A DNA Sequencer Cheap Enough For (Some) Doctors' Offices

cylonlover writes "Until recently, DNA decoding machines — fitting in the US$500,000 to $750,000 price range — would take weeks or even months to sequence a human genome, and the whole procedure would cost $5,000 to $10,000. That could be about to change, however, as Life Technologies introduces the Benchtop Ion Proton Sequencer — a machine that may finally deliver the power of genetics into the hands of ordinary doctors thanks to its $149,000 price tag and ability to decode a human genome in one day at a cost of $1,000."

Unforeseen consequences

[bonch]

Warning--side effects may occur.

Re:Unforeseen consequences

[grantek]

This is a completely different machine, it's not the one that TSA agents will use to remotely scan your DNA...

Re:Unforeseen consequences

[AHuxley]

Give blood for a US visa? They can look for the strength of your VMAT2 (God Gene, spiritual experiences) gene.
If you light up, your fanatic potential is noted.

Re:Unforeseen consequences

[justforgetme]

omg, the days of GATTACA are finally here! Now I'll never fly to mars ${sadface}

Re:Unforeseen consequences

[Samantha+Wright]

You may still fly to Mars! But best give up on Jupiter; your heart is crap.

Re:Unforeseen consequences

"If you light up, your fanatic potential is noted & an invitation to join the Republican party is dispatched."

FTFY

Re:Unforeseen consequences

Awesome movie. Sad reality though.

Re:Unforeseen consequences

Doctors over diagnosis there patients anyway---- You go in for an exam come out with high blood pressure ( the "old standard" was normal pressure for years) cancer, some 10 acute "diseases" that seem to be false. Now you want to give them this to aid in them sucking your health and wallet dry. I would be useful but it should be kept to someone medically trained to use/understand DNA and what the problem maybe.

Before you go on over what doctors I go to, it was meant to poke fun at the medical industry. Several people go in for one thing and end up continue to come out with something else. Everything is a disease solely for the prescription drug industry to make money. Very sad, you want to eat healthy foods but they have pesticides through out (even organic has some downside to it), the meat is littered with antibiotics or hormones.Now the medical industry is destroying human health with a vast rainbow of drugs that cause more problems then what you were diagnosed with

Re:Unforeseen consequences

[MacGyver2210]

It turns you into Jeff Goldblum?

Re:Unforeseen consequences

[smi.james.th]

Weren't they going to Titan in Gattaca?

FWIW, $1000 is still somewhat expensive and it's just scanning genes at the moment. It's not actively messing with the genes of a zygote as was happening in Gattaca.

For the moment, anyway.

Re:Unforeseen consequences

[zippthorne]

Half of what was happening in Gattaca. Not even the interesting half.

Messing with genes was the logical response to the first half, though, which was gene discrimination. Or did you not notice that the main character was smart enough and driven enough to become a rocket engineer, but because of a chance of a flaw in other areas was relegated to menial labor.

It's not just that they wouldn't let him be an astronaut, either. They wouldn't even hire him as an engineer at all, as a "bad risk." And his love-life was implied to have suffered as well, with the matchmaking sequencers on every street corner....

The movie was about the horrors of discrimination, and the virtue of overcoming them, not gene manipulation, which is not a necessary precondition to gene discrimination. Regardless, I think it was probably supposed to be an allegory to present-day race discrimination, but with a narrative trick to make the character white, so white people wouldn't have any preconceived notions getting in the way of the message, rather than a direct prediction of the future, however prescient it may appear to have been.

Re:Unforeseen consequences

[smi.james.th]

That's a very good post. Someone mod parent up, please!

Re:Unforeseen consequences

[GameboyRMH]

In Dead Space 2 the Unitologists would do various physical and psychological tests on prospective members to weed out the skeptics.

Re:Unforeseen consequences

[cbiltcliffe]

They also conveniently forget to mention the "side effect" that you need a $75,000 computer setup to analyze the data the $149,000 machine spits out. So in reality, this is actually a $225,000 machine, plus an IT person to manage the hardware.

Re:Unforeseen consequences

[mrops]

Gene discrimination has been happening for ever, some call it Evolution.

Re:Unforeseen consequences

[Paul+Fernhout]

Whie I like your general points on the movie, if Gattaca's biotech was so advanced, why could the protagonist not just alter his own DNA etc.? Or maybe Gattaca's biotech was not really as advanced as one might think?

Re:Unforeseen consequences

[climb_no_fear]

Not to mention that it wouldn't hurt if you doctor was a trained geneticist...

Re:Unforeseen consequences

[serialband]

The biotech was the plot vehicle for the real story of the discrimination and it wasn't really about the tech. The movie was more about the human drive and imagination.

There are always plot holes in movies. If you're going to pick at everyone of them, you couldn't enjoy very many movies.

Re:Unforeseen consequences

[climb_no_fear]

Engineering changes in DNA is done a the single cell cell (i.e. stem cells and fertilized eggs), not in a fully developed organism with tens of trillions of cells.

That's why no one has cured cancer with genetic engineering, you have to fix every single tumor cell.

So the engineering would have to occur between generations, i.e., in his children, not in him.

Re:Unforeseen consequences

[Paul+Fernhout]

Unless the engineering was more sophisticated. :-)

Like retroviruses, or growing compatible organs from scratch using 3D printing, or whatever.

There are probably levels of sophistication in genetic engineering.

One promise of nanotech is also to do the same -- modify every existing cell.

Star Trek sometimes does that with the "Transporter" too.

Re:Unforeseen consequences

But *the Cloud*, man. 1e5 KWh of CloudTime will come out as a few dollars and just a *little* of your information for a company to use for 'Marketing' purposes.

After all, who doesn't want Google/Apple/Microsoft/The Gubermant knowing your nucleotides?

Re:Unforeseen consequences

And if you don't have any, then you're one of those dirty atheists and shouldn't be allowed in the country. ...somehow, I can't think of a way to make my sarcasm come through. This makes me a little sad.

Hospitals

I predict that the first buyers will be University research hospitals, and the Mayo Clinic.

It needs to drop a bit more before seeing it at your local pediatrician's.

Re:Hospitals

[jamstar7]

Love to scam one of these puppies up when the price drops to a couple K. Especially if it has a 'write mode' as well.

Think 'gene hacking' as the next 'nerd' occupation...

Re:Hospitals

DNA is a read-only media. They'd also need to invent DNA-RW.

Re:Hospitals

[Samantha+Wright]

Gene hacking already is the next nerd occupation (I should know; I'm in the middle of it. Mozilla even funds projects for it.) Here's one starting place if you're really interested.

About the read/write thing: synthesizing large amounts of DNA from scratch still costs ungodly amounts of money. Further, the ABI IonTorrent system being advertised here is a destructive read; you have to treat a blood sample with a large number of chemicals and then stuff it in a big machine. It's no Star Trek scanner.

Re:Hospitals

[justforgetme]

synthesizing large amounts of DNA from scratch costs ungodly amounts of money

can't you just write one DNA sequence, put it in a cell and grow it?

Re:Hospitals

[Samantha+Wright]

Yes, but it's fraught with errors, and making a single molecule longer than a few thousand bases costs a great deal. A bacterial genome is 0.4-3 million bases; humans are 3.1 billion in total. That's why only the Venter Institute has done it.

Re:Hospitals

[bill_mcgonigle]

It needs to drop a bit more before seeing it at your local pediatrician's.

And I'm not sure that it ever will. How long has generating a CBC been a solved science? But the pediatrician will still send you over to the hospital's phlebotomy lab to get one.

I guess they do do instant strep tests in the office. When a DNA sequence costs $15 including equipment perhaps they'll do it.

Re:Hospitals

[justforgetme]

You really shine in biology, don't you?
BTW, homepage down?

Re:Hospitals

[lightknight]

More interested in the capacity to read / write DNA in vivo, but I'll take what I can get.

Re:Hospitals

[Forty+Two+Tenfold]

Gene hacking already is

Yes.

