CRISPR therapy cures first genetic disorder inside the body


For the first time, researchers appear to have effectively treated a genetic disorder by directly injecting a CRISPR therapy into patients' bloodstreams — overcoming one of the biggest hurdles to curing diseases with the gene editing technology.

The therapy appears to be astonishingly effective, editing nearly every cell in the liver to stop a disease-causing mutation.

The challenge: CRISPR gives us the ability to correct genetic mutations, and given that such mutations are responsible for more than 6,000 human diseases, the tech has the potential to dramatically improve human health.

One way to use CRISPR to treat diseases is to remove affected cells from a patient, edit out the mutation in the lab, and place the cells back in the body to replicate — that's how one team functionally cured people with the blood disorder sickle cell anemia, editing and then infusing bone marrow cells.

Bone marrow is a special case, though, and many mutations cause disease in organs that are harder to fix.

Another option is to insert the CRISPR system itself into the body so that it can make edits directly in the affected organs (that's only been attempted once, in an ongoing study in which people had a CRISPR therapy injected into their eyes to treat a rare vision disorder).

Injecting a CRISPR therapy right into the bloodstream has been a problem, though, because the therapy has to find the right cells to edit. An inherited mutation will be in the DNA of every cell of your body, but if it only causes disease in the liver, you don't want your therapy being used up in the pancreas or kidneys.

A new CRISPR therapy: Now, researchers from Intellia Therapeutics and Regeneron Pharmaceuticals have demonstrated for the first time that a CRISPR therapy delivered into the bloodstream can travel to desired tissues to make edits.

"This is a major milestone for patients," Jennifer Doudna, co-developer of CRISPR, who wasn't involved in the trial, told NPR.

"While these are early data, they show us that we can overcome one of the biggest challenges with applying CRISPR clinically so far, which is being able to deliver it systemically and get it to the right place," she continued.

What they did: During a phase 1 clinical trial, Intellia researchers injected a CRISPR therapy dubbed NTLA-2001 into the bloodstreams of six people with a rare, potentially fatal genetic disorder called transthyretin amyloidosis.

The livers of people with transthyretin amyloidosis produce a destructive protein, and the CRISPR therapy was designed to target the gene that makes the protein and halt its production. After just one injection of NTLA-2001, the three patients given a higher dose saw their levels of the protein drop by 80% to 96%.

A better option: The CRISPR therapy produced only mild adverse effects and did lower the protein levels, but we don't know yet if the effect will be permanent. It'll also be a few months before we know if the therapy can alleviate the symptoms of transthyretin amyloidosis.

If everything goes as hoped, though, NTLA-2001 could one day offer a better treatment option for transthyretin amyloidosis than a currently approved medication, patisiran, which only reduces toxic protein levels by 81% and must be injected regularly.

Looking ahead: Even more exciting than NTLA-2001's potential impact on transthyretin amyloidosis, though, is the knowledge that we may be able to use CRISPR injections to treat other genetic disorders that are difficult to target directly, such as heart or brain diseases.

"This is a wonderful day for the future of gene-editing as a medicine," Fyodor Urnov, a UC Berkeley professor of genetics, who wasn't involved in the trial, told NPR. "We as a species are watching this remarkable new show called: our gene-edited future."
 
They actually cured people of sickle cells? Please feel free to give me a reason to not be excited.
We don't yet know how long the edits will last, if there is an autoimmune reaction in response to the treatment, or any dangerous genome changes resulting from CRISPR missing its mark.

If it does work though, that is a game changer.
 
I think that's part of the point of such "cures" to make sure there are future patients who will either pay out of pocket or get their treatment via subsidies, either way good o'l pharma gets some cash.

Medical/Pharmaceutical Industries are not in the business of curing diseases and disorders or they would be in the business of putting themselves out of business, their business is life extension and symptom mitigation/suppression, preferably with drugs that a patient needs to take for life, a dead person doesn't pay for treatment but neither does a healthy one.

another point is that this genetic tech is crazy expensive so we will end up with rich people being able to cure themselves and the rest of us having no way to afford it. Same with personalised treatments for cancer which are coming soon. It will create a two-tier system, even more than it is already.
 
They actually cured people of sickle cells? Please feel free to give me a reason to not be excited.
If you can cure a genetic disorder, you can also induce one.

I was recently working on some scripts and changing one value in something seemingly barely relevant fucked up something semi-important in a completely different place and I had no fucking idea wtf until I rolled the whole thing back. Now sure, I'm an idiot for not properly checking dependencies but my point should be clear.

But whatever, we're exiting times where decades of testing were required for something to be deemed "safe". Looking forward to "gene bugfixing therapy v.1.0031".

I do hope it works, I want to believe that something good can be done and just work but it's difficult these days.
Edit:
another point is that this genetic tech is crazy expensive so we will end up with rich people being able to cure themselves and the rest of us having no way to afford it. Same with personalised treatments for cancer which are coming soon. It will create a two-tier system, even more than it is already.
The right ones, with right connections will be able to, the wrong ones will have complications, a nice cleansing. Wonder who'll be deciding who's who though.

But sure, it already works like that to an extent, see how many heart transplants David Rockefeller had and how many you can get.
 
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another point is that this genetic tech is crazy expensive so we will end up with rich people being able to cure themselves and the rest of us having no way to afford it. Same with personalised treatments for cancer which are coming soon. It will create a two-tier system, even more than it is already.
Not really. You're not factoring in human nature in that scenario. If something like that were to happen and it ever got out that the rich were curing themselves of everything like that and leaving everybody else to die of curable diseases, such people would not be pleased. They would more than likely riot and lynch said rich people. Nobody would tolerate being told to shut up and die while others cure themselves. Humans don't take that kind of thing very well, especially when they have nothing to lose
 
Not really. You're not factoring in human nature in that scenario. If something like that were to happen and it ever got out that the rich were curing themselves of everything like that and leaving everybody else to die of curable diseases, such people would not be pleased. They would more than likely riot and lynch said rich people. Nobody would tolerate being told to shut up and die while others cure themselves. Humans don't take that kind of thing very well, especially when they have nothing to lose

So if it got out, it would become the next gamergate and pizzagate and CNN will tell the podfolks its a neo nazi nutjob theory, Schlomo is just living healthily on a diet of vegan meat, soy milk and foreskin flavoured bug pizza.

Super Schlomo vs Chink the Mighty will look fun though.
 
fatso sedentary elites need to use high tech just not to die of their obesity related diseases at age 60, while I keep myself healthy with 100 dollar worth of skipping rope and weights lel

the VIRGIN 1% vs the CHAD 99%
 
the most important use of gene editing tech is radiation hardening humans. there's only so much we can do to block harmful radiation in space with known / feasible technology, and the most feasible way to get to far away places involves a lot of nuclear powered tech. the easiest way to solve this problem is by making us rad resistant cockroach hybrid gods.
 
another point is that this genetic tech is crazy expensive so we will end up with rich people being able to cure themselves and the rest of us having no way to afford it. Same with personalised treatments for cancer which are coming soon. It will create a two-tier system, even more than it is already.
CRISPR is very cheap. So cheap it cheapened the genetics field completely, and will make sophisticated DNA-editing tech obsolete.
 
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