Results from a Phase-II Clinical Trial of Baricitinib

Baricitinib works by interfering with signaling pathways inside immune cells, to reduce inflammation and lower the immune system.  It is part of a class of drugs called Janus kinase (JAK) inhibitors.  JAK comes in two forms, JAK1 and JAK2, and Baricitinib targets both of them.

Baricitinib is not a new drug; it was first approved by the US Food and Drug Administration (FDA) in 2018.  It is taken as a once-daily oral pill and used to treat other autoimmune diseases, such as rheumatoid arthritis and alopecia areata (an autoimmune form of hair loss).  Because it has been in use for several years for other autoimmune conditions, its safety profile is well-understood.

Since the drug works on other autoimmune diseases, it seems reasonable to try it on type-1 diabetes.  Also, there has been the usual success with nonobese diabetic mice, which are commonly used to test potential type-1 diabetes cures.

This Study

This study is a phase 2, double-blind, randomized, placebo-controlled trial. A total of 91 patients were enrolled, with 60 individuals assigned to receive Baricitinib and 31 to the placebo group. Participants were honeymooners, having been diagnosed within 100 days before the start of the treatment.  They took one Baricitinib pill daily for almost a year.

The primary end point was the C-peptide level after a year. C-peptide is a substance released when the body produces insulin, serving as a reliable indicator of remaining beta-cell function. 

Secondary endpoints included several practical measures of diabetes management, average daily insulin dose,  A1c levels, and various metrics of glycemic control gathered from continuous glucose monitors. Tertiary end points included measuring things inside the immune system to see how Baricitinib affected them, especially what are called "effector memory CD8+ T cells".

The Results

The grey, placebo line shows the normal progression of T1D during the honeymoon phase.  C-peptide generation falls steadily until it hits some small residual levels, where it stays constant.  The amber, treatment line shows pretty much the opposite.  C-peptide generation goes up, but then plateaus out.  There is no doubt in my mind that this is a good outcome.  Generating more C-peptide is good, and this is not just holding constant; at the beginning it is going up.

But there are two big questions here.  First, is the difference important.  Untreated people leveled out at a level around 0.43, but treated people leveled out at about 0.65 and that is still way below healthy.  Second, this plateau was constant for the last 6 months of the study. and while the people were continuing to get Baricitinib.  This tells me that at this dose, it is not just a matter of time to get more improvement.

Discussion

To me, the obvious next question is: will a higher dose show more improvement?  This study shows improvement, but not enough to cure anyone, or even make much difference in treatment.   Would a higher dose of Baricitinib have a bigger impact?

Another follow on question is: will earlier treatment prevent T1D?  This is harder to study, and we will need to wait longer for the results.  However, any treatment which preserves beta cells might prevent T1D, if given in the pre-honeymoon phase.  And it is important to remember, this treatment did more than just preserve C-peptide production, it increased it.

The findings also support the concept that JAK inhibitors, as a class of drugs, may hold promise for treating type 1 diabetes. This could lead to further exploration of other JAK inhibitors in future clinical trials for this condition. 

One other clinical trial testing JAK inhibitors is being run now.  It is testing both abrocitnib and ritlecitinib.  It started in 2023 and they hope to finish in 2026.  It is recruiting in several sites in California, Other USA locations, Australia, and one in Canada.  You can see details here:

https://www.clinicaltrials.gov/study/NCT05743244

(click on the grey space to see a map of study locations)

For More Information

• US Clinical Trials Registry (ClinicalTrials.gov): https://clinicaltrials.gov/study/NCT04774224
• Australian New Zealand Clinical Trials Registry for BANDIT study: https://www.anzctr.org.au/Trial/Registration/TrialReview.aspx?id=380252
• Study Web Site: https://www.trialnet.org/events-news/blog/study-finds-jak-inhibitor-baricitinib-slows-t1d

Joshua Levy

http://cureresearch4type1diabetes.blogspot.com 

publicjoshualevy at gmail dot com

All the views expressed here are those of Joshua Levy, and nothing here is official BreakthroughT1D or JDCA news, views, policies or opinions.  I sometimes use generative AI ("chatbots") to generate draft blogs, parts of blogs, or drafter alternate wordings for these blogs.  I always review every part of every published blog to ensure that it is saying what I want, in the tone that I want, truthfully, and accurately.  My kid has type-1 diabetes and has participated in clinical trials, which might be discussed here.  I am obese and right on the border of T2D and therefore may be taking drugs for those conditions.  My blog contains a more complete non-conflict of interest statement. Thanks to everyone who helps with the blog!