Re:Hospitals

[cperciva]

The only reason they do instant strep tests at MD offices is that they want to know the results before you walk out the door. The same goes for rapid STD tests: If you walk out the door and have to come back to get the results later, there's a chance you won't return.

A DNA test is the ultimate in non-urgent tests, and is going to remain something you head off to the phlebotomist to get done... right up until the day where they are done routinely at birth and you leave the hospital jugging a baby, birth certificate, and a flash drive containing its DNA sequence.

Re:Hospitals

It needs to drop a bit more before seeing it at your local pediatrician's.

And I'm not sure that it ever will. How long has generating a CBC been a solved science? But the pediatrician will still send you over to the hospital's phlebotomy lab to get one.

I guess they do do instant strep tests in the office. When a DNA sequence costs $15 including equipment perhaps they'll do it.

And insurance companies still fight if a CBC includes platelets (adds maybe $1 to the bill)....
good luck getting any useful medical utility, other than the cheap ability for health and life insurance companies to GATTACA us
(I'm and MD and PhD and I don't like this idea)

Re:Hospitals

[pjt33]

Since you didn't link them, I assume you missed the previous Slashdot discussions on gene hacking as a nerd occupation.

Re:Hospitals

you leave the hospital jugging a baby, birth certificate, and a flash drive containing its DNA sequence.

Actually, you don't leave the hospital with a birth certificate. They are issues a few weeks later and mailed to you. At least that's how it is here in Michigan.

Re:Hospitals

[RDW]

... right up until the day where they are done routinely at birth and you leave the hospital jugging a baby, birth certificate, and a flash drive containing its DNA sequence.

Which might happen sooner rather than later:

http://www.forbes.com/sites/matthewherper/2012/01/10/not-quite-the-1000-genome-but-maybe-close-enough/

"Yale geneticist Richard Lifton, who was the first to document the use a DNA sequence to diagnose a disease, is looking at utilising the Proton for clinical work. In the state of Connecticut, where Yale is based, infants are tested for 43 different genetic mutations that need to be detected early in infancy. The Proton could be a better way to do that that traditional methods, especially given its ability to deliver results quickly."

There's going to come a point when even whole genomes are cheaper to do than a few dozen separate conventional tests.

Re:Hospitals

Yeah, but 99.5% of the 3.1B base pairs in humans are the same. I could see some kind of production line for that as a starting material that you can buy over the internet. Then you need to "tweak" the last .5% and voila, you have your own custom made human, a clone army, whatever.

Re:Hospitals

[timeOday]

Why wait until birth? If your DNA doesn't pass muster, you'll probably be rejected as a zygote and head off to the incinerator with 99% of your siblings.

Re:Hospitals

[Samantha+Wright]

5% of the whole human genome is under evolutionary pressure (i.e., we know it does something.) 1% of it contains protein-coding genes, most of which are non-negotiable and critical to living. It's actually only about 0.1% of the total DNA that changes from person to person.

Re:Hospitals

[Samantha+Wright]

I'd like to think so.

As for the homepage, it should be back up, and I'm planning on moving it to a colo within a week or two (primarily because I'm sick of the reverse VPN dying repeatedly.)

Re:Hospitals

[Samantha+Wright]

'fraid so—wasn't active then. Although the second one mentions Reshma; I'm pretty sure I've e-mailed her before, if that lends any credibility. :)

Re:Hospitals

[Samantha+Wright]

Close enough.

my penis

your anus

Don't believe the hype

There are two unfortunate challenges that the Ion Proton approach hasn't yet solved. The first is that the steps required to get the DNA out of human cells and into the sequencer (DNA extraction and especially library preparation) are still frustratingly complex. Their OneTouch device simplifies parts of the library prep but there are still many steps that require highly skilled people doing hours to days of work.
The second major issue is that the genome is being read out in fragments of 200-400 nucleotides, then needs to be assembled. The human genome is full of repetitive regions that are much longer than 200-400nt and when one gets a sequence read from one of these regions, it's can be very difficult to determine which of the copies of the repeat region that sequence came from. Better statistical models and algorithms for genome assembly may solve this to some extent, but there are fundamental limits to what can be done with short sequence reads. Other sequencing technologies don't suffer the short read problem, Pacific Biosciences' hardware for example can read several thousand nucleotide fragments. Mate pairing strategies might be used on the Ion instrument but the library prep for these involves considerably more challenging and manual lab work.

Re:Don't believe the hype

[ColdWetDog]

The third problem (once you solve the first two) is what the hell you do with all that information. At present, having a complete readout of your genome doesn't get you very far. Even after you've figured out what diseases that you are more at risk for, what do you do? Well, you keep an active, healthy lifestyle, drink in moderation, don't smoke etc. You didn't need all of that info for me to tell you that.

I don't see this in doctor's offices (except for the boutique practices that do everything to / for you for the specific purposes of lightening your wallet). Maybe it will allow smaller research groups to tackle projects that they couldn't afford to do. But it's a long way to clinical utility.

Re:Don't believe the hype

[Samantha+Wright]

Pacbio promises a trillion unicorn farts per second. It's hard to take them seriously. As far as medical applications are concerned, the read length in the Ion Torrent system is ten times the size it needs to be, since most (known) diseases occur due to mutations in the very specific and non-repetitive exome, or in its close vicinity. No one (that I know of) has ever seriously proposed using this hardware for de novo sequencing of large eukaryotes, especially since the machine currently on offer doesn't have the well capacity to sequence the whole human genome!

That being said, there's always paired-end reads. I'm guessing the protocol for doing so with this system doesn't exist yet, but they tend to solve most of the repetitiveness problems for shorter read lengths.

Re:Don't believe the hype

[Samantha+Wright]

You archive it until you need it. A situation-specific microarray might cost a hundred dollars; those tend to stack up with every hospital visit. With whole exome sequencing like this, you pay the fee once, and have all* the data medical science will ever need about you.

* Not counting repetitive elements, promoter regions, UTRs, spacer DNA, or the epigenome, all of which are known to describe at least a few diseases.

Re:Don't believe the hype

[backslashdot]

"the read length in the Ion Torrent system is ten times the size it needs to be"

Uh no. Not at all.

"most (known) diseases occur due to mutations in the very specific and non-repetitive exome"

The problem is that if it does occur outside of this, there's be no way to tell where exactly it is. Second, even if it is within the non-repetitive region .. a mutation could make matching the sequences difficult since it wouldn't be certain if you're dealing with an overlap or a mutation. The reason most known diseases occur due to mutations in non repetitive areas is because those are the easiest areas to detect. The unknown diseases probably occupy the other spots.

For disease specific mutations such as cancer the only way to detect the mutations is with long reads. If you want to cure cancer there needs to be a way to do long reads with single cell sequencing.

Re:Don't believe the hype

The third problem (once you solve the first two) is what the hell you do with all that information. But it's a long way to clinical utility.

Well, if by "long way" you mean five years, then yes, it's a long way.

On the other hand, in five year when this technology gets of the ground, it will transform diagnostic medicine in the same way that the automobile transformed personal transportation.

One huge application is diagnosis of infectious disease. Not only will you know whether what you have is viral or bacterial, if it's bacterial you'll know exactly which antibiotics will work. And you'll probably even be able to correlate you infection with known outbreaks: "There's been 50 other infections with this pathogens in the northeast corner of this city over the last two weeks."

The other huge application is birth defects. Many birth defects are recessive and this technology will tell couple which birth defects they are both carriers for - and could pass on to their children. Also, in the case of most mental retardation, the actual causative mutation isn't known (it doesn't have distinct symptoms) but when the comprehensive databases of human mutations start coming online, it will be possible to know exactly which mutation is causing the problems. And, in rare cases, that will even lead to successful therapy (the other cases will have to wait for general gene therapy).

Bottom line: high throughput sequencing for medical diagnosis is going to be one of major advances of this century.

