
  23. Physiological ranges of matrix rigidity modulate primary mouse hepatocyte function in part through hepatocyte nuclear factor 4 alpha.
    Desai SS, Tung JC, Zhou VX, Grenert JP, Malato Y, Rezvani M, Español-Suñer R, Willenbring H, Weaver VM, Chang TT| | PubMed
  24. Spaceflight alters expression of microRNA during T-cell activation.
    Hughes-Fulford M, Chang TT, Martinez EM, Li CF| | PubMed
  25. Spaceflight impairs antigen-specific tolerance induction in vivo and increases inflammatory cytokines.
    Chang TT, Spurlock SM, Candelario TL, Grenon SM, Hughes-Fulford M| | PubMed
  26. Molecular mechanisms underlying the enhanced functions of three-dimensional hepatocyte aggregates.
    Chang TT, Hughes-Fulford M| | PubMed
  27. The Rel/NF-κB pathway and transcription of immediate early genes in T cell activation are inhibited by microgravity.
    Chang TT, Walther I, Li CF, Boonyaratanakornkit J, Galleri G, Meloni MA, Pippia P, Cogoli A, Hughes-Fulford M| | PubMed
  28. Monolayer and spheroid culture of human liver hepatocellular carcinoma cell line cells demonstrate distinct global gene expression patterns and functional phenotypes.
    Chang TT, Hughes-Fulford M| | PubMed
  29. Caudate split for open and laparoscopic liver resections.
    Chang TT, Corvera CU| | PubMed
  30. Implementation of a multidisciplinary treatment team for hepatocellular cancer at a Veterans Affairs Medical Center improves survival.
    Chang TT, Sawhney R, Monto A, Davoren JB, Kirkland JG, Stewart L, Corvera CU| | PubMed
  31. Injury in the elderly and end-of-life decisions.
    Chang TT, Schecter WP| | PubMed
  32. Recovery from EAE is associated with decreased survival of encephalitogenic T cells in the CNS of B7-1/B7-2-deficient mice.
    Chang TT, Sobel RA, Wei T, Ransohoff RM, Kuchroo VK, Sharpe AH| | PubMed
  33. Genetic background determines the requirement for B7 costimulation in induction of autoimmunity.
    Jabs C, Greve B, Chang TT, Sobel RA, Sharpe AH, Kuchroo VK| | PubMed
  34. Antigen-specific regulatory T cells develop via the ICOS-ICOS-ligand pathway and inhibit allergen-induced airway hyperreactivity.
    Akbari O, Freeman GJ, Meyer EH, Greenfield EA, Chang TT, Sharpe AH, Berry G, DeKruyff RH, Umetsu DT| | PubMed
  35. Role of the B7-CD28/CTLA-4 pathway in autoimmune disease.
    Chang TT, Kuchroo VK, Sharpe AH| | PubMed