Paving the way for hyper-accurate cancer treatments

A collection of microscopic cancer cells

Radiopharmaceuticals are an emerging medical technology that deliver radiation therapy directly to cancer cells while sparing the rest of the body from the harsh effects of cancer treatment.

And now The University of Queensland is taking a leading role in the innovation and production of new radiation therapy drugs.

The newly created Advanced Manufacture of Targeted Radiopharmaceuticals (AMTAR) hub, established from a $5 million Australian Research Council grant and $10 million from partners, will be a one-stop-shop for experts and industry to come together and streamline emerging radiopharmaceutical technologies.

Professor Kris Thurecht working in a laboratory wearing safety goggles and a lab coat

Professor Kris Thurecht from UQ's AIBN

Professor Kris Thurecht from UQ's AIBN

Professor Kris Thurecht from UQ’s Australian Institute for Bioengineering and Nanotechnology and Centre for Advanced Imaging will lead the hub, alongside crucial pharma industry partners and some of the world’s best scientific minds.

He had a chat with UQ News to share his take on the project and the incredible opportunities ahead.

Okay Professor, radiopharmaceuticals. Give us the basics.

So, we’re talking about a group of drugs that deliver radiation therapy directly and specifically to cancer cells. If you want to get scientific, radiopharmaceuticals are isotopes bound to biological molecules that can target specific organs, tissues or cells.

By focusing on very specific areas, we can reduce the collateral damage – or side effects – that the human body usually experiences during radiation therapy like hair loss, skin changes, diarrhoea and loss of taste.

A graphic illustration of a spaceship carrying therapeutics flying towards cancer cells

Radiopharmaceuticals are an emerging medical technology that deliver radiation therapy directly to cancer cells.

Radiopharmaceuticals are an emerging medical technology that deliver radiation therapy directly to cancer cells.

So... it’s kind of like the Fantastic Voyage? A tiny crew travelling through the body to the area that needs attention?

I suppose so! Although probably minus the shrink-ray technology, submarines and Cold War intrigue.

Still, radiopharmacueticals are very much a microscopic ally working inside the body. They make a beeline to the problem area, sparing other parts of the body from the effects of cancer treatment.

Is this a new concept? How long have radiopharmaceuticals been around?

They can be traced right back to the 1920s, but radiopharmaceuticals are still considered an emerging branch of medical technology. We’re definitely using them more as we get better at understanding, diagnosing and treating diseases like cancer with high accuracy and sensitivity.

It’s clear radiopharmaceuticals will be an integral part of modern healthcare. There are several agents on the market, and many more in development. We’re going to be seeing them used a lot more over the coming 10 to 15 years.

Robotic arms holding a small tube in a lab

Centre for Advanced Imaging's radiochemistry facilities.

Centre for Advanced Imaging's radiochemistry facilities.

A radiochemistry machine with several tubes attached

Centre for Advanced Imaging's radiochemistry facilities.

Centre for Advanced Imaging's radiochemistry facilities.

Is it true that radiopharmaceuticals have been used to treat animals?

It is true! In 2018 myself and a team at AIBN used radiopharmaceuticals to treat a 10-year-old beagle, ‘Hoover’, that had prostate cancer.

Hoover was the first patient in the world to be given that particular nanomedicine. Like humans, dogs naturally develop prostate cancer and so Hoover was an important part of helping us better understand how we can track and treat the disease.

Hoover the beagle

Hoover the beagle.

Hoover the beagle.

A scientist looking at scans on a computer

Scientists examine Hoover the beagle's scans.

Scientists examine Hoover the beagle's scans.

Tell us about the new AMTAR hub at UQ. What is it and who’s involved?

In July we secured a $5 million Australian Research Council grant, which has allowed us to establish the Hub for Advanced Manufacture of Targeted Radiopharmaceuticals (AMTAR) at UQ. Essentially, the hub will use the capabilities and infrastructure on hand at UQ and the University of Sydney to bring together some of the world’s best scientific minds and major pharma industry players.

We won’t expressly be treating patients or addressing medical outcomes, but we’ll be developing knowledge and technology platforms within the radiopharmaceutical manufacturing pipeline. Basically, the hub’s a one-stop shop that will help enhance Australia’s reputation in the field of radiopharmaceuticals, and importantly, open us up to lucrative commercial opportunities.

So you’re strengthening the radiopharmaceuticals pipeline?

Yes, I suppose you could say that. AMTAR’s vision is to develop new technologies and establish a platform for smart-design, manufacture and quality assurance of targeted radiopharmaceuticals. We’ll do this through collaborative research that improves the cost-effectiveness of production while ensuring there’s a process in place to manufacture new products here in Australia.

Radiochemistry machine

Centre for Advanced Imaging's radiochemistry facilities, to be utilised by the AMTAR Hub.

Centre for Advanced Imaging's radiochemistry facilities, to be utilised by the AMTAR Hub.

The commercial opportunities sound pretty big!

Absolutely. A big part of our work will be assessing how radiopharmaceutical design and development can enhance commercial opportunities. Australia’s already a recognised incubator of early-stage innovation in the biotechnology sector, and this will further our position as a leader.

We have a chance to enhance Australia’s international reputation in pharmaceuticals and medical technologies and lift our nation’s prosperity in the next decades.

Media: Alex Druce, a.druce@uq.edu.au, +61 (0)447 305 979