Re:Don't believe the hype

[lbbros]

There's another problem to bear in mind: coverage. What is coverage exactly? In terms of "next generation sequencing" (to which this machine belongs to) is how well a part of the genome is covered (sequenced), and that in turns means that the number of fragments (100-150 in the case of Ion Torrent) read for a specific region must be high as possible (those are called "reads").

A good coverage allows you ensure that what you're seeing is real and not some sequencing errors (all technologies suffer from certain types of errors). In the case of Ion Torrent, you usually sequence fragments up to 1 Gbp of sequenced material (G base pairs of DNA), which isn't enough to cover the inter-genic regions or other structural DNA. So usually you do a "reduction step" by either only selecting a handful of genes to be sequenced (mutation screening for example) or by sequencing only the "exome" (exons are the parts of DNA that are actually transcribed to mRNA, the exome is a collective term for all the exons in the genome). That may be useful per se but it's nowhere near a complete genetic map for one individual.

Equipment to do that is much more expensive (500K USD, not counting reagents and other machines).

Re:Don't believe the hype

[mapkinase]

PacBio produces a lot of errors.

Re:Don't believe the hype

[RDW]

With whole exome sequencing like this, you pay the fee once, and have all* the data medical science will ever need about you...* Not counting repetitive elements, promoter regions, UTRs, spacer DNA, or the epigenome

Not just exome, but whole genome in about a year (they claim), so everything except the epigenome. Some interesting discussion here:

http://pathogenomics.bham.ac.uk/blog/2012/01/ion-torrent-proton-the-chip-is-not-the-machine/

http://seqanswers.com/forums/showthread.php?t=16709

Re:Don't believe the hype

[RDW]

If the 'Proton 2' chip (which we probably won't see this year) lives up to the hype, then with reasonable assumptions about read length and numbers of active sites, it may manage whole genome at 30x:

http://seqanswers.com/forums/showthread.php?t=16709

Re:Don't believe the hype

[RDW]

For disease specific mutations such as cancer the only way to detect the mutations is with long reads.

This really isn't true. Though it would be nicer to have longer reads, short read sequencing (exomes or whole genomes) is actually proving to be very successful at picking up many novel mutations in cancer. Discovering tumour-specific somatic mutations is a particularly nice application for this technology, as you can often do a direct pairwise comparison with the patient's normal germline DNA (e.g. blood DNA if you're working with solid tumours). Typically results will be validated by another technique (e.g. conventional Sanger sequencing), but with a decent analysis pipeline you shouldn't get too many false positives from the NGS.

Re:Don't believe the hype

[Rutulian]

One huge application is diagnosis of infectious disease. Not only will you know whether what you have is viral or bacterial, if it's bacterial you'll know exactly which antibiotics will work. And you'll probably even be able to correlate you infection with known outbreaks: "There's been 50 other infections with this pathogens in the northeast corner of this city over the last two weeks."

I think you're overselling this a bit. Sequencing a human genome is not going to tell you whether you are infected with a pathogen, and it won't identify the pathogen. To do that, you will need to isolate the organism and sequence it that way. Also, having the genome of an organism does not automatically make it easier to determine things like antibiotic resistance. In some ways it makes it more difficult, because you have too much information. High throughput sequencing is definitely a great advance for the scientific community but, like all great advances, it's a tool that is useful for some things, not a magic answer machine.

Oh and by the way, everything you mention for diagnosis above can already be done with current methods faster and cheaper than with whole genome sequencing.

Re:Don't believe the hype

[cthlptlk]

There is a very real use case for genomics in the treatment of disease: drug-gene interaction. Just as certain mutations suggest a higher risk for certain diseases, certain mutations also reduce the probability that certain drugs don't work. For example, plavix must be metabolized, so the 15% (or so, can't remember) of people who can't metabolize it should take something else. And there's a well known genetic marker for that.

Of course, that doesn't mean that the test should happen in a doctor's office, and it doesn't require the whole genome. But there are treatment (rather than epidemiological) applications of genomics, too.

Re:Don't believe the hype

[Samantha+Wright]

Yeah, the scaling there isn't exactly an up-hill problem. (In fact, I knew about those plans before I posted.) Still, I'm a little unsure about how good that read length will be at capturing the big picture. It's not going to be exactly suitable for running de novo on mammals.

Re:Don't believe the hype

[Samantha+Wright]

As I said in my journal, I think the gains from the Ion Torrent read length vs. the SOLiD read length (about 10x) don't do as much to probe the depths of repetitive regions as is necessary to be super-useful. Most of what's lost can be made up for with increased coverage. (Insert theoretical and inauthentic-sounding statement about combinatorial magnitude here.) Of course, it only takes one example of two genes a few hundred bp apart with a couple of SINEs in the middle to prove me wrong. :)

Re:Don't believe the hype

[Pseudonym]

You're completely right about sample prep. It's not like you can just bleed into the machine and results an hour later.

On read length, though, a few hundred nt is probably fine for 90+% of diagnostic tasks, given that we have lots of reference human genomes already. Unless it's a cancer biopsy (and sometimes not even then), any sample processed in a doctor's surgery or consumer pathology lab doesn't need to be assembled de novo. Alignment plus statistics will probably do the job just fine.

Another application where long reads aren't really needed is identifying infections. At the moment, if you walk into a doctor's surgery with flu-like symptoms, your doctor is essentially guessing whether it's a virus or bacterium. If we could tell that within a day, there'd be far less antibiotic misuse.

Re:Don't believe the hype

[Pseudonym]

Sequencing a human genome is not going to tell you whether you are infected with a pathogen, and it won't identify the pathogen. To do that, you will need to isolate the organism and sequence it that way.

Actually, you may not need to isolate the organism at all. If you really had a "just stick a sample in the machine"-type reader (which this box isn't), and copy of a few human reference genomes and a library of known pathogens, you could separate the reads just using simple statistics. We do this today with mixtures such as gut flora samples or cancer xenografts with varying degrees of success. The statistical models are getting better every day, though.

Of course, what constitutes an "infection" is partly context. You're supposed to have a lot of e. coli. What matters is where it is.

Also, having the genome of an organism does not automatically make it easier to determine things like antibiotic resistance.

True enough. The "genes" for antibiotic resistance often turn out to be plasmids. Chances are that a lot of your gut flora are already resistant to various antibiotics, so looking for those plasmids won't necessarily help you determine whether or not the pathogen is.

Re:Don't believe the hype

[Pseudonym]

I am not a biologist, but I am a bioinformatician. So I can BS about combinatorics slightly more convincingly.

Even though de novo assembly for most medical diagnostic purposes is a waste of time, I should point out that most de novo assemblers (including ours) split up long reads into short reads for error correction, then piece the reads back together. In that sense, if all you want to do is find SNPs or other small variants, read length is irrelevant given the same coverage, especially compared to the biasses introduced during sample prep and PCR.

Having said that, the comparison probably isn't fair. Ion Torrent will probably never beat SOLiD on quality. Its selling point is always going to be price, which is why it may be feasible to put one in every consumer pathology lab (though not in every GP surgery).

Re:Don't believe the hype

[Samantha+Wright]

Yeah, I'm a bioinformatician too, not really a biologist, but I figured I should keep it obvious for my signature. :) And yeah, you raise a very good point about de novo techniques; velvet will go as short as 5 bp when it wants to really get something done, as I recall.

Re:Don't believe the hype

Other sequencing technologies don't suffer the short read problem, Pacific Biosciences' hardware for example can read several thousand nucleotide fragments.

Yes, but Pacific Bioscience's accuracy isn't anywhere near that of other next-generation technologies. Inaccuracies make their de facto read-length much smaller.

Re:Don't believe the hype

[Rutulian]

We do this today with mixtures such as gut flora samples or cancer xenografts with varying degrees of success.