Avotres Announces Results from a Phase-I Trial of AVT001

This blog posting reports on the results of Avotres recent phase-I clinical trial into AVT001 and the company's future plans for testing.  I reported on the start of this trial here:

https://cureresearch4type1diabetes.blogspot.com/2019/12/avotress-avt001-starts-phase-i-trial.html

AVT001 is an "autologous dendritic cell therapy" meaning that a person's own dendritic immune cells are taken out, processed in some way, and then put back.  Dendritic cells can be thought of as the immune systems "sensors".  They detect foreign invaders and then communicate that knowledge to other types of immune cells (especially T cells).

This trial flows out of some work done at Columbia University.  Researchers there found a defect in a specific type of immune cell called a HLA-E–restricted CD8+ T cells.  They believe that this defect leads to the immune system attacking the beta cells in the pancreas and causing type-1 diabetes.   The basic technique being tested here is to take out dendritic cells from the patient and treat those cells so that when they are put back into the patient, they (in turn) fix the defect in the HLA-E–restricted CD8+ T cells which leads to type-1 diabetes.

This Study and Its Results

This study involved 25 people, 16 were in the treatment group and 9 in a control group.  They were 16 years old or older, and in their honeymoon phase after diagnosis of T1D.  There were primary end points for safety and a secondary end point for C-peptides.  For me, the key results are below.  

The table below covers a year, from left to right on the bottom, and the amount of C-peptides a person generated, from zero up, on the left side.   A flat line shows success.   The body continues generating C-peptides. For the first 150 days for the treated group, C-peptide numbers do not drop at all.  This is the flat purple line. After that they did drop at about the same rate as untreated people.  This is the purple line dropping down. You can notice that the purple line and the dotted orange line (the untreated group) drop at about the same rate. The difference is that the untreated group started immeadiately, but the treated group stayed constant for at least 150 days. Since the treatment group was given three infusions, 30 days apart, the treatment last 90 days (infusions were on days 1, 30 and 60).  The treatment prevented beta cell loss for at least 90 additional days.  Safety and side effect data showed that there were no safety issues.

That's hopeful news in terms of prevention.  It suggests that giving this drug before the honeymoon phase might prevent T1D or at least delay it.   Of course, a study giving this treatment to pre-honeymooners would be needed to see if this actually happened.  Such a test would compare pre-honeymooners who got the treatment to pre-honeymooners who did not, and see how many of each group progressed to the honeymoon phase of type-1 diabetes.  If enough people are enrolled, and they are followed for long enough, such as trial could be run.   My memory is that such trials have been run lasting 2 and 5 years, and enrolling from 1 to 3 hundred people, so it is reasonable to do.

Also, it is important to remember that this treatment involves removing white blood cells from a  person's blood, treating the cells in a lab, and then intravenously infusing them back into the person with T1D.  So this is two clinic visits per treatment.

Poster: https://www.avotres.com/_files/ugd/1b81f5_edb8f657a28440638f8e32d2ec98ec4f.pdf

Journal Article: https://evidence.nejm.org/doi/abs/10.1056/EVIDoa2300238

Clinical Trial Registry: https://clinicaltrials.gov/study/NCT03895996

What Next?

From the point of view of Avotres, this was a clearly successfully phase-I/II and so are in discussions with the FDA to set up a phase-III clinical trial as the next step.  There is no advantage in speculating as to what the FDA will do.  The only thing that makes sense to do is wait a few months (or a year) and see what actually happens. 

From my point of view, this was a successful phase-I study, which showed that AVT001 might work as a T1D prevention.  If given to people before the honeymoon, it might delay or even prevent the onset of T1D.  Therefore, Avotres could turn this into a prevention/delay treatment (like Tzield®) by running three more studies (one one phase-II study and two phase-III studies as a minimum) to get approval.

In addition Avotres could try to apply AVT001 to treatment of established T1D in a different set of clinical trials, and see where that led.  

For background, the FDA generally requires one phase-I study, one phase-II study, and two phase-III studies as a minimum for approval, although there are occasional exceptions.

