Our resource hub is home to a wealth of articles, stories and videos about managing and living with type 1 diabetes.
Place your order for our free information packs that support adults and children who have been recently diagnosed.
Our researchers are working on different ways to develop a cure for type 1 diabetes - from growing insulin-producing beta cells in labs to hacking the immune system.
Learn about the technologies that can deliver insulin automatically when needed. And discover the next generation of insulins that are currently being developed.
You could win a cash prize of up to £25,000 when you play the Breakthrough T1D lottery. As well as the chance to win great prizes, you’ll also help fund our research to find a cure for type 1 diabetes.
Join us on Tuesday 4 June for an exclusive drinks reception and panel event featuring some of the UK’s top former and current sports professionals living with type 1 diabetes.
Find out about the latest progress in type 1 diabetes research, learn more about our ongoing partnerships or see what our celebrity ambassadors are up to.
Join the type 1 diabetes community and come together, raising awareness and vital funds for T1D. Every pound raised directly supports us to fund our life-changing research.
We provide a wealth of information and free resources to help you support and empower your patients or students.
Take our free course for schools to learn more about supporting pupils with type 1 diabetes in educational settings.
JDRF has now rebranded to Breakthrough T1D. Our name has changed, our mission has not.
Home > Knowledge & support > Resource hub > Five reasons why medical research can be a long process
We all want a cure for type 1 diabetes as soon as possible, but we need to make sure any new treatments are safe and reliable. So, the journey from scientific discovery to a new medical treatment, known as the research pipeline, involves a complex and time-consuming process.
We’ve received a lot of questions on social media about why research can be a slow process, so we hope this blog helps explain some of the challenges that our researchers navigate to bring us new treatments for type 1.
Medical conditions, such as type 1 diabetes, are incredibly complex. As people with type 1 know all too well, so many things influence the working relationship between insulin and glucose, from your stress levels to the weather outside.
Type 1 diabetes primarily involves the insulin-producing beta cells and the immune cells that attack them. But these cells don’t exist in isolation. We have roughly 20,500 genes for around 400 different types of cells totalling 17 trillion cells in children and up to 37 trillion in adults. Our cells and the chemicals they release have intricate interactions and relationships with each other. So, our researchers have so much more than just the beta cells to consider when trying to replace, regrow or protect them.
Due to this complicated biology, researchers often face unexpected challenges and setbacks that require revisiting and refining their ideas and approaches or sometimes starting from scratch.
Before doctors can give new treatments for type 1, researchers need to thoroughly test them to make sure they are safe and effective. This extensive development and testing process is called the research pipeline and involves distinct phases.
A diagram of the research pipeline.
The drug discovery stage is when the exploratory lab work takes place, with researchers investigating new ways to prevent, treat and cure conditions like type 1. Promising ideas move forward to preclinical trials, in which researchers test new therapies using cells in petri dishes and lab animals. Treatments that prove safe and effective in animals progress to clinical trials in humans.
New treatments must undergo three phases of clinical trials. Phase I trials involve a small number of people to check the treatment isn’t toxic for humans and to find the best dose. Following this, the trial moves to phase II, recruiting more people to investigate side effects and whether the treatment works. Then, in phase III even more participants are involved to compare the new treatment to an existing therapy or a placebo. A trial can fail and be terminated at any of these three stages.
Each stage of the research pipeline involves time-consuming processes, including planning experimental methods, applying for ethical approval and writing and reviewing scientific papers, and getting those papers published in journals. Many individual research projects occur within every stage to repeat the experiments to ensure results are reproducible and to tweak methods to improve the outcomes. Only five in 10,000 prospective drugs reach clinical trials, and just one progresses all the way to securing regulatory approval.
Evidence gathered from research studies is used to apply for approval for new technologies and treatments from government regulatory bodies. Each country has their own organisation that carefully evaluates the data to ensure that the benefits outweigh any risks before granting licences for new medicines. In the UK, we have the Medicines and Healthcare products Regulatory Agency (MHRA). This step is crucial for patient safety but can add a significant amount of time to the overall process. For example, the MHRA can request more evidence of a treatment’s safety and effectiveness, so researchers must run more clinical trials.
Even once the MHRA approves a treatment, this approval doesn’t mean it becomes automatically available for patients. The next stage to get medications and technology into the hands of people who need them is an agreement between the manufacturers, government bodies and healthcare providers.
For example, the first hybrid closed loop (HCL) system was licensed in 2020. In the UK, this HCL technology was approved by the National Institute for Health and Care Excellence (NICE) for most people with type 1 in 2024. The approval process involved extended negotiations between five medical technology companies, the NHS, healthcare professionals and patient advocacy groups including Breakthrough T1D UK to agree who can receive the funding. These consultations are sometimes lengthy to ensure that treatments are provided to the people who need them most.
Medical research is a hugely expensive endeavor, and it is extremely important that the available money is used wisely. Therefore, researchers often face lengthy review processes to secure funding for their projects. Competition for grants, limited resources, and the need for long-term financial support can all slow down the progress of research.
That’s why our supporters are so vital, and we are so grateful to you all for helping us boost the pace of research by funding so many incredible type 1 diabetes research projects. Without your donations, we wouldn’t be able to fund our pioneering research, and we’d be a lot further from a cure than we are now.
Donate now to help fund our research and so that our scientists can develop new treatments and cures, sooner.
Megan Neville was diagnosed with type 1 diabetes at three years old. Now a graduate of the Royal School of Needlework, Megan shares her experiences of growing up with type 1 and how it became the topic of her sculptural handbag embroidery project: Ordinary Oddness.
Eden Valk was diagnosed with type 1 diabetes while she was still in school, navigating classes, friendships and everyday life. Here, she shares five of the most important lessons she’s learned along the way.
Manisha Vadgama shares what she has learned on her own pregnancy journey so far, from getting the tech right to making sure she has the right people around her.
Researcher, Dr Paidamoyo Katsande, shares why she's so passionate about curing type 1 diabetes and how Breakthrough T1D supporters are bringing us closer to a cure.
Our research is improving the lives of people with type 1 and making strides towards a cure. We’ll keep pushing until we make type 1 diabetes a thing of the past.