Oh yes, this is true. However, it is still fairly complicated and I'm not sure if it is a better (faster/easier) way to diagnose. Take, for example, strep throat. What does that entail, some Streptococcus variety (likely pyogenes) growing in your throat and threatening to invade your lungs. So you can cough into the machine and it can sequence everything, and you can use a fancy statistical model that somehow lets you differentiate between the Streptococcus growing in your throat and the Streptococcus that is a normal part of your oral flora within some degree of confidence. Alternatively, you can do a throat swab, and there are plenty of assays that you can do in minutes to hours (ELISA, PCR) to determine whether or not it is Streptococcus and which variant. Antibiotic susceptibility will still take a culture, but it seems to me that this is a solved problem, and whole genome sequencing provides more information than you really need, potentially making the diagnosis much more complicated.

The "genes" for antibiotic resistance often turn out to be plasmids.

Or modifications to the cell wall or translation machinery, such as in the development of vancomycin resistance in some strains. I don't mean to knock whole genome sequencing. I think it's an awesome tool for research purposes. It just isn't a panacea. Microarrays weren't either, for that matter, or pretty much any new development. It's novel and new, so it's cool, it will enable us to do things we weren't able to do before, but we aren't going to transform medicine overnight.

What does it all mean?

Not to demean this excellent advance in the technology but it should be called out that the pace of understanding what all these raw sequences mean is not on a growth path too. Anyone have some ideas for accelerating our understanding of semantics?

It really is a daunting task. The protein codings are just the beginning. We are making some progress on the various (more to come?) regulatory mechanisms and from there we need to know how all of that interacts over the lifetime and various differentiate cell states. Throw in environmental factors and wow, that's a big space to map out. It needs automation but how?

Re:What does it all mean?

[guttentag]

It means that Facebook is going to buy Walgreens or CVS, install these machines in every location and offer sequencing for free (as in you'll have to watch ads during the procedure and they will copyright your DNA). While you are strapped into a chair, a button you cannot reach will light up and you will be invited to opt out of their plan to sell your DNA, simply by pushing the lighted button. This might not seem like a big deal until Zynga targets you with some pointless free game that you are genetically predisposed to become addicted to (free as in you can do absolutely nothing even faster if you give them money).

Re:What does it all mean?

[Samantha+Wright]

There are a few key puzzles we need to crack—protein dynamics, mostly—and then we'll have the ultimate acceleration method: we'll be able to simulate it all. Right now we're content with trying to sort out those challenges, and fixing the disorders we already know how to recognize. It'll keep us busy for a long time. In the interim we'll just play with increasingly clever tricks to sort out the patterns in the sequences, and catalogue lots of people so we have things to work with when the time comes.

Re:What does it all mean?

[Rutulian]

No, I don't think so. Simulation of complex biological systems, especially when you include molecular details like protein folds and conformation changes, takes a tremendous amount of computer time. If you can approximate some things using empirical measurements, you can speed things up a bit, but even so we are pretty far from knowing all of the rules we need to know to simulate even relatively straightforward things like the progression of an infection in a host.

People were saying similar things decades ago when mechanistic enzymology was a hot field. "All we need to know is get binding and catalytic parameters for every enzyme in primary metabolism, and then we will be able to model it." Now, decades later, we still can't even simulate a simple pathway like glycolysis much less all of the interacting pathways.

Re:What does it all mean?

[Samantha+Wright]

The reason I say exhaustive physical simulation is the silver bullet to biological problems is that, while it may be fantastically slow and inefficient, it will finally get us an honest and reliable model of what's really happening. We can then study that model, and determine what optimisations and simplifications we can reliably make.

Traditionally, when biologists try to simplify a system (such as just looking at enzyme binding graphs, an act that makes me nauseous because it's so abstract and useless) we do so with radical reductionist objectives (i.e., only looking at the interactions of couple of genes and their products) and a grossly incomplete picture (of the physics involved in those phenomena.) Further, most such studies are done with empirical measurements, which are really a game of broken telephone and fraught with error margins. It's taking the problem of determining which straw was responsible for breaking the camel's back—and putting it in a wind tunnel.

The modern bioinformatics perspective, of holistic collection followed by logically-backed reduction, avoids all these problems. I'm not saying we'll be simulating biological organisms with absolute fidelity forever, merely that we can't really appreciate the biology until we've seen it in its native environment.

Re:What does it all mean?

[Rutulian]

Well, if anything I think the reductionist models have been much more useful than the exhaustive ones to date. Understanding that there are control points at key steps in metabolism has been much more useful (for understanding and prediction), in my opinion, than previous efforts to model the contribution of every enzyme in the pathway.

Bioinformatics is great. Many advances have been driven by developments in that field. But it is no more a silver bullet than x-ray crystallography was. Right now, efforts to understand native microbiomes is almost entirely driven by bioinformatics, because there is currently no other way to study these systems. But so far, the predictive power has been useless. Knowing which organisms (and in some cases which genes) are present has helped us appreciate the diversity out there, but hasn't contributed much to the clarity of how these micorbial communities develop and change in response to environmental stimuli.

Re:What does it all mean?

[Samantha+Wright]

I'm not really a fan of mass environmental sequencing, because quite frankly it's downright cavalier. There's definitely this misguided undercurrent in bioinformatics (of which Craig Venter seems to be the somewhat unwitting originator) wherein the "grab it all at random, then just keep grabbing until you probably have it all" mentality gets applied to everything. I remember being taught in my fourth-year Computational Biology course by a very well-meaning medical informatician that committing "post hoc ergo propter hoc" was what it meant to perform boolean gene network analysis. Of course, I could tell that this was mostly miscommunication and not really what she intended to say (although seeing her stumble though Word a week later made me somewhat concerned) but I'm pretty sure my classmates (themselves mostly more interested in medical imaging than biology) swallowed it hook, line and sinker.

Collecting data that you don't have enough dimensions to resolve is always a stupid idea, unless you want to answer a very specific question through it (or no question whatsoever) and are certain this will be no problem. Environmental sequencing certainly accomplished the goal of appreciating diversity, as you put it, but I think if someone was claiming that it could help with making sense of what's actually going on, they're probably not very logically rigorous people. I think the best use for the technique would be akin to cDNA library generation, except with species instead of mRNAs, and unique species identification tags instead of ESTs. Now all we need is a really, really big microarray...

Re:What does it all mean?

[Rutulian]

Indeed. I think the problem here is twofold: that there is such an overwhelmingly large number of organisms, and that we don't know how to culture the vast majority of them. So until deep sequencing was fully developed, it just wasn't possible to know what was really out there, aside from hints from a handful of 16s rDNA sequencing projects. Now that we have a much better idea, we still don't know how to do these studies. But there are people who are desperately trying. The human microbiome people are trying to link Lactobacillus to everything, from diabetes to cancer, by looking at the gut microbiome samples of different patient populations. It's pretty unsatisfying overall, but when you think about it the problem is fairly enormous. There are some limits in methodology that have to be overcome before we can really start to address these questions in a more constructive way. Until then, I think we will continue to see this "let's just sequence everything" approach.

A single server

[jamesh]

The Ion Proton Sequencer uses analysis software called Ion Reporter to analyze the data of a single genome on a single server. This speeds up the process considerably and removes the IT-related bottlenecks

Genius! A cluster of computers is an obvious bottleneck and they have made the step of getting a single server to do all the work. I hope they have a patent on that idea.

However, the most important factor in reducing the sequencing speed so dramatically is the introduction of the next generation of Ion Torrent semiconductor chip technology.

Oh. Right. So this is really just using _better_ hardware to do the job.

Re:A single server

[lbbros]

In fact, I think it's just hype. To do proper analysis runs you *need* parallel computing, as these tasks are primarily CPU bound. But a whole load of RAM doesn't hurt, either, especially if you analyze more than one genome at once.

Re:A single server

[RDW]

Reports elsewhere suggest they'll be selling a "$75,000 server" with this machine, which will apparently be able to spit out a fully processed whole genome in a day, and lets them market the whole thing as an 'appliance'. This will be enough for many labs. But if the Proton is anything like their previous sequencer, the unaligned sequence data will just be in a standard text file format that can be uploaded to the local cluster (if you have one) and processed any way you like. Large genome centres may go this route if the basic technology lives up to the hype.