Company website: https://www.avotres.com/ and https://www.avotres.com/companyoverview

Joshua Levy

http://cureresearch4type1diabetes.blogspot.com 

publicjoshualevy at gmail dot com

All the views expressed here are those of Joshua Levy, and nothing here is official BreakthroughT1D or JDCA news, views, policies or opinions.  I sometimes use generative AI ("chatbots") to generate draft blogs, parts of blogs, or drafter alternate wordings for these blogs.  I always review every part of every published blog to ensure that it is saying what I want, in the tone that I want, truthfully, and accurately.  My kid has type-1 diabetes and has participated in clinical trials, which might be discussed here.  I am obese and right on the border of T2D and therefore may be taking drugs for those conditions.  My blog contains a more complete non-conflict of interest statement. Thanks to everyone who helps with the blog!

No Blog Postings Until August

I have not posted anything in this blog for the last 5 weeks, and I don't expect to for the next few weeks.  That is because my father has passed away.  It was not sudden or unexpected, but it is still very shocking.  He was diagnosed with terminal pancreatic cancer about six months ago, and was slowly declining.  However, in mid-May, he started quickly declining, and died on 10 June 2025.  His cancer had nothing to do with diabetes, although it did cause him to have high blood glucose for the last few months of his life.

My plan is to take a break from blogging for the rest of June and July, but then start blogging again in August.

My dad taught me several things which have directly shaped this blog, including:

• Optimism, which is why I blog on cures, even as we are so far away from a cure, but also allows me to do something (blogging) that I had never done before, and in an area (medicine) that I have no special skills or training.   
• As a small kid and repeatedly throughout my life, he told me: when talking to someone else (anyone else), to always be willing to talk about what they were interested in.  Learn why they liked it, why they found it exciting, and the complexities they found in whatever was important to them.  Reading other's research is similar to talking to them about something they are very, very interested in.
• As a young adult, he reminded me that "your children will take you in directions you would not have gone yourself".  This blog is a testament to an unexpected place that my child has taken me.
• My dad understood that facts were just web searches.  But the important thing was understanding why something was true, how it was true, what it meant, how changes in the world would change the fact, and how changes in the fact would change the world.  These were the questions that interested him, and you can see how those questions fuel this blog.

Joshua

Diamyd’s GABA-Based Remygen® Unsuccessful in Phase 1 Clinical Trial

This clinical trial tested whether long-term daily treatment with Remygen®, an oral drug developed by Diamyd Medical, could help restore insulin production in adults with longstanding type 1 diabetes (T1D). The active component of Remygen® is GABA (gamma-aminobutyric acid), a compound that in earlier experimental studies appeared to support the regeneration of insulin-producing beta cells, improve insulin release, and reduce inflammation.

What Was the Clinical Trial Testing?

The trial enrolled 35 adult men with T1D for at least five years and divided them into three treatment groups. One group received a lower daily dose of GABA, a second received a higher dose, and a third group received the higher GABA dose plus a short-term course of alprazolam (an anti-anxiety, benzodiazepine drug). The treatment lasted six months.

Researchers monitored insulin production using fasting and post-meal C-peptide levels, tracked blood glucose control, and recorded any side effects or adverse events. The goal was to assess both the safety of long-term GABA use and whether it had any regenerative effect on the pancreas.

What Were the Results of the Clinical Trial?

The trial found that Remygen® did not restore insulin production or improve any markers of beta-cell function.

C-peptide levels, which reflect the body’s natural insulin production, remained unchanged in all treatment groups throughout the six-month period. This included individuals who had some detectable C-peptide at baseline, as well as those with undetectable levels. No meaningful changes were observed for insulin production either.

Measures of blood sugar control—including continuous glucose monitoring data and HbA1c—also remained stable, with no significant improvements seen in any group.

Additionally, the trial found no change in the body’s hormonal response to low blood sugar. This was in contrast to some earlier short-term studies that had hinted at possible effects of GABA in this area.

In terms of safety, the treatment was generally well tolerated, but side effects were common.  One participant had a serious liver reaction, likely related to the drug, though liver function returned to normal after stopping the medication.

Discussion

My memory is that, at its height, there were 4 or so GABA related clinical trials running.  But this was the last GABA clinical trial that I knew of, so I think this line of research is dead for now.

Diamyd has also been developing a DNA-based immunotherapy (also called Diamyd®) aimed at slowing or stopping the immune system’s attack on beta cells, a different strategy from GABA. That program remains in clinical development. 

