VANCOUVER and TORONTO, Canada (November 3, 2016) — Zucara Therapeutics Inc., a pre-clinical life sciences company advancing a novel long-term therapeutic approach to prevent hypoglycemia in patients with diabetes, announced…
Fanny Sie, MaRS Innovation’s head of imaging technologies, was quoted in Tanya Powley‘s article, “Printing whole organs remains a long way off,” for the U.K.’s Financial Times on June 11, 2015, regarding the technology’s potential to transform existing healthcare practices.
MI does wish to note that the article inaccurately attributes the PrintAlive device’s development to MaRS Innovation; MI is working with the University of Toronto inventing team, led by Dr. Axel Gunther, to commercialize the device.
Here’s a short excerpt:
Bioprinting could save pharmaceutical companies a lot of money, according to Fanny Sie of MaRS Innovation, a Toronto-based company. The company has developed the PrintAlive Bioprinter, which can print skin that could be used to treat people with large scale burns. The printed tissues could be used by pharmaceutical companies to test the toxicity of new drugs, and help them decide if it is worth starting costly animal and then human clinical trials.
TORONTO, ON (November 13, 2012) — The Ontario Institute for Cancer Research (OICR) and MaRS Innovation (MI) today announced $1.5 million in funding from OICR over three years to further develop Cellax™, a nanoparticle drug that could offer an alternative to chemotherapy with fewer side effects.
“Cellax is promising because it provides a more targeted strategy for treating tumours, killing tumour cells while minimizing the effect on healthy tissue,” said Dr. Rima Al-awar, director, OICR’s Medicinal Chemistry Platform. “OICR is proud to invest in a technology that has such potential to one day improve quality of life for cancer patients.”
Cellax, invented by Dr. Shyh-Dar Li and his research team in OICR’s Medicinal Chemistry Platform group, is a drug-polymer conjugate based on Dr. Li’s proprietary NanoCMC™ technology. These polymers self-assemble into defined nanoparticles and, when injected, selectively accumulate in tumours. Because of this property, the drug is released where it is most needed, increasing therapeutic benefits and reducing the side effects associated with conventional chemotherapy.