Daily Archives: June 27, 2017

Whole genome sequencing could become part of routine medical care. Researchers sought to find out how primary care doctors and patients would handle the results. Cultura RM Exclusive/GIPhotoStock/Getty Images/Cultura Exclusive hide caption

Whole genome sequencing could become part of routine medical care. Researchers sought to find out how primary care doctors and patients would handle the results.

Advances in technology have made it much easier, faster and less expensive to do whole genome sequencing to spell out all three billion letters in a person's genetic code. Falling costs have given rise to speculation that it could soon become a routine part of medical care, perhaps as routine as checking your blood pressure.

But will such tests, which can be done for as little as $1,000, prove useful, or needlessly scary?

The first closely-controlled study aimed at answering that question suggests that doctors and their patients can handle the flood of information the tests would produce. The study was published Monday in Annals of Internal Medicine.

"We can actually do genome sequencing in normal, healthy individuals without adverse consequences and actually with identification of some important findings," says Teri Manolio, director of the division of genomic medicine at the National Human Genome Institute, which funded the study. Manolio wrote an editorial accompanying the paper.

"There's a lot of excitement and a lot of hope about this new technology and how it's going to revolutionize medicine," says Jason Vassy, a researcher at the VA Boston Healthcare System and the Brigham and Women's Hospital, who led the study. "But at the same time, there are a lot of fears and a lot of concerns."

Vassy acknowledges that routine genome sequencing could overwhelm doctors and patients with confusing and sometimes alarming information, leading to anxiety and stress, as well as expensive and sometimes dangerous follow-up testing.

So he and his colleagues sought to find out what routine testing would look like in a general medicine setting. They studied 100 healthy, middle-aged patients whose primary care physicians randomly asked them if they were interested in having their genomes sequenced.

Half of the volunteers had their DNA scanned for genetic variations that could cause nearly 5,000 rare genetic diseases as well as other genetic markers. The other half answered questions about diseases that ran in their families the traditional way of spotting inherited risks.

One of the volunteers was Renee Duchainey-Farkes, 63, who runs an elementary school in Boston.

"I'd always been kind of fascinated by genome studies," Duchainey-Farkes says. "So I was more than excited, but at the same time now nervous because it was like, 'Well, do I really want to know if things aren't great?'"

Among the 50 volunteers who got sequenced, the researchers found that about 1 in 5 had a variant in their genome that was associated with a rare, sometimes serious genetic disease.

"That was higher than we expected to find," Vassy says. "These were generally healthy middle-aged adults who had gone their entire life and didn't think they had any genetic diseases."

Most of them were fine, but what happened next surprised the researchers: Neither the volunteers nor their doctors overreacted.

"We were pleasantly surprised to see that primary care physicians were able to manage their patients' genetic results appropriately," Vassy says. "And patients are generally able to handle this information. It does not cause an increase in anxiety or an increase in depression."

Many of the patients also received useful information, the researchers reported.

Duchainey-Farkes says she discovered why she got odd rashes and bad sunburns. It turns out she's had what so far has been a very mild version of variegate porphyria, a rare skin disease. As a result, her doctor gave her a list of drugs to stay away from because they could aggravate the condition.

"So I feel that was a really positive outcome," Duchainey-Farkes says.

She also found out she may be prone to diabetes, so she's trying harder to watch her weight and eat better, she says.

Finance professor Irena Vodenska, 46, of Brookline, Mass., learned she was carrying a genetic variation that could put her at risk for heart problems. Follow-up tests found nothing wrong with her heart. But Vodenska is still glad she did it.

"It made me think," Vodenska says. "It satisfied my curiosity, and it made me change some things in my life." She walks instead of drives whenever she can now, and she tries to eat better.

Manolio says those in the study who learned they were carrying variations associated with rare diseases could potentially use that information when planning their families.

Still, others remain skeptical.

"There's a lot of, in my opinion, highly misplaced enthusiasm for doing genomic sequencing in the general population," says James Evans, a geneticist at the University of North Carolina, Chapel Hill. "And this study shows that its routine provision, in that context, is vastly premature and likely lead to more mischief than benefit."

Others fear that people who get sequenced could be subject to discrimination.

"That information is accessible by third parties who can require access to it," says Mark Rothstein, who directs the University of Louisville's Institute for Bioethics, Health Policy and Law. For example, he says, "applying for life insurance or disability insurance or long-term care or other things."

Vassy and Manolio acknowledged the patients in the study were more affluent and better educated than the general populace. The doctors also received extra training in interpreting genetic information. And they stressed more research is needed before sequencing becomes commonplace.

But some private companies have already are starting selling genome sequencing to people who are really curious about what secrets may be hiding in their DNA.