Clinical Trial Registry: https://www.clinicaltrials.gov/study/NCT03635437

EU Clinical Trial Registry: 2018-001115-73

Joshua Levy

http://cureresearch4type1diabetes.blogspot.com

publicjoshualevy at gmail dot com

All the views expressed here are those of Joshua Levy, and nothing here is official BreakthroughT1D or JDCA news, views, policies or opinions.  I sometimes use generative AI ("chatbots") to generate draft blogs, parts of blogs, or drafter alternate wordings for these blogs.  I always review every part of every published blog to ensure that it is saying what I want, in the tone that I want, truthfully, and accurately.  My kid has type-1 diabetes and has participated in clinical trials, which might be discussed here.  I am obese and right on the boarder of T2D and therefore may be taking drugs for those conditions.  My blog contains a more complete non-conflict of interest statement. Thanks to everyone who helps with the blog!

Changes to My Blogging: AI

I'm going to start using generative AI (what people call "chatbot" technology) to help me create draft blog postings.    In all cases, I will review and edit every word to ensure three things:

• Every posting has the right tone.
• Every piece of information in the posting is accurate.
• Every posting conveys the truth, as I understand it, in terms of importance, future directions, risks, unknowns, and so on.  I check that the things implied the posting implies are true, are in fact, true.

This blog has never accepted as sufficient mere facts-and-figures accuracy (what the media often calls "fact checking").  In addition to checking facts, I have always spent a lot of time checking that the tone, implications and views conveyed in this blog are also the truth, as far as I know it.  That will continue, even as I use AI to help write initial drafts of the blog.

I'm starting to use AI for three related reasons:  First, blogs take a lot of time and I hope that using generative AI will allow me to create blogs of the same quality in less time.  I'm not going to save time in the editing or reviewing part of writing blogs, but crafting the English takes me a lot of time and I hope AI can speed the process. Second, I hope that I can use this newly available time to either create more blogs or create more complex blogs.   I want to do more analysis and historical perspective type blogs, rather than just writing all the time to keep up with the clinical trial results.  I feel that is sort of the news equivalent of "treading water", and what I want is to get ahead of the news and use the news to write more inciteful posts.  Third, it would be nice to get news about clinical trials out quicker so you can read about it sooner after the results are announced.

In terms of "how will I use AI", I'm not going to use it in a simple minded or unthinking way! I am going to experiment with several different methods and expect to end up using a combination of these techniques, and incrementally improving them over time.  

• For example, one simple technique would be to have many different chatbots respond to the same question, and then I, as a human, merge the best parts (or the best language) from each of their responses together to create a posting.   
• Another technique I will try is asking very specific, very focused questions of AI in order to generate parts of the blog posting.  Then (as a human) merging those parts together into a posting.
• I will also experiment with creating very complex detailed questions for the AI in order to generate blog postings all at once.  (This is called "prompt engineering".)

The future is the undiscovered territory, and I am going exploring.

Joshua Levy

http://cureresearch4type1diabetes.blogspot.com

publicjoshualevy at gmail dot com

All the views expressed here are those of Joshua Levy, and nothing here is official BreakthroughT1D or JDCA news, views, policies or opinions.  I sometimes use generative AI ("chatbots") to generate draft blogs, parts of blogs, or drafter alternate wordings for these blogs.  I always review every part of every published blog to ensure that it is saying what I want, in the tone that I want, truthfully, and accurately.  My kid has type-1 diabetes and has participated in clinical trials, which might be discussed here.  I am obese and right on the boarder of T2D and therefore may be taking drugs for those conditions.  My blog contains a more complete non-conflict of interest statement. Thanks to everyone who helps with the blog!

Sana Biotechnology Reports First Results For Islet Transplants Without Immunosuppression

This blog post reports on some news that I consider exciting, for at least two different reasons: first because it might be an early milestone on a path that leads to a practical cure of established T1D.  The second because it could speed up research into similar cures.  However, it is important to understand what is actually new and unique about this news, and how it differs from previous news that sounds similar.

The JDCA (Juvenile Diabetes Cure Alliance) has published a report on this work, which is worth reading: https://www.thejdca.org/publications/report-library/archived-reports/2025-reports/cell-protection-without-immunosuppression-sana-biotechs-t1d-trial-presents-early-data.html

And so has BreakthroughT1D: https://www.breakthrought1d.org/news-and-updates/cell-therapy-first-transplanted-islets-working-without-immunosuppressives/

And Diatribe: https://diatribe.org/diabetes-research/promising-step-towards-insulin-independence-type-1-diabetes

Background: Islet Transplants Without Immunosuppression

At least 50 years ago, it was pretty clear that the beta cells of people with T1D were destroyed, and that gave hope that transplanting in new beta cells might cure T1D in a straightforward way.  It did not happen, because the new cells were attacked by the body's immune system for two reasons: (a) they were foreign cells so the immune system attacked them "normally", as part of the healthy attack on foreign cells.  And (b) because the immune system is broken, leading to T1D in the first place, it attacked these new cells "abnormally" just as they had attacked the body's own cells to trigger T1D in the first place.