Re:A single server

[cbiltcliffe]

Yes, and I'm betting that $75k server has just a few processor cores in it, which really takes care of the parallel computing problem nicely.
I'm guessing for that kind of money, it's probably a quad core, 4 CPU machine, at least. I can't imagine it needing enough storage to burn through $60,000+ worth of hard drives, so it's got to be a monster processing machine.
My wife (yes, there are married slashdotters!!!) currently works with the previous instrument that Ion Torrent released, about a year ago. It uses a server that's not as expensive as this, and has a few (I think 6) TB of storage. Even if this machine needed exponentially more storage, 60 TB RAID is about than $10,000, even at current flood sale hard drive prices.
Throw in the markup that Life Tech puts on everything they outsource, and you're looking at probably $40k worth of actual computing power.
Heck, for that price, maybe their "server" is actually a small cluster and SAS, conveniently fitted into a single 24Uish rack.

Re:A single server

However, the most important factor in reducing the sequencing speed so dramatically is the introduction of the next generation of Ion Torrent semiconductor chip technology.

Oh. Right. So this is really just using _better_ hardware to do the job.

You misunderstand what the technology is. The Ion Torrent "chip" in the sequencer is a matrix of wells in which the DNA reading takes place. The chemistry is being monitored electronically for incorporation events (nucleotides give off a proton when they incorporate onto a DNA template.) It's not the same as advances in computational power of processor chips although the development of denser semiconductor technology has certainly advanced the Ion Torrent chips.

How does that compare to X-ray machines?

[jcr]

A hundred and fifty grand doesn't sound like a whole lot of money for medical equipment.

-jcr

Re:How does that compare to X-ray machines?

[ColdWetDog]

"Ah, I see you have the machine that goes ping. This is my favorite. You see we lease it back from the company we sold it to and that way it comes under the monthly current budget and not the capital account. "

Yay, progress!

[martin-boundary]

Patient: "So, snif, bhat dh'you bheckon I habh, snif, bhoctor?"

Doctor: "Well, it looks like you have a common cold. But let's be sure, shall we? I just got this new DNA sequencing machine. Come back tomorrow."

The next day...

Patient: "Hebho bhoctor, bhat dho I habh?"

Doctor: "Well, it looks like you have a common cold. That will be $1000."

Re:Yay, progress!

[guttentag]

Patient: "Hebho bhoctor, bhat dho I habh?"

Doctor: "Well, it looks like you have a genetic predisposition to paying exorbitant sums of money for things you don't need. It's called Gullibility. Don't be so sad, it's very common in this country, like a cancer! Just remember that even though it eats some people alive, some people survive! You just need to have balls like Lance Armstrong, avoid drugs and wear yellow shirts in the summertime. That will be $1000. Now that I know what to look for, I can zero in on this and accurately determine the likelihood of recurrence if we sequence your DNA just one more time and you give me your debit card pin number."

The next day...

Re:Yay, progress!

Currently it's like this:
  Patient with walking pneumonia: I'm really sick - I think I may have walking pneumonia - can I have some antibiotics?
  Doctor: I have no way of knowing what you have - but there are some vague claims that over use of antibiotics leads to resistance - so just go home and see what happens.
  Patient: "goes home" for a couple weeks. That is, patient spends next couple weeks out in community infecting other people - including an old person who ends up in the hospital costing everyone's insurances tens of thousands of dollars.

Then original patient gets worse and goes back to doctor.
  Patient with walking pneumonia: It's been two weeks and I'm getting worse. It's really hard to breathe.
  Doctor:OK, I still have no way of knowing what you have - but I've got a vacation coming up and don't feel like dealing with this with this so just go to the hospital.
  Patient: goes to hospital
  Hospital Doctor: What you have is probably bacterial but I have no way of know which strain of bacteria is infecting you so I'll just give you this broad spectrum antibiotic.

Overuse of broad spectrum antibiotic at hospital leads to development of resistance - and then there's a nasty outbreak of bacterial pneumonia in the hospital that can't be cured with even their broad spectrum antibiotic.

Or, in a few with years when high throughput sequencing is available:

Patient with walking pneumonia: I feel really sick - I think I may have walking pneumonia.
  Doctor: Hmm, you're still early in the infection so it could just be a virus but let's use our high throughput sequencer to check. Just cough into this tube.
  Doctor (a couple hour later): Yes, you do actually have walking pneumonia - and it's a strain that's resistant to penicillin so we'll give you a different antibiotic that's work on this particular strain.
  Patient - gets better in a few days and doesn't infect anyone else

Re:Yay, progress!

Implying the primary result of this kind of technology being more accessible is your (apparently terrible) doctor milking you for money is ridiculous. I guess you would prefer that MRI machines were still only for the super rich.

Re:Yay, progress!

[LordKronos]

Huh? In what way does the cold virus alter your DNA, such that a DNA sequencing machine could be used to diagnose it? And you know, doctors currently have all sorts of diagnostic tests at hand that could be used unnecessarily, yet I've never heard of doctors using an x-ray, EKG, MRI, or anything of the sort to diagnose a cold.

Yeah, I know, it was probably a joke and not meant to be taken seriously, but your score was +3 Insightful, not +3 Funny.

Re:Yay, progress!

More likely scenario, given the current state of the American healthcare system:

Doctor: Well it looks like you have a common cold. Best thing to do would be to get some bed rest.
Patient: But I don't think that's it. Where's that new DNA sequencing machine I've heard about in the news?
Doctor: I can assure you that there is absolutely no indication for such a test with the symptoms you're having.
Patient: How can you be sure? Why not just give me the test?
Doctor: It is an expensive test, and the likelihood that it would tell us something that would drastically change --
Patient: Don't you greedy doctors care anymore these days? I'm the patient. I demand to have the test!

The next day...

Doctor: The test results are back. You have a common cold.

Five years later...

Public: Gee, why is our healthcare system so bankrupt?

Re:Yay, progress!

[timeOday]

Alternately, "I'm afraid you have Bird Flu, please come with me!"

The reason "the common cold" hasn't been cured is because "it" is actually hundreds of different virii. If only there were a way to tell which is which...

In the future the doctor will swab your throat, upload some markers, and the next day the correct prescription (from hundreds) will be FedEx'd to your door.

Re:Yay, progress!

[cbiltcliffe]

Doctor: Hmm, you're still early in the infection so it could just be a virus but let's use our high throughput sequencer to check. Just cough into this tube.

  Doctor (a couple hour later): Yes, you do actually have walking pneumonia

You know those crime shows on TV that where the cop and a computer guy have a crap video from a 320x240 surveillance camera, and the cop asks the computer guy "Can you enhance that?" and the video zooms right in on the suspects face, which then turns from about a 9 pixel smudge into a 10 Megapixel image that's clear enough to see the pimple on the perp's nose?

Yeah....

Just so you know, high throughput sequencing is currently available, and has been for a year or two. The problem is all the lab work that needs to be done to isolate the DNA, purify it, and put it into a solution that this instrument can analyze. (Not to mention in a case like this, the viral DNA would also have to be separated from the patient's DNA, which would probably at least double the processing time.)

All that stuff is manual lab work that can not currently, or for the foreseeable future, be automated, and it takes much longer than a couple of hours.

Another medical money-grubbing bullshit

We still don't know how DNA/RNA/epigenetics work. So-called "junk DNA" are simply ones we don't know what they do.

Our "modern" medicine is still not that far off from the old-school quackery. Ask a practicing physician friend.

Re:Another medical money-grubbing bullshit

[Samantha+Wright]

The term "junk DNA" is now only used by shoddy science journalism. We're quite comfortable with how DNA and RNA do what they do. There's a mystery about what happens on the protein side, and the question about what functional bits of RNA (called microRNA) interact with what genes is sheerly a matter of ridiculously obtuse combinatorics. Say whatever else you will about them, fat cancer research budgets have taught us a lot about the essentials.