"We think that whole genome sequencing will be part of the foundation of medical practice much sooner than people are thinking," says Brad Perkins, the chief medical officer at Human Longevity, Inc., one of the companies selling the test.

"It's a completely new way of looking at things," agrees Mirza Cifric, CEO of Veritas Genetics. "By having your whole genome sequenced, you have an asset for life. You have a digitized version of yourself that you can go back to for a variety of reasons."

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Whole Genome Tests' Risks And Benefits : Shots - Health News : NPR - NPR

The UK is home to acollection of hotspots known as The Golden Triangle for biotech. This week, we take a look at the top biotechs in one vertex, Oxford.

Ahh, Oxford.The image of Hogwarts for fans of the Harry Potter films and home to one of the worlds best all-around academic institutions, Oxford University. Though it ranksjust abit behind its counterpart at Cambridge, the university gave rise to some of the most promising biotechs in Europe, including two unicorns and a number ofchallengers.

Small wonder that bigger industry players are staking out territory in Oxfords biotech scene! German CRO Evotec recently launched Lab282with Oxford Sciences Innovation to act as a bridge between academia and industry. Then in January, Novo Nordisk spent 135M to start a diabetes research centerat the university.

Most of the biotechs are located south of Oxford at Milton Park check em out below!

It may yet be too early to call Immunocore a success story, but the immuno-oncology company has made a name for itself as a biotech unicorn since it raised $320M (293M) in the largest private round in Europe on record. Though CBO Eva-Lotta Allen told me that all immuno-oncology drugs are still experimental, her companystechnology seems to have the confidence of the likes of Neil Woodford and the Baker Brothers convinced. So what is it?

Immunocore relies on its ImmTAC platform, which strips down TCRs to bi-specific molecules and couples them to an anti-CD3 system to activate a T cell response and eradicatetumor cells. The majority of the pipeline is in Phase I, but Immunocores lead candidate IMCgp100 has made it to the pivotal stage in uveal melanoma and cutaneous melanoma. Beyond immuno-oncology, the company is looking to expand into infectious and autoimmune diseases.

Oxitecs founder and CEO Hadyn Parry waded into the thorny issue of GMOs and engineered sterility to stem epidemics of mosquito-borne diseases like Zika, as well as malaria and dengue. As he explained at Refresh earlier this month,Were not using toxic chemicals to fight these diseases but were using themosquitoto fight itself.

The company has since been able to reduce mosquito populations of the Aedes aegypti species by an incredible80-90% by releasing Oxitecs so-calledFriendly Aedes mosquito in field trials in Brazil, the Cayman Islands, the US or India.The results from this technology sealed Oxitecs exitto become part of Intrexon for 146M ($160M) in 2015.

After closing last years largest fundraising round of 120M, Oxford Nanopore has entrenched its position as a British biotech unicorn with nearly 500M raised in total since it was founded in 2005. Its MinION pocket sequencer, which was just used to sequence whole human genomes, has the potential to democratize genome sequencing and disrupt the market and you know the company isserious when onegets hit witha lawsuit from Illumina, as Oxford Nanopore did in 2016.

The biotechs device hinges on a nanopore that directly reads a DNA strand in an electrical, single-molecule and label-free process.CEO Gordon Sanghera told methat the companys R9-Series nanopore is able to read more than one billion bases per 48-hour run with up to 97% accuracy.The company has designed the MinION for broader use,targetingtheclinical diagnostics niche with aFlongle attachment; but the device isalsofinding use in academic research.

PsiOxusworks on oncolytic viruses that turn those so-called cold tumors hot by stimulating an immune response, as CEO John Beadleexplained to us. Theplatform, Tumor-Specific Immuno-Gene Therapy (T-Sign), uses a viral vector to deliver anti-cancer therapeutic transgenes to tumoral cells. In particular, NG-348 encodes the gene forMembrane-integrated T-Cell Engagers (MiTEs), T-cell activating ligands located on the cell surface.

This technology wonPsiOxusa 850M deal with BMSlast December, after a whopping 34.7M (25M)Series C propelled by Neil Woodford, GSKs VC arm and Imperial Innovations in 2015.

PsiOxus isnt scientific co-founder Leonard Seymours only company healso co-founded Oxford Genetics.As CEO & co-founder Ryan Cawood told me, the companywas born when the teamfound thattesting gene therapy plasmidswasincreasingly tough because we justcouldnt make them. Typically, theyre built from an amalgam of sources with no standardization.

So, Oxford Genetics set out to improve DNA design with its synbio-based SnapFast platform, and the team believes in its potential to improve cell and gene therapies through this approach to personalised medicine. Backers like Innovate UK, which handed the company a1.61M (1.8M) grant in January, are buying in.