One way to solve both these problems is to modify the new cells so that they are invisible to the immune system.  That is, they don't present as foreign cells nor do they present as beta cells.  This is the solution that Sana Biotechnology has been researching, and that I'm reporting on here.

What Was Reported

In a very small clinical trial, they reported data on the first person transplanted with beta cells, after one month:

• C-peptide data shows the transplanted beta cells were generating insulin, and were generating it in response to eating carbohydrates.  
• MRI images suggest that the new beta cells are surviving.
• No safety issues were seen.
• The new cells appear to have avoided any immune attack ("evaded immune responses"). 

This is all good news, but notice what was not reported: no specific numbers on C-peptide generation, which means no specific numbers on insulin generation.  And similarly, no numbers on insulin usage, A1c, or anything else to show how well the new beta cells were operating.

Also notice the limitations of this reporting: one person and one month, and no scientific journal article, just a press release.

More Study Details

The entire study is a two person, phase-I study lasting a year, so not much bigger.   Donated beta cells are modified using Sana’s Hypoimmune (HIP) technology, and then implanted into the forearm of the person with T1D.   The procedure took 90 minutes.  The HIP technology is the "secret sauce" that Sana hopes will make the cells invisible to the immune system.  This protocol is identified as "UP421" and they are using it in another program aimed at cancer. 

This study was very much a proof of concept.  The researchers are implanting between 2% and 7% of the beta cells that will ultimately be needed, to see if they get any results at all.  They are measuring C-peptides, as well as various safety and immune system measurements.  But the summary is, even when the whole clinical trial is done, we will have very little information.  

Press Release: https://ir.sana.com/news-releases/news-release-details/sana-biotechnology-announces-positive-clinical-results-type-1

News Report: https://firstwordpharma.com/story/5926109

Last Minute Update

Just as this blog was going out, Sana released a corporate presentation, which had some additional information.  The main updates are as follows, and I think they are all very positive:

• Three months of data are included, and the c-peptide numbers continue to be strong for the entire time.
• They include data (specific numbers) for fasting and mixed meal c-peptide data.  Considering how small the transplantation was, the results are very promising.
• They include immunology data that supports their claims that the newly transplanted beta cells are not triggering an autoimmune response.  

Corporate Presentation: https://ir.sana.com/static-files/a3b2a275-e72e-4382-aa08-6760f9cfc528

Discussion

What To Look For In The Future (and When)

To me, this has the potential to be a huge breakthrough, as it could lead to a practical cure in the future.  The key words here are "potential" and "future".  For many people the next questions is, how likely is it or how long will it take.  But those are not my questions.  My questions are, what are the next reports we should expect to see, and what data from those reports will signal good news?

Unfortunately, we are not going to get a lot more information any time soon.  This data comes from a very small, phase-I clinical trial: only two people in total (both treated, no control group). That means that over the next year, the very best we can hope for is 2 people; no control group; a small dose; all published in a scientific journal.  That is not much (although one year is not long to wait).

The next data we should expect, would be the results of a phase-II or maybe a phase-II/III clinical trial.  But we should not expect that for 3 or 4 years.  And remember, no matter how successful the current  study is, and how successful the next study is, approval will still require an additional phase-III study (maybe two phase-III studies), which is more years.

Clinical Trial Registry: https://clinicaltrials.gov/study/NCT06239636

Is it a cure?  The immune system is still broken!  

One comment I sometimes hear when I talk about transplants is that they are not cures, because the immune system is still broken.  They might stop the symptoms, but they do not cure the "real" disease, the flaw with the immune system.

This gets into the very emotional question of what is a cure.  After all, if someone's leg is crushed and you install a pin, have you cured them?  What if the pin means they can walk but not run?  On the other hand, if they crush a leg, and need a wheelchair for the rest of their lives, are they cured?  After all, the wheelchair means they can get around.  And so on.

