Jason Palmer, Author at 快猫短视频 Science news and science articles from 快猫短视频 Tue, 15 Mar 2016 11:48:24 +0000 en-US hourly 1 https://wordpress.org/?v=7.0.1 242057827 Graduate Special: Fancy a flying start? /article/1897766-graduate-special-fancy-a-flying-start/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 22 Oct 2008 17:00:00 +0000 http://mg20026790.300 Ireland

LESS than an hour by plane and 快猫短视频 finds itself surrounded by the Wicklow mountains and the Georgian architecture of Dublin. Trinity College 鈥 Ireland鈥檚 most prestigious university 鈥 has seen a host of top names in science passing through its corridors. And what greater sign that Irish research is booming than the fact that Irish-born researchers are flooding back from far-flung foreign shores?

Ireland鈥檚 aspiration to be a player on the world stage means that technology-based wealth washes both in and out of the country. High-tech manufacturing makes up more than 75 per cent of Ireland鈥檚 exports, but more than 75 per cent of economic turnover is by companies that are foreign-held 鈥 names like Intel, Cisco and Hewlett-Packard. Fundamental research is burgeoning, too. Technologies of the nano, bio and information varieties lead the pack, and all are receiving serious cash. Science Foundation Ireland (SFI) holds the purse strings and is implementing the Irish government鈥檚 eight-year Strategy for Science, Technology and Innovation, which has already funded more than 鈧1 billion in R&D.

Dublin has remained a hub for great research, boasting five of the SFI鈥檚 Centres for Science, Engineering & Technology. The others are in Limerick, Galway and Cork. Researchers who relocate to Ireland invariably cite the warm nature of its people, from lecturers and locals to cabbies. And that openness goes right to the top: many attribute Ireland鈥檚 successes in part to a government that is sympathetic to the needs of research. Most Irish universities also provide business courses for their graduates, so unleashing your inner entrepreneur on the Emerald Isle might just make you a tidy sum.

Scandinavia

THE Nordic countries have long enjoyed a rich funding climate, with Sweden regularly topping lists of investment in R&D. So how can you get your hands on some of that money? Much of it is piped into biotech, the region鈥檚 flagship science industry. Medicon Valley, a cluster of biotech companies that stretches from the Danish capital of Copenhagen across the south-western toe of Sweden, boasts 345 ventures at last count and hundreds of job opportunities.

A look at the publication record of the Nordic countries shows vast expertise in medicine, and the cluster of cancer research institutes near Oslo in Norway represents the first of many such groups planned for the future. Research, in fact, makes up an unusually high fraction of employment here. Finland, Iceland and Sweden top an international list of researchers as a proportion of the population.

Cross-border collaboration is ever increasing, with the Nordic Council of Ministers working to combine the strengths of each Nordic country into an impressive whole. 鈥淚t鈥檚 not just five small countries, it鈥檚 an area of 25 million people with similar cultures and social, political and welfare systems,鈥 says Gard Titlestad, the council鈥檚 head of education, research and labour affairs. The council is working to establish cross-border postgraduate opportunities, and it鈥檚 worth noting that in some Nordic countries, postgrads positions are paid staff jobs.

Mention Scandinavia and in the next breath usually comes a comment about the high quality of life. That comes in part from a sensible work ethic and relatively high wages. Highly qualified newcomers get a few years鈥 amnesty from the high taxes, meaning lots more cash for the enjoyment of the region鈥檚 cold weather 鈥 or as a consolation for it.

Germany

EUROPE鈥橲 most populous nation is arguably its most inventive; its patent applications account for nearly half of the European total. This kind of applied knowledge has created a backbone for Germany鈥檚 dominance in industry, with names like Diesel, Geiger and Zeppelin peppering the country鈥檚 history of innovation. Ideas still flow strongly from Germany鈥檚 renowned research infrastructure and world-class universities.

Recent years have seen vast changes in Germany鈥檚 research landscape. Most of that change has been chalked up to the influence of its physicist-cum-chancellor, Angela Merkel, who besides stimulating more fundamental research has been successful in reforming the higher education system to bring it into line with world standards. Alongside this, Germany鈥檚 central funding body is in the second year of its Excellence Initiative 鈥 using 鈧1.9 billion to establish several graduate schools and research centres.