Though still in its infancy, SpyBiotechmade a splashydebut earlier this year with a4M (4.7M)seed round backed by none other than Googles venture capital arm, GV.Itstechnology hinges on the bonds betweenstrep throat bacteria, Streptococcus pyogenes: the founding academics engineered the bacteria,nicknamedSpy, to make the connection without disrupting the antigen or virus-like protein (VLP)folding.

Vaccinesare tailored to a specific disease by tetheringa VLP to an antigen, but the existing method ofgenetic fusionis costly and unreliable.SpyBiotechs method opens the door to a new generation of more robust vaccines spanning a broad range of diseases that the legendary Greg Winter says we so desperately need.

OxStem is developing cell programming therapies that could treat a range of usually age-related conditions, including dementia, heart failure, macular degeneration, diabetes and cancer, based on the research of spin-off sultansKay Davies, Angela Russell and Steve Davies. In May 2016, the company claimed the title of Largest Fundraising for Academic Spin-Out in a 21.4M roundto which Craig Venters Human Longevity fund contributed.

Oxstems strategy uses a new class of small molecules that can modulate or stimulate endogenouscellsto awakendormant cellular processes. These includerepairand stem cell functions. Since the range of applications is so broad, OxStem has had plans to spin out a number of daughter companies,OxStem Cardio, OxStem Neuro, OxStem Ocular andOxStem Oncology, which is most advanced.

Since we first met KarusTherapeuticsin 2015 to talk about their small molecule therapies for cancer and inflammatory disease, the company has entered the immuno-oncology fray. Its now developing a PI3K-p110/ inhibitorto inhibit cancer cell growth and metastasis: KA2237begana Phase I clinical trial last fall in partnership with MD Anderson Cancer Center, and this lead candidate could be a first-in-class small molecule to fight tumor growth and cancer metastasis.

Since it was founded in 2005, Karus has raised nearly 11M, excludingthe yet undisclosed remainder ofits Series B. That might not seem like a lot, but the company has established itself as solid enough to grow its headcount to at least a dozenemployees to inch its programs towards the clinic.

Oxford BioMedicais one of those companies that has been around for ages, having apparently reached a sustainable equilibrium.It was founded in 1995 to developlentiviral vectors for gene and cell therapy applications, anditwent public in 2008; its market cap now clocks in at164M (186M). Most recently, Orchard Therapeutics signed on as a partner to use Oxford BioMedicas vectors in its ex-vivo stem cell gene therapies for rare diseases.

While itsmodus operandiis to out-license its technology, Oxford Biomedica is receiving its fair share of glory. The companys technology is an important component of Novartis stellarCAR-T therapy, CTL-019. The drug from this Swiss pharma wowed ASH attendees last winter with its 82% response rate in a Phase II trial for B-cell acute lymphoblastic leukaemia (ALL) and may very well winthe race to be first to market in CAR-T.

Sometimes referred to as the sister company to Immunocore, Adaptimmune deserves its own attention as a potential immuno-oncology success story. This biotech uses whole adaptive T cells from patients rather than biological molecules derived from them. Notably, while Immunocore remains private, Adaptimmune went publicin 2015 with an huge IPO of $191M (157M) on NASDAQ, when it was listed as one of the most volatile of the notoriously volatile biotech stocks.

Though its stock is now less than a third of its original value after some procedural hiccups that led to a partial hold, the company has thesupport of Big Pharma player GSK and one of the largest headcounts on theUK biotech scene. With its 312 employees and a respectablemarket cap of427M(488M), even if thats a third of what it once was, Adaptimmune is more than holding its own as one of the top biotechs not just in Oxford but the UK.

Images via Oleksandr Kostiuchenko, MR.Travel, CI Photos, Digital Photo, sumroeng chinnapan, isak55, Visuta, mspoint, bluebay, GiroScience, Maryna Olyak, Tonhom1009/shutterstock.com

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Advanced Potions: The Top 10 Biotechs Brewing at Oxford - Labiotech.eu (blog)

Okay, so seriously, imagine this.

In order to help cure cancer, researchers are working with microscopic 3D printers to make tiny little harnesses for sperm, like one little harness per sperm.(I presume one size fits all but I need to check.) And what do these sperm harness actually do? Well they help deliver the sperm, now soaked incancer-curingchemicals, far into the nether-regions of women who need the medical treatment.

The spermharnesses actually have tiny little micromotors Im telling you this is crazy but true stuff.

It all started because, as you may well know, the vagina, cervix and uterus are considered a harsh environments for medicine. Apparently, this environmentmakes drug delivery difficult and gynecological cancers notoriously hard to treat. So after years of study (and who even thought of this in the first place)researchers believe the answer to this may lie in sperm. I can hear men all over the world rejoice, high five each other and celebrate their contribution to cancer research.