My answer to this question is on my web page, just to the right of every blog posting I write: 

1. Blood sugar control without testing and with doctor's visits four times a year, or less. Any cure must result in an average lifespan close to normal.  

2. Does not require a lifetime of immunsuppressive drugs, so it is not trading one treatment for another. (but a couple of operations, or a short course of drugs is OK) 

 Obviously, this is my personal definition of a cure; yours may differ.

By that definition, this would be a cure, if it works.  The fact that the immune system is still broken does not change the fact that the person no longer needs to take insulin, count carbs, or wear a pump 24x7.

History and Complexities of Islet Transplants

You don't need to read this section to understand the research, or why it is important.  I'm putting it here for people who find it interesting.

The history and complexities of islet transplant research is a huge topic, far to big to fit in one blog posting, much less one section of a blog posting.  However, I will try to summarize both the history of transplant-based cures and the complexities that have prevented the research from succeeding:

Transplant History

In the 1970s and 1980s, it was commonly thought that type-1 diabetic's beta cells had been destroyed, and if they could just be replaced, their diabetes would be cured. This led to several attempts at transplants to cure T1D, especially whole pancreas transplants, beta cell transplants, and drug treatments designed to get beta cells to regrow (such as human growth hormone). 

These did not work because the new beta cells were destroyed by the broken immune system just as the old ones had been, and also because the properly working immune system attacked transplants as foreign cells.  

Starting in the 1980s, researchers tried encapsulating beta cells: they put beta cells inside a wrapper and then implanted the bundle in a person. The wrapper would need to be a very high-tech material that would allow nutrients and oxygen to flow in, wastes to flow out, insulin to flow out, and the chemicals which triggered insulin production to flow in. But if they succeeded, it would be like having a natural pancreas inside you, but protected from the immune system.

Many different companies and many different researchers tried to use encapsulated beta cells to cure T1D.  There were a lot of different options to try.  Every researcher needs to choose a source of beta cells, and an encapsulation technology.  Optionally, they might also add an unusual transplant location or a new drug protocol for the transplant itself.  Since there are many different sources of beta cells, and an almost unlimited number of encapsulation technologies, you can see how this would keep many researchers busy for many decades.

At different times, beta cells have been sourced from: pigs, genetically modified pigs, human cadavers, or live humans.  Plus, they have been grown from stem cells sourced from: the person with T1D themselves, other people's skin cells, placenta cells, or embryos.  Plus, I'm probably forgetting a few, since this research has been going on for 40 years!

As for encapsulation technologies, there are dozens of them, and I'm not even going to try to list them, but all kinds of modern material science has been applied to the problem.

However, to date nothing has worked.  I believe that there are several problems and solving one tends to make the others worse, and it is very hard (so far, impossible) to solve all of them at once.  The problems include: 

1. Allowing nutrients to pass from the body into the new beta cells, and waste products to pass from the beta cells back out to the body.
2. Not allowing immune cells to move from the body to the beta cells.
3. Allowing sugar to pass in and insulin to pass out.
4. Not having the body build up scar tissue around the beta cells, which blocks access to them.

You'll notice that solutions to problems 1 and 3 tend to make problem 2 worse, while solutions to problems 2 and 4, tend to make problems 1 and 3 worse.  Of course, all problems must be solved at the same time, for this to work.

Sana's Approach Is Different

Sana Biotechnology is not trying to encapsulate beta cells.  Instead, Sana is trying to alter them so that the immune system can not detect them.  This would solve both major transplant problems at once.  The "natural" attack on any foreign cells would not even see the new cells, and the "broken" attack on beta cells would not even see the beta cells to attack them.

The immune system identifies cells by identifying specific structures on the outside of cells.  MHC Class I and II are two such structures and the CD-numbers refer to other such structures.  So Sana is trying to remove these structures from the outside of their beta cells.  The hope is that then the immune system will not see the cells at all.

I'm not a researcher, so I have a lot of trouble evaluating the science behind Sana’s Hypoimmune (HIP) technology.  However, here are two summaries of HIP that I could find:

Sana's approach seeks to modify cells to evade both innate and adaptive immune responses by knocking out MHC Class I and II expression and over-expression of CD47.

