The goal of this K99/R00 proposal is to develop a new translational research framework whereby the role of the mechanical properties in tumor growth and molecular response are specifically exploited to design new photodynamic therapy (PDT) combination treatments for pancreatic cancer. Previous studies have shown that while the rigidity of the extracellular matrix surrounding cells directly impacts growth, development and signaling, the relevance of this crucial factor to treatment response has not yet been explored. This is particularly relevant for tumors of the pancreas which are characterized by a profound growth of dense fibrous tissue around the tumor (called desomplasia). In order to overcome this limitation in our scientific knowledge, this proposal introduces a highly interdisciplinary approach combining 1) fluorescence laser tracking microrheometry (FLTM) a novel optical technology to measure the mechanical properties (microrheology) in and around tumors, 2) a customizable three-dimensional (3D) tumor model system using a synthetic nanofiber scaffold called PuraMatrix"""""""" with tunable matrix mechanics, 3) a high-throughput quantitative imaging approach to report tumor growth properties and treatment response in relation to matrix mechanical properties. Dr. Celli will first optimize the 3D model system informed by studies on ex vivo tumors from orthotopic PanCa mice, to assess the impact of matrix rheology (measured by FLTM and traditional bulk rheology) on growth and development of 3D in vitro tumors. He will conduct PDT treatments and specific survival factors as potential targets for mechanism based combination treatments that are customized to each synthetic mechanical microenvironment. He will then evaluate the efficacy of the most promising combination treatments to test the hypothesis that only a treatment customized for the appropriate mechanical microenvironment will in fact achieve a synergistically enhanced efficacy in that environment. The research will culminate in testing of the most promising strategies in a mouse model of pancreatic cancer. If successful, this research will not only produce urgently needed new treatments for a deadly disease, but will also add a new level of understanding to guide the design of future treatments which could be applied to the study of other tumors. A mentoring committee has been assembled to guide the research in the K99 phase and facilitate Dr. Celli's training. Dr. Tayyaba Hasan, who is an expert in PDT treatment of cancer will provide primary mentorship and guidance in the overall study design. Co-Mentor, Dr. Peter So is a world expert in novel imaging technologies. He will guide Dr. Celli in FLTM measurements (which was developed in his laboratory) and help interpret results. Training in the molecular biology and treatment of pancreatic cancer will be provided by Dr. Nabeel Bardeesy and Dr. Stephen Pereira. Dr. Gareth McKinley will provide additional mentorship in rheology and microrheology. The opportunities provided by this award will not only allow Dr. Celli to pursue potentially ground-breaking research, but will also provide him with valuable mentorship and training to his career as an independent investigator.
The proposed research is directly relevant to the treatment of pancreatic cancer with potentially broader application to other solid tumors. This work will shed new light on how the mechanical properties of the tumor stroma can guide the design of more effective therapeutic strategies. In the present study this concept will specifically be leveraged to design enhanced photodynamic therapy combination treatments which, upon translation into the clinic, could have a direct impact on survival and quality of life for patients with this lethal form of cancer.
|Broekgaarden, Mans; Rizvi, Imran; Bulin, Anne-Laure et al. (2018) Neoadjuvant photodynamic therapy augments immediate and prolonged oxaliplatin efficacy in metastatic pancreatic cancer organoids. Oncotarget 9:13009-13022|
|Chen, Hao; He, Juan; Lanzafame, Raymond et al. (2017) Quantum dot light emitting devices for photomedical applications. J Soc Inf Disp 25:177-184|
|Cramer, Gwendolyn M; Jones, Dustin P; El-Hamidi, Hamid et al. (2017) ECM Composition and Rheology Regulate Growth, Motility, and Response to Photodynamic Therapy in 3D Models of Pancreatic Ductal Adenocarcinoma. Mol Cancer Res 15:15-25|
|Ouyang, Zi; Mainali, Madan Kumar; Sinha, Neeharika et al. (2016) Potential of using cerium oxide nanoparticles for protecting healthy tissue during accelerated partial breast irradiation (APBI). Phys Med 32:631-5|
|Mallidi, Srivalleesha; Mai, Zhiming; Rizvi, Imran et al. (2015) In vivo evaluation of battery-operated light-emitting diode-based photodynamic therapy efficacy using tumor volume and biomarker expression as endpoints. J Biomed Opt 20:048003|
|Hempstead, Joshua; Jones, Dustin P; Ziouche, Abdelali et al. (2015) Low-cost photodynamic therapy devices for global health settings: Characterization of battery-powered LED performance and smartphone imaging in 3D tumor models. Sci Rep 5:10093|
|Jones, Dustin P; Hanna, William; El-Hamidi, Hamid et al. (2014) Longitudinal measurement of extracellular matrix rigidity in 3D tumor models using particle-tracking microrheology. J Vis Exp :|
|Celli, Jonathan P; Rizvi, Imran; Blanden, Adam R et al. (2014) An imaging-based platform for high-content, quantitative evaluation of therapeutic response in 3D tumour models. Sci Rep 4:3751|
|Li, Yuyu; Petrovic, Ljubica; La, Jeffrey et al. (2014) Digital holographic microscopy for longitudinal volumetric imaging of growth and treatment response in three-dimensional tumor models. J Biomed Opt 19:116001|
|Anbil, Sriram; Rizvi, Imran; Celli, Jonathan P et al. (2013) Impact of treatment response metrics on photodynamic therapy planning and outcomes in a three-dimensional model of ovarian cancer. J Biomed Opt 18:098004|
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