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  • 05/02/17 - 9:45 AM to 11:00 AM

    Dow Lecture Series: Professor Nathan Gianneschi

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    Department Seminar


    Dow Lecture Series

"Seek, Destroy and Heal: Enzyme-Responsive Nanoparticles as In Vivo Targeted Delivery Systems"

The goal of targeted therapeutics and molecular diagnostics is to accumulate drugs or probes at the site of disease in higher quantities relative to other locations in the body. To achieve this, there is tremendous interest in the development of nanomaterials capable of acting as carriers or reservoirs of therapeutics and diagnostics in vivo.[1] Generally, nanoscale particles are favored for this task as they can be large enough to function as carriers of multiple copies of a given small molecule, can display multiple targeting functionalities, and can be small enough to be safely injected into the blood stream. The general goal is that particles will either target passively via the enhanced permeability and retention (EPR) effect, actively by incorporation of targeting groups, or by a combination of both.[2] Nanoparticle targeting strategies have largely relied on the use of surface conjugated ligands designed to bind overexpressed cell-membrane receptors associated with a given cell-type.[3] We envisioned a targeting strategy that would lead to an active accumulation of nanoparticles by virtue of a supramolecular assembly event specific to tumor tissue, occurring in response to a specific signal. The most desirable approach to stimuli-induced targeting would be to utilize an endogenous signal, specific to the diseased tissue itself, capable of actively targeting materials introduced via intravenous (IV) injection. We present the development of nanoparticles capable of assembling in vivo in response to selective, endogenous, biomolecular signals. For this purpose, we utilize enzymes as stimuli, rather than other recognition events, because they are uniquely capable of propagating a signal via catalytic amplification. We will describe the preparation of highly functionalized polymer scaffolds utilizing ring opening metathesis polymerization, their development as in vivo probes and their utility as a multimodal imaging platform and as drug carriers capable of targeting tissue via a new mechanism. Furthermore, we will describe new methods and approaches for characterizing this kind of dynamic material at the nanoscale, including by liquid cell transmission electron microscopy and combined isotopic and optical nanoscopy.


  1. J. A. Hubbell, A. Chilkoti, Science, 337, 303-305.
  2. a) Y. Matsumura, H. Maeda, Cancer Res 1986, 46, 6387-6392; b) D. Peer, J. M. Karp, S. Hong, O. C. Farokhzad, R. Margalit, R. Langer, Nat. Nanotechnol. 2007, 2, 751-760.
  3. a) W. Arap, R. Pasqualini, E. Ruoslllahti, Science 1998, 279, 377-380; b) D. Pan, J. L. Turner, K. L. Wooley, Chem. Commun. 2003, 2400-2401; c) A. R. Hilgenbrink, P. S. Low, J. Pharm. Sci. 2005, 94, 2135-2146
Professor Nathan Gianneschi's seminar abstract graphic

Research interests

Professor Gianneschi's research is focused on the ability to control the assembly and destruction of nanoscale materials in response to specific biomolecular stimuli is expected to have a significant impact in targeted drug delivery and advanced sensor design. His research program takes a multidisciplinary approach to the development of novel, stimuli responsive supramolecular and nanoscale materials by combining synthetic organic and inorganic chemistry with biological molecules and polymers. A set of strategies is being developed to incorporate enzymes, proteins, peptides and nucleic acids into novel polymeric synthetic materials with the aim of programming morphology and function. Together, these efforts involve a concerted effort to develop bioresponsive, and bioactive chemical systems through innovations in synthesis and characterization of dynamic systems at multiple length and time scales. 

  • Event Details

    Location: 331 Smith Hall
    Host: Professor Marc Hillmyer
    • Professor Nathan Gianneschi
    • Nathan Gianneschi
    • Department of Chemistry & Biochemistry
    • University of California, San Diego

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