The goal of Sana’s hypoimmune (HIP) platform is to eliminate the need for immunosuppression by cloaking cells from immune recognition while at the same time generating the manufacturing scale and reproductibility of allogeneic cells. The challenge for the field to date in generating immune cloaked cells has been turning off both the adaptive and innate immune system concurrently. Sana’s platform includes disruption of major histocompatibility (MHC) class I and MHC class II expression to hide cells from the adaptive immune system, which includes antibody and T cell responses, as well as overexpression of CD47 to inhibit activation of the innate immune cell system, in particular macrophages and natural killer (NK) cells. 

As with all research approaches, it doesn't matter if it sound good or if it makes sense.  It only matters if it works in clinical trials.  

News Report: https://firstwordpharma.com/story/5926109

Press Release: https://ir.sana.com/news-releases/news-release-details/sana-biotechnology-highlights-hypoimmune-allogeneic-car-t-cell

Joshua Levy

http://cureresearch4type1diabetes.blogspot.com

publicjoshualevy at gmail dot com

All the views expressed here are those of Joshua Levy, and nothing here is official BreakthroughT1D or JDCA news, views, policies or opinions. My kid has type-1 diabetes and has participated in clinical trials, which might be discussed here.  I am obese and right on the boarder of T2D and therefore may be taking drugs for those conditions.  My blog contains a more complete non-conflict of interest statement. Thanks to everyone who helps with the blog!

TIXIMED Starts a Phase 1 Study of TIX100

TIX100 is a protein which inhibits the action of TIXNP (thioredoxin-interacting protein).  It is being developed by the TIXIMED company.  TXNIP is elevated in pancreatic islets of people with type-1 diabetes and causes beta cell death and dysfunction.  The hope is that inhibiting that protein will protect beta cells and therefore delay or prevent T1D.

Anath Shalev, a researcher at the University of Alabama, Birmingham is leading this research effort, first at UAB and now also at TIXIMED.  She first identified TXNIP in 2002 in human islets exposed to high glucose and then later showed that it played a role in glucose toxicity and diabetic beta cell loss.  Research has shown that inhibiting TXNIP protects beta cells and promotes beta cell health and function.

Recently she has run clinical trials for Verapamil, which lowers TXNIP and is already approved in the USA for the treatment of high blood pressure, migraines, and heart problems.  I have blogged several times on those studies, but especially the results from a phase-II trial here:

https://cureresearch4type1diabetes.blogspot.com/2023/03/results-from-phase-ii-verapamil-study.html

I also listed it as a drug to watch in 2024:

https://cureresearch4type1diabetes.blogspot.com/2024/01/what-to-watch-in-2024.html

because there is another phase-II study ongoing in Europe, but it is now scheduled to finish in 2025 or 2026.

TIX100 is an oral medicine, and a "small molecule", but I have not found any other public information on what it actually is.  It has been tested in animals for T1D, T2D, nonalcoholic fatty liver disease (NAFLD) and nonalcoholic steatohepatitis (NASH).  For example: 
https://diabetesjournals.org/diabetes/article/72/Supplement_1/97-OR/150782/97-OR-Antidiabetic-TIX100-Improves-NAFLD-NASH-in

This Study

This is a blinded dosing study done in healthy people.  They are recruiting 35 people, none of whom have T1D, and giving them 6 different doses ranging from none to 200 mg of TIX100.   The goal is to make sure all potential doses are safe.  

This is a single dose study, follow up is after one week, and they expect to be done by May.  Because the end points are all safety and side effect related, we will not know anything about efficiency (if it actually works against T1D), but "the trip of 1000 miles starts with a single step".  Good results here will presumably enable an efficiency focused phase-II study.

The good things about this study are that it is quick and easy to participate in.  They are recruiting in one location:

Chula Vista, California, United States, 91911

ProSciento, Inc.  619-427-1300   hello@myproscientostudy.com

Corporate Web Page: https://tiximed.com/

Corporate Interview: https://www.youtube.com/watch?v=sezKoZi7lJU

To see a longer history of research into curing type-1 diabetes by targeting TIXNP, you can read this article: https://www.news-medical.net/news/20240731/FDA-clears-UAB-startups-TIX100-for-clinical-trials.aspx

Clinical Trial Registry: https://www.clinicaltrials.gov/study/NCT06800729

Joshua Levy

http://cureresearch4type1diabetes.blogspot.com

publicjoshualevy at gmail dot com

All the views expressed here are those of Joshua Levy, and nothing here is official JDRF or JDCA news, views, policies or opinions. My kid has type-1 diabetes and has participated in clinical trials, which might be discussed here. My blog contains a more complete non-conflict of interest statement. Thanks to everyone who helps with the blog!