Re:Another medical money-grubbing bullshit

[jo_ham]

Can they help us crack Photosystem II? That bastard is frustrating chemists the world over (as far as knowing sort of how it works but not enough of the really key details).

Re:Another medical money-grubbing bullshit

I'll add a clarification about Junk DNA for non-biologist slashdotters:

Although some may use the term 'Junk DNA' erroneously, as analagous to 'DNA with unknown function', this does not mean that the term is not valid. In fact, most of the human genome is certainly junk, in the sense that it demonstrably has no function whatsoever. For example, approximately one-third of the genome is made up of many thousands of copies of long-dead transposable elements (known as LINES and SINES; look them up). A further 10% of the genome is made up of other nonfunctional transposable elements, and about 8% is made up of dead viruses. Much intronic sequence is also junk.

While it has long been understood that some of the 98.5% of the genome that is non-coding DNA is functional, this only represents a small fraction of total non-coding DNA, and in invariably located within the ~10% of the genome that is evolutionarily conserved. This 10% figure also constitutes the most plausible upper limit for functional DNA.

In summary, the current figures we have are that two-thirds of the genome is known to be junk, less than 9% is known to be functional, and almost all the remaining fraction, being non-conserved, is very likely to also be junk.

Re:Another medical money-grubbing bullshit

[Rutulian]

Well, yeah, and the appendix was also a junk organ until quite recently. Just because we don't know what it does doesn't mean it is non-functional.

Re:Another medical money-grubbing bullshit

[Samantha+Wright]

Well, the trick to getting a fat cancer research grant (FCRG) is that you have to be able to contort your pet project into something that somehow conveniently plays into the hands of human cancer research. Photosynthesis might be a bit too far off, but I'm sure you could get good bucks for studying root nodules or the effects of unengineered agrobacterium. Then again, one of the labs I worked in as an undergrad studied the neurodevelopment of C. elegans under a FCRG, so perhaps I'm being too stringent in my definition of contortability.

Re:Another medical money-grubbing bullshit

[Samantha+Wright]

Nah, it's less exciting than that. We're pretty sure that most of the non-functional DNA has no purpose other than functioning as spacer material. When a chromosome is functioning normally in a cell, it forms a roughly spherical shape comprised of many loops that go out toward the edge and then back in toward the middle. The outermost parts of these loops are the starting positions of very important genes, which makes them more accessible to the proteins that are supposed to make use of them. The non-functional DNA provides enough flex room to let the chromosome get bent like this. The bends themselves are accomplished by proteins called histones. One of the ways in which the cell can effect gene regulation is by changing how far out a particular gene's promoter region is.

For this DNA, the important thing about it is that we know the sequence does not matter (or, at least, matters very little.) The repetitive elements that comprise this DNA may provide a gripping point (like handles in a rock climbing gym) but they're not really important themselves. Since humans are so complex and we're so good at finding and storing food, the cell has every motivation to find little tricks like this to streamline these complex processes. Bacteria, by contrast, have absolutely no ability to support the stress caused by chromatin remodelling, and the gaps between genes are typically less than a thousand nucleotides.

That being said, on occasion some of the dead and inactive DNA rises to the challenge and becomes useful. One of the most prodigious components of the non-functional human genome are the corpses of retroviruses that integrated their payloads with us and then became inactive due to mutation. We've co-opted these genes on a few occasions, including once to anchor the placenta to the uterine lining during pregnancy, an adaptation that allows higher mammals to support much larger fetuses. (For comparison, mice lack this.) The cervical plug that forms during pregnancy to protect the fetus from the exterior environment is also comprised predominantly of malformed and misshapen bits of random viral capsid (shell) proteins.

A lot of people assume the genome has to be this nice, neat, clear-cut thing, and get indignant at the shortsightedness of scientists who seem to be arrogant about what is important and what isn't. The truth is that we know a lot more now, and the genome is really more like a giant vibrating box of LEGO bricks that sometimes assembles random bits of useful stuff out of itself.

Re:Another medical money-grubbing bullshit

[Samantha+Wright]

...then again, you probably already knew half of that. It is such a pain to keep track of who knows what in this place!

Re:Another medical money-grubbing bullshit

[shiftless]

In summary, the current figures we have are that two-thirds of the genome is known to be junk, less than 9% is known to be functional, and almost all the remaining fraction, being non-conserved, is very likely to also be junk.

Please frame this and hang on the wall so you can laugh at yourself in 20 years when all of this is proven to be laughably ignorant.

How do you know a piece of DNA isn't being used? Maybe because every time you've created an mRNA library, you never seem to see these sequences expressed? Well, how do you know that the DNA in question isn't activated by some obscure environmental conditions, or other specific conditions which are never seen in your laboratory? How can you really prove that this sequence of DNA is not activated ANYWHERE, EVER, AT ALL? You CAN'T know that, using today's science, because we simply don't understand enough about genetics to really say with certainty that a specific DNA sequence is NEVER expressed.

Re:Another medical money-grubbing bullshit

[Rutulian]

Hehe, yes well, it was a good explanation.

I guess I just don't like the idea of unequivocally claiming that we know exactly how something works. It's just backfired so many times in the history of science. There was a rather famous exchange during the 1970s between Bob Abeles (the guy who worked out the mechanisms of vitamin B12 mediated reactions) and some Harvard chemists who said the chemistry he was proposing was "impossible." Well, long story short, Abeles was right and the Harvard consortium was wrong.

Re:Another medical money-grubbing bullshit

Please read the grandparent post properly. We do know that dead transposons and viruses don't do anything, and even when they were active (long ago), they functioned as autonomous, selfish genetic elements. The impact that these elements had on the host organism was invariably deleterious, just as with active viruses that infect us today.

Please learn more about genetics before pontificating in future. I suggest starting by reading about transposable elements.

Re:Another medical money-grubbing bullshit

If you want certainty, look to mathematics, not science.

I know many slashdotters look down on biologists and biology, but believe it or not we actually have examined the questions you are asking.

Over half the human genome is made up of dead transposable elements and viruses. When these genetic elements were active, they spent many generations expanding through the genome by repeatedly inserting many thousands of copies of themselves throughout the genome. For example, there are around 500,000 LINES and 1,500,000 SINES, almost all of which are long dead (i.e. inactive), and which together make up over a quarter of the human genome. They are no longer being conserved; they have no plausible function; Occam's Razor suggests they are exactly what they appear to be: foreign nucleic acid that invaded the genome for its own purposes.

Re:Another medical money-grubbing bullshit

[cduffy]

...then again, you probably already knew half of that. It is such a pain to keep track of who knows what in this place!

...then again, it's not as if you're writing for an audience of one. I certainly learned something.

Re:Another medical money-grubbing bullshit

[Samantha+Wright]

Glad I could help. :)

Hands of ordinary doctors

[nbauman]

Yes, you bring your doctor a thumb drive with 3 billion base pairs of your genome, coding for 23,000 genes. Do you know what he says?

"What am I supposed to do with that?"

Years ago, people thought that we could find Mendelian genes for all the important things in health and disease. Now it turns out that most of the important things we want to know are controlled by hundreds or thousands of genes, each of which increases the risk by 1%, sometimes less. That's for things like cholesterol, autoimmune diseases, cancer susceptibility, etc.

For the most part, your family history is a better predictor than any genome screening. Gene tests usually aren't useful unless you have a particular gene in your family and you want to find out whether you have it, like the BRCA genes for breast cancer. If your mother died of breast cancer at age 40 because of the BRCA1 gene, and you don't have the BRCA1 gene, you don't have to worry.

Re:Hands of ordinary doctors

[EnsilZah]

Well, obviously you don't bring the raw data to your doctor.
How about you run it through some statistics software and it gives you a list, 5% increased chance for breast cancer, 7% chance of heart attack by age 50, then your doctor can suggest more frequent checkups, changes in diet.

