Will CRISPR succeed in curing disease?
ASU expert discusses challenges of new technology's clinical trials
Last week, scientists began the first human clinical trials using the gene-editing tool CRISPR to combat cancer and blood disorders. Researchers remove some of a person’s cells, edit the DNA, and then inject the cells back in, where hopefully they will cure the diseases.
The technology hit the world stage in 2012, with the promise of curing more than 6,000 known genetic diseases. Samira Kiani is a health systems engineer at Arizona State University, where her lab works on using CRISPR and synthetic biology to create safe and controllable CRISPR gene therapies.
ASU Now talked with Kiani, an assistant professor in the School of Biological and Health Systems Engineering, about the trials.
Question: Do scientists fully understand the changes they’re making?
Answer: What I gather from these clinical trials is obviously they are based on years of preclinical studies that have been done in itself and in the animal models. The targets they have chosen in the blood disorders, these are two monogenetic diseases. There have been many studies before using CRISPR to target these genes that are responsible for these diseases in the cells and in the animal models. The exact modification they want to do in these patients, yes, it’s well-studied. How this is going to affect patients — because this is the first clinical trial — obviously that’s something we all have to wait and see.
Q: What are some of the obstacles to success in these trials?
A: The very first obstacle is how efficiently you can modify these cells outside the patient body. You get these cells, you introduce CRISPR to them and then you really have to hope for really high efficiency in repairing the type of disease abnormality they have. Usually, as you can imagine, the efficiency (of CRISPR) to really cut the genome and repair the disease genes is not 100%. One obstacle is to increase this efficiency. People are doing work to increase that efficiency. Obviously we are not there yet.
The other obstacle is that once you have a number of cells edited, how can you expand those? How can you make sure you expand those outside the patient body? That expansion strategy is very much challenged right now, so a lot of people are working on that. We are not there yet.
Q: If these trials are successful, what’s next?
A: If these types of trials are successful, one of the major advances for CRISPR would be if we could avoid getting the cells and modifying them outside of the body, and really move forward and modify these cells inside the patient body. You can imagine it’s very costly and also time consuming to get these cells from the patient, expand them outside the body, modify them, and infuse them back, you really need to have a really special facility and a lot of money is involved. You really want to be able to put the CRISPR directly in the patient and see your intended changes. Some of the clinical trials are already intended for this purpose.
Top photo: Assistant Professor Samira Kiani poses for a portrait in her lab in the School of Biological and Health Systems Engineering. Photo by Deanna Dent/ASU Now
More Science and technology
Celebrating 34 years of space discovery with NASA
This year, NASA's Hubble Space Telescope (HST) is celebrating its 34th anniversary of the world's first space-based optical telescope, which paved the scientific pathway for NASA's James Webb Space…
Making magic happen: Engineering and designing theme parks
The themed entertainment industry is widespread and diverse, encompassing everything from theme parks to aquariums, zoos, water parks, museums and more. The Theme Park Engineering and Design…
AI-equipped feeders allow ASU Online students to study bird behavior remotely
ASU Online students are participating in a research opportunity that's for the birds — literally. Online Bird Buddies is a project that allows students to observe birds remotely, using bird feeders…