Scientist profiles A-F

Administrative Assistant: Ram Mohabir
Phone: 416-480-6128
Fax: 416-480-6002
Email: ram.mohabir@sunnybrook.ca

Education:

• B.Sc., 1991, biochemistry, McMaster University, Canada
• PhD, 1995, medical biophysics, University of Toronto, Canada
• MD, 2000, University of Toronto, Canada

Appointments and Affiliations:

• Senior scientist, Physical Sciences, Odette Cancer Research Program, Sunnybrook Research Institute
• Radiation oncologist, Sunnybrook Health Sciences Centre
• Associate professor, departments of radiation oncology and medical biophysics, University of Toronto

Research Foci:

• Ultrasound imaging
• Spectroscopy of cancer therapy responses

Research Summary:

Dr. Czarnota is conducting research focused on using ultrasound imaging and spectroscopy at conventional and high frequencies to detect apoptosis and other forms of cell death in response to chemotherapy and radiation therapy. In addition to being a scientist in the imaging discipline he is an MD in the department of radiation oncology with applied research in breast cancer patients. His basic science research interests include studies in biochemistry, chromatin biology, biophysics, medicine and oncology.

Dr. Czarnota, along with his collaborator Dr. Michael Kolios, discovered that ultrasound could be used to detect apoptosis. This finding has since been applied to important questions in oncology and organ transplantation. Our research group has demonstrated that this special form of cell death may be detected using ultrasound imaging and spectroscopy in vitro, in situ, and in vivo. The use of ultrasound to detect apoptosis and other forms of cell death has numerous applications listed below.

Cell and molecular biology:

Despite the use of medical ultrasound for decades, the features inside cells that contribute to ultrasound backscatter at conventional and high frequencies remain unknown. We are systematically probing how subcellular constituents such as DNA, RNA, protein and lipids contribute to backscatter. In particular we are interested in how nuclear and chromatin structure affects ultrasound signals since we have found it to be a dominant structure in the formation of backscatter signals.

Image and spectroscopic analysis:

We are collaboratively investigating a number of spectroscopic parameters for characterizing tumours and tumour responses to chemotherapy and radiation therapy at conventional and high frequencies. We are developing these methods to generate colour-coded ultrasound parameteric maps to aid in assessing tumour responses to therapy. Since these spectroscopic signals are potentially linked to nuclear structure and chromatin structure which differs between normal and neoplastic tissue there is potential to develop our spectroscopic methods not only into a method to track tumour responses but a potentially important diagnostic tool.

Clinical evaluations of ultrasound imaging and spectroscopy:

We are instituting a number of clinical evaluations of our spectroscopic detection of cell death. Our main investigational site is breast cancer patients with large “locally advanced” breast cancers who receive neoadjuvant combined chemotherapy and radiation therapy. We hope to rapidly distinguish responding tumours from those that are non-responding so that the latter may be treated with different chemotherapy regimens or with radiation sensitizers to hopefully improve outcomes.

Selected Publications:

See current publications list at PubMed.

1. Tunis AS, Czarnota GJ, Giles A, Sherar MD, Hunt JW and Kolios MC. Monitoring structural changes in cells with high frequency ultrasound signal statistics. Ultrasound Med Biol. 2005 Aug; 31(8):1041–1049.
2. Czarnota GJ. Role of ultrasound in the detection of apoptosis. Eur J Nucl Med Mol Imaging. 2005 May; 32(5):622–632.
3. Kolios MC, Czarnota GJ, Lee M, Hunt JW, Sherar MD. Ultrasonic spectral parameter characterization of apoptosis. Ultrasound Med Biol. 2002 May; 28(5): 589–597.
4. Czarnota GJ, Kolios M, Abraham J, Portnoy M, Sherar MD, Ottensmeyer FP and Hunt JW. Ultrasound imaging of apoptosis: high resolution non-invasive monitoring of programmed cell death in vitro, in situ, and in vivo. Br J Cancer. 1999 Oct; 81(3):520–527.
5. Czarnota GJ, Kolios M, Vaziri H, Benchimol S, Ottensmeyer FP and Hunt JW. Ultrasound biomicroscopy of living, dead, and apoptotic cells. Ultrasound Med Biol. 1997; 23(6):961–965.

Related News and Stories:

• A cut above: Amid funding pressures, SRI scientists post stellar results (Feb. 1, 2019)
• Will ultrasound be used one day to diagnose breast cancer?: Inexpensive imaging technique shows high potential to provide early, precise and noninvasive "acoustic" biopsy (SRI Magazine, 2018)
• Closing in on clinical impact: Researcher’s ultrasound work will culminate in first-in-human precision medicine studies (June 8, 2018)
• Resounding approval: Sunnybrook Research Institute's success rate in CIHR competition soars past national average (Jan. 25, 2018)
• A measured approach: researchers test use of quantitative ultrasound-based tool to detect cancer (Dec. 13, 2017)
• Pioneering science rewarded: Canada Foundation for Innovation invests in image-guided therapeutics research (Oct. 12, 2017)
• Echoes of success: Ultrasound-based imaging technique aims to personalize cancer care (Oct. 3, 2017)
• Magnifying innovation: Conferences put next-generation cancer care in plain view (Nov. 22, 2016)
• Individualizing breast cancer therapy: New technologies can deliver highly specific information about a therapy’s effectiveness in days, not months; and help women with DCIS decide on the best course of action (SRI Magazine, 2016)
• Hi-dose re-irradiation helps breast cancer patients who have limited options (Sunnybrook-led report published in Oncotarget, Oct. 16, 2015)
• Terry Fox Foundation supports cancer research: Funding for quantitative ultrasound research for more tailored cancer treatment (Sept. 11, 2014)
• Crowdfunding success for cancer innovation: WaveCheck raises $20,000 in first day through online donations (Oct. 10, 2013),
• Competition spurs high scores: Scientists secure funding with federal agency (July 25, 2013)
• Discoverers' recompense: Scientists recognized for innovation in prostate cancer research (July 18, 2013)
• New use of ultrasound enhances radiation: Research points to bigger treatment impact at lower radiation doses (July 10, 2012)
• In Focus: Image-Guided Sound Waves Will Change Medicine, Here's How (SRI Magazine, 2010)
• Smarter, Faster, Better: On the Horizon Innovations in Cancer Care (SRI Magazine, 2009)
• Crowning Tomorrow's Medical Scientists: Annual project competition highlights research talent of SRI's summer students (Aug. 26, 2009)
• Science and Tech Students Lauded: Ontario Graduate Scholarship recognizes science and technology excellence (Dec. 7, 2007)
• Translation in Collaboration - Sunnybrook plans a novel breast cancer treatment (Sunnybrook Research Institute Research Report, 2004-2006)

Related Links:

• U of T profile, department of medical biophysics
• SRI Centre of Excellence in Focused Ultrasound