How about this, your government subsidizes a sequencing for every individual (I know getting into Gattaca territory here, also Americans would scream 'socialism!'), say in reverse order, oldest to youngest until you can do one at birth, then you gain a wealth of statistical data with each subsequent year.

Re:Hands of ordinary doctors

[FairAndHateful]

For the most part, your family history is a better predictor than any genome screening. Gene tests usually aren't useful unless you have a particular gene in your family and you want to find out whether you have it, like the BRCA genes for breast cancer. If your mother died of breast cancer at age 40 because of the BRCA1 gene, and you don't have the BRCA1 gene, you don't have to worry.

While I fully agree with this, I can see the potential value of screening for all genetic markers for disease at once, including the ones we are not aware of yet. "We think you're clear now, but there's a slight possibility of a future problem with bone-us eruptus. To make sure you're in the clear, we just need to test for this newly discovered genetic marker for... Oh... I see... You have... Well, 18th chromosome, 1017th pair... Okay, you're clear... Haha, yeah, I guess that would have been a stressful couple of days waiting for the test results! Well, enjoy the rest of your day." Also, it'd be nice to have the complete sequence to yourself and off of your medical records, in case the insurance companies start looking for that stuff. Worried about a marker? Look it up yourself! You've already had the test!

Re:Hands of ordinary doctors

[pesho]

Yes, you bring your doctor a thumb drive with 3 billion base pairs of your genome, coding for 23,000 genes. Do you know what he says?

"What am I supposed to do with that?"

You hit the nail on the head. There is very little if any useful information for a doctor in full genome sequence, and most of it can be obtained with much cheaper genetic tests. ABI is ramping up the hype because they really need this instrument to be a good seller. Their first bet in the field was on a sequencing by ligation machine (SOLID) which did not sell very well.

Re:Hands of ordinary doctors

[Demonoid-Penguin]

Yes, you bring your doctor a thumb drive with 3 billion base pairs of your genome, coding for 23,000 genes. Do you know what he says?

"What am I supposed to do with that?"

Maybe you should get a doctor that knows what an USB thumb drive is?

Then you can move onto the next problem.... (who's your daddy?)

Re:Hands of ordinary doctors

Yes, you bring your doctor a thumb drive with 3 billion base pairs of your genome, coding for 23,000 genes. Do you know what he says?

"What am I supposed to do with that?"

You hit the nail on the head. There is very little if any useful information for a doctor in full genome sequence, and most of it can be obtained with much cheaper genetic tests.

I feel like I'm watching a bunch of guys on horses making fun of the first automobiles. We're seeing the beginnings of the biggest revolution in medicine since antibiotics. This is going to be huge.

Sure, if you already know what you're sick with then a specific test for that condition will, in certain cases, be cheaper. But the point is you don't know.

You walk into the doctor's office with symptoms that could be cold, flu, the onset of bacterial pneumonia, etc. - and, in a few years, high throughput sequencing will tell you exactly which antibiotics/anitvirals (if any) to take.

You have a kid and when he's a few years old it becomes clear that he's got mild mental retardation. You want to know whether the obstetrician messed up during the birth, or your spouse dropped him on his head when you weren't around, or whether he got into the cleaning chemicals under the sink, or whether he got meningitis - or what. Well, if it's genetic, in a few years high throughput sequencing will be able to give you an answer.

Re:Hands of ordinary doctors

[pesho]

I feel like I'm watching a bunch of guys on horses making fun of the first automobiles. We're seeing the beginnings of the biggest revolution in medicine since antibiotics. This is going to be huge.

Sure, if you already know what you're sick with then a specific test for that condition will, in certain cases, be cheaper. But the point is you don't know.

You walk into the doctor's office with symptoms that could be cold, flu, the onset of bacterial pneumonia, etc. - and, in a few years, high throughput sequencing will tell you exactly which antibiotics/anitvirals (if any) to take.

Your car analogy is not very appropriate. To begin with I have been riding the automobile in question for couple of years, and its predecessors (microarrays) for about 10 years. You are completely missing the point that the problem here is not the amount of information that a doctor can potentially get from the full genome sequencing. The problem is that at the current state of the art we are unable to digest this information to a point where a doctor can act on it. The reason is that once you go beyond the simple Mendelian genetics, the interactions between different factors become exceedingly complex. You need to take into account multistate interactions of the genome sequence with epigenetic and environmental factors. In addition, having the genomic sequence will not solve your problem of not knowing what to look for. It will tell you even less about what kind of infection you have. In this case we don't really need to use the latest gadget to replace cheap, fast and reliable immunology tests? Kind of reminds me about the machine that says 'BING'.

As it stands now, doctors have more information that they can process. So if your are looking for a revolution that is just starting look at technologies for integrating large amounts of 'fuzzy' information from patient records, medical textbooks and literature, and various medical test to produce accurate diagnosis. Technologies like IBMs Watson and the NIH sponsored i2b2 is the next big thing in medical care.

You have a kid and when he's a few years old it becomes clear that he's got mild mental retardation. You want to know whether the obstetrician messed up during the birth, or your spouse dropped him on his head when you weren't around, or whether he got into the cleaning chemicals under the sink, or whether he got meningitis - or what. Well, if it's genetic, in a few years high throughput sequencing will be able to give you an answer.

You can get the answer if it is genetic now. So going back to the original comment: What are you and your doctor are going to do about it??

Re:Hands of ordinary doctors

[nbauman]

OK, you run it through this wonderful statistics software and it gives you a list.

Your doctor says, "Normally you would have a 10% chance of getting breast cancer (when you're still young enough that treating it would make a difference), so you should get a mammogram every 2 years. But you have a 5% increased chance for breast cancer, so you have a 10.5% chance of getting breast cancer. You *really* should get a mammogram every 2 years."

There is an increasing list of mutations that really do make a significant difference in risk, like 50% or 85% risk, such as BRCA1 and BRCA2 for breast cancer. I think it's up to a couple of hundred by now. Most of them are fairly rare, with the disease occurring in maybe 1/100,000 births. Most of the people who have these genes know that they have it in their family. (Another difficulty is that unlike breast cancer many of these diseases have no cure or treatment.)

You could make a single gene chip to test for all of these genes, although it's a waste to test me for sickle cell anemia since I don't have any Mediterranean or African ancestry, and it's a waste to test me for Huntington's disease since I've never had it in my family. But if it's cheap enough, and the patents expire, you might as well make a singe test for all the *known* mutations to test at birth. But there's no benefit in sequencing the *entire* 3 billion bp human genome, given our current state of understanding and our understanding any time in the near (5-10 years) future.

There are some useful genetic tests to diagnose cancers for example. You're 60 years old, you get a routine blood test, and you have chronic lymphocytic leukemia. Now there's a DNA test. For patients with a marker called ZAP-70, median survival is 5 years. For patients without the ZAP-70 marker, median survival is 25-30 years (without treatment). Big difference.

Sequencing your entire genome is a cool thing to do. I'd like to have a copy of my entire genome sequence, so every time I read about the discovery of a new function for a gene, I could look up my allele. It's about as cool as a backyard telescope and about as useful.

Re:Hands of ordinary doctors

[nbauman]

"There's a 0.001% possibility of a future problem. Oh, I see, 18th chromosome, 1017th pair... 0.0009% possibility."

Re:Hands of ordinary doctors

[nbauman]

What you're watching is a bunch of guys who have been burning through billions of dollars on the War On Cancer, and still haven't been about to cure (most) cancers. They've hit a few home runs, like chronic myelocytic leukemia and acute lymphocytic leukemia in children, and some of the major cancers have longer life expectancies and less brutal treatments, but it never delivered the promise Mary Lasker and Richard Nixon made of curing cancer (thought it's better than pissing it away on the military). We've learned. Curing cancer is difficult.

You're also watching a bunch of guys who have followed so many wild goose chases that they don't want to follow another one.