Be that as it may gentlemen, this study isntjust the latest debate in the war of the sexes its actually an incredible breakthrough. Scientists at the Institute of Nanosciences in Germany realised that while the natural chemistryof our lady parts tends to dilute most forms of treatment before they can reach the site of the cancer, the human male naturally produces something which thrives in this environment.

This promising study suggests that sperm may be the future of gynecological cancer treatment. Awelcome developmentin an area where an estimated 275,000 women die every year from cervicalcancer, 287,000 from uterine cancer and 140,000 from ovarian cancer.

Just because you have access to a 3D printer doesnt mean you can make a sperm harness. Trust me. I know.

Mariana Medina-Snchez and her team in Germany led a study looking into the unique drug delivery benefits human sperm could provide. They found that when sperm is submerged in an active ingredient known to treat cancer, it absorbs large doses.

The sperm can then be assembled into microscopic, 3D printed, mechanical harnesses, forming sperm-hybrid micromotors (trying saying that 10 times fast) In something out of a science fiction movie the sperm is then directed towards the tumor through the use of external magnetic fields.

How fast can a sperm powered by a micromtor and an external magnetic field actually go? I have no idea.

Once the sperm reaches its destination the harnesses relinquish their grip and the sperm is free to swim towards its target. In theory, the sperm can then burrow deeper into the cancerous tissue and expose more cells to the treatment than ever before.

During experimentation the team noticed that the sperm-hybrid micromotor reduced cancerous cells by 87% in just 72 hours.

The sperm were found to not only protect the drug against dilution, but also not to trigger the immune system. Triggering of the immune systemhas been a challengein previous studies where, for example, treatment was delivered usingbacteria.

Further studies are needed to perfect this method of treatment no gentlemen, at this point, no further volunteers are currently needed to assist. But, the preliminary results hint at a better future one where you will be more equipped to fight gynecological cancer and perhaps other diseases as well (watch the below video for more details).

If you are interested in reading more about this amazing technology, click here for MarianaMedina-Snchezs study.

I still want to know who was first sitting around the lab and said, hey I know what we can do, lets get some sperm, a tiny microscopic 3D printer and then we will make harnesses for micromotors.

That person? They are a genius.

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Tiny Little Sperm Harnesses Are The Cutest Thing Ever. - Longevity LIVE

Democratising data - making information available to all staff at an organisation - takes power away from managers and risks exposing a misalignment of objectives.

That's the opinion of Paul Fitzpatrick, consultant at Human Longevity, speaking at a recent Computing IT Leaders Forum.

"The alignment of objectves is key to an organisation," said Fitzpatrick. "And where objectives aren't aligned, data can make that situation more transparent. Culturally it's a big leap if everyone has access to the same dashboards. With data comes control, so [democratising data is] putting control in hands of people not executives. If you do that, where there's misalignment of objectives, it will become more obvious," he argued.

Jason Nathan, group MD for data at data analysis firm Dunnhumby explained that people will interpret data in ways favourable to themselves and not necessarily the company, if their objectives aren't properly set.

He used the example of supermarkets, and the complexities inherent even in what seems to outsiders to be trivial data.

"It all boils down to the definition around the data," said Nathan. "It may sound like an extrordinary thing to say, but even something like knowing how much did this product sell by value over this week is really hard. How much time do you allow for returns? What about promotions? How much value do you ascribe to these products from multi-buy packs? People try to game the system in their favour if you allow free reign at a granular level.

"In any job, you see people who act at times in the company's best interests, and at times in their own. At a well managed company people always act in their best interests, which happens to align with the company's. But that's a nirvana which is usually unattainable."

Nathan continued, explaining that when fully democratising data at its most granular level, the interpretation placed upon that data causes a lot of friction.

"As soon as you place a layer of interpretation on top, you're not democratising that data, you're allowing someone else to game it, and you're not allowing unfettered access," he said.

"Around 1832 we had universal suffrage. We need the same thing for data," said Bob Tulloch, technical director at Walnut Medical.

Gopal Sharma, global practice head - strategy and architecture at Liaison explained that organisations need to create an enterprise data layer into which everyone has visibility.

"This will then deskill the roles themselves by establishing business rules and logic around data validation, that's the opportunity. Make that data available for anyone to use, analyse and create algorithms for. That requires a very visible and engaged leadership, and each organisation needs to look inwardly at the blockers they have."

Earlier the panel had argued that Google can sometimes lose interest in some aspects of its cloud offering and not keep them updated as much as they should.

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Democratisation of data can lead to organisational problems, says expert panel - http://www.computing.co.uk