Darrell Irvine

Darrell

J.

Irvine

Professor of Materials Science and Engineering & Biological Engineering

Investigator, Howard Hughes Medical Institute

B.S. Engineering Physics, University of Pittsburgh, 1995

Ph.D. Polymer Science and Technology, MIT, 2000

76-261

Phone:

(617) 452-4174

Fax:

(617) 452-3293

djirvine@mit.edu

The Irvine Lab

Disciplines:

Biotechnology
Nanotechnology
Polymers

Research:

The Irvine laboratory works at the interface of materials science and immunology. Synthetic materials can be applied in two major ways to 'immunobioengineering': (1) Synthetic materials can modulate the function of immune cells by mimicking signals derived from the immune system or foreign pathogens, both as a probe for cell function and as a tool for immunotherapy— both in vitro and in vivo; (2) Synthetic materials can be used to create in vitro and in vivo models of the microenvironment present in lymphoid and non-lymphoid tissues, to better understand immunobiology in health and disease. To meet these goals, engineering must be married to an in-depth appreciation for the biology of these problems. Their laboratory is thus deeply interdisciplinary in every project. Key to their approach is a balanced emphasis on both the engineering and immunological aspects of the problems the Irvine group has chosen to address: In each of these projects, state of the art chemistry, polymer science, physics and immunology are combined to address critical biological questions and medical challenges.

Converging on cancer at the nanoscale

Monday, July 10, 2017 - 2:15pm

This summer, the Koch Institute for Integrative Cancer Research at MIT marks the first anniversary of the launch of the Marble Center for Cancer Nanomedicine.

The Marble Center for Cancer Nanomedicine focuses on grand challenges in cancer detection, treatment, and monitoring that can...

Fighting cancer with the power of immunity

Wednesday, October 26, 2016 - 10:15am

Professor Darrell Irvine was a senior author alongside Dane Wittrup for a study published to the online edition of Nature Medicine on Oct. 24.

"Harnessing the body’s own immune system to destroy tumors is a tantalizing prospect that has yet to realize its full potential. However...

Prof. Irvine to speak at US Frontiers of Engineering

Friday, July 29, 2016 - 9:45am

Prof. Darrell Irvine has been selected to participate in the 2016 US Frontiers of Engineering Symposium in Irvine, CA this September from the 19th to the 21st.

Prof. Irvine will present a talk entitled "...

Materializing the Future of Vaccines and Immunotherapy

Monday, January 25, 2016 - 11:00am

The industries of immunotherapy and vaccination are on the brink of major breakthroughs, and many developments in the field are heavily focused on materials science. Safely modulating the immune system in patients with cancer is one of the biggest challenges at present, but developments in...

Microfluidic cell-squeezing device opens new possibilities for cell-based vaccines.

Friday, May 22, 2015 - 4:15pm

MIT researchers have shown that they can use a microfluidic cell-squeezing device to introduce specific antigens inside the immune system’s B cells, providing a new approach to developing and implementing antigen-presenting cell vaccines.

Such vaccines, created by reprogramming a patient’...

Professor Darrell Irvine named AIMBE Fellow

Wednesday, March 11, 2015 - 8:00pm

Darrell J Irvine To be Inducted into Medical and Biological Engineering Elite

WASHINGTON, D.C.— The American Institute for Medical and Biological Engineering (AIMBE) has announced the pending induction of Darrell J. Irvine, Ph.D., Professor of Biological Engineering and Materials Science...

Vaccine Delivery

Monday, February 17, 2014 - 7:00pm

Professor Darrell Irvine has published research on new vaccines that catch a ride to immune cell depots in order to help fight cancer and HIV. See the MIT...

Nanoparticle vaccine offers better protection

Wednesday, September 25, 2013 - 8:00pm

Particles that deliver vaccines directly to mucosal surfaces could defend against many infectious diseases. See the News Office for the full story.

Polymer films used in vaccinations

Sunday, January 27, 2013 - 7:00pm

A polymer film that gradually releases DNA coding for viral proteins could offer a better alternative to traditional vaccines; Professor Darrell Irvine and his collaborators are working on just such a technology. See the...

Prof. Irvine and colleagues are working on an AIDS vaccine

Thursday, October 18, 2012 - 8:00pm

Prof. Darrell Irvine and colleagues Darrell Irvine have received funding to break down silos of scientific disciplines to create an AIDS vaccine. Learn more from...

Lunch and Lecture, April 14, Prof. Darrell Irvine

Sunday, April 11, 2010 - 8:00pm

Combining cell therapy and nanoparticle drug delivery: Chemical cell surface engineering on live cells using nanoparticles
Darrell J. Irvine, Associate Professor of Materials Science and Engineering & Biological Engineering
Wednesday, April 14
12:...

Prof. Irvine profiled in Spectrum

Thursday, October 1, 2009 - 8:00pm

Spectrum, a magazine from the MIT Office of Resource Development, profiled Prof. Darrell J. Irvine and his work on new materials that help the immune system fight disease.

2016

Moynihan KD, Opel CF, Szeto GL, et al. Eradication of large established tumors in mice by combination immunotherapy that engages innate and adaptive immune responses. Nature Medicine. 2016;22(12):1402 - +.

Kimmerling RJ, Szeto GLee, Li JW, et al. A microfluidic platform enabling single-cell RNA-seq of multigenerational lineages. Nature Communications. 2016;7:10220.

Tzeng A, Kauke MJ, Zhu EF, et al. Temporally Programmed CD8 alpha(+) DC Activation Enhances Combination Cancer Immunotherapy. Cell Reports. 2016;17(10):2503 - 2511.

Tang L, Zheng Y, Mabardi L, Irvine DJ. Carrier-free delivery of cytokine to specifically expand adoptively transferred T cells for enhanced cancer immunotherapy. Cancer Immunology Research. 2016;4(1).

Griffiths KL, Ahmed M, Das S, et al. Targeting dendritic cells to accelerate T-cell activation overcomes a bottleneck in tuberculosis vaccine efficacy. Nature Communications. 2016;7:13894.

Kumari S, Poh Y, Melo M, et al. Specialized actin architecture mechanically tunes T cell synaptic contact lifetime. Molecular Biology of the Cell. 2016;27.

Irvine DJ. Materializing the future of vaccines and immunotherapy. Nature Reviews Materials. 2016;1(1):15008.

Moyer TJ, Zmolek AC, Irvine DJ. Beyond antigens and adjuvants: formulating future vaccines. Journal of Clinical Investigation. 2016;126(3):799 - 808.

Irvine DJ. A Receptor for All Occasions. Cell. 2016;164(4):599 - 600.

2015

Hotaling NA, Tang L, Irvine DJ, Babensee JE. Biomaterial Strategies for Immunomodulation. In: Yarmush ML Annual Review of Biomedical Engineering, Vol 17.Vol 17. Annual Review of Biomedical Engineering, Vol 17.; 2015:317 - 349.

Szeto GLee, Van Egeren D, Worku H, et al. Microfluidic squeezing for intracellular antigen loading in polyclonal B-cells as cellular vaccines. Scientific Reports. 2015;5:10276.

Atukorale PU, Yang Y-S, Bekdemir A, et al. Influence of the glycocalyx and plasma membrane composition on amphiphilic gold nanoparticle association with erythrocytes. Nanoscale. 2015;7(26):11420 - 11432.