Back in the 1990s, I wrote an article predicting the wonderful world of computerized courts in the 21st Century. You'd go into the court records office, press a few buttons, and your documents would appear on the screen like magic. (According to IBM.) Then around 2005 I had to go down to the Federal courthouse in Manhattan to look up the documents in a patent trial that was going on there. I will leave it to your imagination. It was easier to get court documents in Herman Melville's time.

Re:Hands of ordinary doctors

[shiftless]

What if it's a 10% increased probability? For example, in my specific case, where I have a 10% higher chance than average of developing type II diabetes, based on my genome. Would you consider that helpful information? Or how about the fact that according to my genetics my body exhibits an increased sensitivity to Warfarin, a blood thinning agent? Do you think it could be helpful for the doctor to know this information, if I ever require this drug for some reason?

Re:Hands of ordinary doctors

[shiftless]

You are completely missing the point that the problem here is not the amount of information that a doctor can potentially get from the full genome sequencing. The problem is that at the current state of the art we are unable to digest this information to a point where a doctor can act on it.

And you're completely missing the point that flooding the world with tons of cheap genetic sequences will do nothing but make this information EASIER to process and understand. It's a hell of a lot easier to search for patterns when you have a larger quantity of more accurate information to work with.

Re:Hands of ordinary doctors

[nbauman]

If I pick you out of the U.S. population at random, you already have a 10% average chance of developing type II diabetes. If you have a family history of diabetes, that confirms it. So whatever it is you're going to do with that information, do it.

If a genetic test tells you that you have a 10% higher chance than average of developing type II diabetes -- that is, 11% -- would you do anything more than you wouldn't do otherwise?

The answer is no. The additional information from these genetic tests for type II diabetes has such a small effect that they wouldn't make any difference.

People *already* have a pretty good idea of their genetic background from their family history. If your parents had diabetes, that tells you as accurately as any genetic test that you have a predisposition. If your grandfather lost a leg to complications of diabetes, that's the kind of thing that motivates people. Which makes sense.

As for warfarin, yes, different people have different responses and doctors are working out a test to find out in advance. I don't know how far they've gotten, but I expect they'll have a good test someday soon.

However, (1) The doctor doesn't need that information until he prescribes warfarin and (2) You don't have to sequence 3 billion base pairs of DNA to find out. The tests they're working on only test for single enzymes (actually, it's usually easier and cheaper to test for the enzymes than for the DNA that synthesizes the enzyme).

This isn't like sickle cell anemia. These genetic traits that show up in the tests have very low penetrance. The penetrance for sickle cell anemia is 100%. The penetrance for these diabetes genes is 1%.

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ion proton. really?

[schmeathouse]

just wtf is an "ion proton"? a proton is an ion. so what then is an ion proton? a $150,000 benchtop 1 day human genome sequencer and marketing couldn't come up with a better name? or at least a more correct one like "proton ion".

Re:ion proton. really?

[lbbros]

The name for the technology is "Ion Torrent", and albeit the wording there is terrible, it detects, using a semiconductor, the flows of protons in solution to determine which DNA base is being read.

Re: Your sig

[srussia]

I am a biologist. Ask me questions in my journal. I'll give car/computer analogies if possible!

No need for the invite. This is Slashdot. You had us at "Samantha".

Boon for salesmen

[JimboFBX]

I know someone who (was) married to a guy who's only 26 and he makes six figures selling some sort of medical machine. Apparently he plays video games all the time and is lazy and just works sparingly and travels a few times a month. You have to wonder about how much mark up is on these medical machines if a guy who works only only a few days a week or month with little schooling can earn 6 figures in commissions

Any Nefarious Uses for This_

[Froggels]

What kinds of nefarious outcomes can this technology lead to? Insurance companies and DHS using it in ways that help no one but themselves (and the children) immediately come to mind.

Doesn't reducing speed mean slowing down?

[DigitalReverend]

FTFA: "However, the most important factor in reducing the sequencing speed so dramatically is the introduction of the next generation of Ion Torrent semiconductor chip technology."

Shouldn't it be increasing sequencing speed, or reducing sequencing time?

This FP f0r GNAA

a fact: FreeBSD long time FrreBSD came as a complete save Linux from a words, don't get for the record, I you join today!

cool

[JustNiz]

Now my doctor can make some interesting mutant fish for the aquarium in his waiting room..

You have a cold? hum, let's look at your DNA

[youn]

we are about to be served with a "let's look at your DNA" at every visit for completely unrelated diseases in every possible scenario possible. This is going to get annoying very fast

And does it really cost $1000 to do a sequencing?

[NotSoHeavyD3]

Just curious since I remember reading, admittedly on a blog, somebody take that "It takes X dollars to do 1 MRI" statement on. Basically the idea was that MRI's have a huge fixed cost. (IE you have to pay for the machine and tech before you do even the first MRI) However the additional cost from each MRI was basically nothing.(Since the machine has to be already there, it's going to use the same amount of power no matter what and the tech has to be there.) So from an economic point of view it didn't make sense to put a huge cost on each individual MRI since that would encourage docs to not use the machine. (When they really should try to schedule as many as possible since each one was additonal money and didn't really cost anything.) Is the deal the same with this sequencer? (IE once you have the machine and the guy to run it a single sequence basically costs nothing.)

What for?

Why on Earth would anyone want such a thing? By "anyone" I mean, other than insurance companies, employers, and crooks.

Re:What for?

[cbiltcliffe]

Well, gee. I guess my wife must be one of the above, then, huh?

How about:
- researchers looking for causes/cures for diabetes.
- researchers looking for causes/cures for cancer.
- researchers looking for causes/cures for stupidity.

Besides, you double-posted. "Insurance companies" and "crooks" are synonymous. :P

Re:And does it really cost $1000 to do a sequencin

[RDW]

'Is the deal the same with this sequencer? (IE once you have the machine and the guy to run it a single sequence basically costs nothing.)

No, the $1000 (or whatever the figure turns out to be) is just for consumables. You need to spend this on every run.

Re:And does it really cost $1000 to do a sequencin

[alphatel]

Just curious since I remember reading, admittedly on a blog, somebody take that "It takes X dollars to do 1 MRI" statement

The DNA sequencing table shows a precipitous drop in costs down below $10,000 and under .10 per genome or check the latest genome chart. However this cost only calculates raw full human sequence not just a particular strand or some desktop device that does limited work.

Re:And does it really cost $1000 to do a sequencin

[NotSoHeavyD3]

Thanks for the info, ignorance fought

Free for every clinic

[sgt+scrub]

A DNA scan of all bacteria/virus from patients with infections would be boon to public health. I can think of two good reasons it should be free to do DNA scans on every patient with an infection. Tabulating the data to watch for the spread of a desease. Studying the changes in bacteria/virus DNA as they develop resistances to treatments. I can also think of three good ways to pay for it. The government wanting to control desease outbreaks. Researchers wanting data for research. Pharmaceutical companies wanting data to make drugs to sell.

Nice, but what's the point?

[msobkow]

It's nice that the price of using DNA sequencing technology is coming down, but I have a question:

So what?

Doctors aren't trained to use DNA sequencing equipment. And even if they were, how many disorders can be diagnosed by gene sequencing? Other than confirmation of genetically carried disorders, gene sequencing would never even be able to help diagnose anything.

Re:And does it really cost $1000 to do a sequencin

[climb_no_fear]

Actually we have an "old" Illumina (same manufacturer) and get bulk discounts on the consumables so a dedicated lab running the machine day and night might still be a better ROI.

Sequencing of tumors

[climb_no_fear]

Actually, probably the best use of these machines will be to sequence tumor DNA to determine the best treatment option.

For example, is your melanoma response to RAF inhibitors?

Such work is going on at the NIH NGS paper (PDF) and, in this case, the more data to correlate responses with, the better.

Of course, not really something for your average doctor.

Re: Your sig

[Samantha+Wright]

Au contraire; that tactic doesn't exactly yield a coherent supply of intelligent conversation.