Benedetta Ciardi, an Italian-born physicist, is sold. 鈥淚 started with a one-year position in 2001 and I鈥檓 still here,鈥 she says. 鈥淚t seems to me that Germany is investing lots of resources in research and promoting young scientists, which is not the case across all of Europe.鈥

Renewable energy is one of the rising stars in Germany鈥檚 portfolio, outstripping even its huge pharmaceutical industry. One German firm accounts for a third of hydropower installations worldwide, and nearly half of the world鈥檚 windmills and a third of all solar cells are of German origin.

Few countries offer so many funding opportunities specifically for foreign researchers: the German Academic Exchange Service and the Alexander von Humboldt Foundation are the best places to start.

Switzerland

THESE days you could be forgiven for thinking that Switzerland鈥檚 only scientific venture is the Large Hadron Collider (LHC), a particle-smashing behemoth whose first experiments will doubtless eclipse any other Swiss scientific output this year.

But it鈥檚 not all chalkboards and accelerators. Switzerland has a rich history to match its high-profile present in the hard sciences. Overall, Switzerland鈥檚 researchers publish more patents per capita than any other European country, home-grown multinationals like Nestl茅 and imported giants such as Google and IBM continue to snap up international graduates, and as home to a host of pharmaceutical giants including Roche, Novartis and Serono, Switzerland easily wins the title of Europe鈥檚 biotech cash cow.

This year the Swiss National Science Foundation introduced a new fellowship, called Ambizione, which is open to foreign researchers. Marcel Kullin, one of the foundation鈥檚 funding heads, says it comes with a 鈥渘ot particularly high salary鈥 of 拢45,000, but hey, at least they provide cash for research. Those who don鈥檛 get money from that pot can apply for funding from the European Union, despite Switzerland鈥檚 non-EU status. And don鈥檛 worry, it鈥檚 not an unusual place to be an expat 鈥 nearly a quarter of Switzerland鈥檚 population is foreign-born.

Switzerland is home to two federal institutes that have long been research heavyweights: the EPFL in Lausanne and the ETH in Zurich, which has seen Albert Einstein and 20 other Nobel laureates pass through its corridors. Researchers from the federal institutes join together with Swiss universities to form the 20 National Centres of Competence in Research, government-funded collaborations in topics that range from biology to climate change to nanotechnology.

The Swiss transport system is clean and highly efficient so day trips to Mont Blanc, Lausanne and the capital, Bern, are all within easy reach. And if you get fed up of talking to scientists all day, Geneva also offers a wide choice of open events, says Kate McAlpine, who works at CERN, the European particle physics lab near Geneva that is home to the LHC. 鈥淢y favourite is the conversation cafe 鈥 a bunch of people getting together and speaking the featured language of the night, at any level of fluency, with the option of a family-style dinner.鈥

And if none of that makes you want to put your passport down and get stuck in, maybe this will: Lindt is hiring.

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Renewable energy: The tide is turning /article/1896520-renewable-energy-the-tide-is-turning/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 08 Oct 2008 17:00:00 +0000 http://mg20026771.800 1896520 Cracking the hardest mystery of the Rubik’s cube /article/1895734-cracking-the-hardest-mystery-of-the-rubiks-cube/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 06 Aug 2008 17:00:00 +0000 http://mg19926681.800 1895734 Gene mutations reveal schizophrenia’s complexity /article/1911143-gene-mutations-reveal-schizophrenias-complexity/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 30 Jul 2008 17:21:00 +0000 http://dn14434 The three largest genetic schizophrenia studies to date have uncovered several ways in which changes to the genome may increase the risk of developing the condition.

The studies bring to light several common variations that increase the risk slightly, and rarer ones that raise it significantly, researchers say.

While previous studies have suggested several genes with roles in schizophrenia, small sample sizes gave these findings limited statistical significance.

Most recently, differences in copy number variations (CNVs) 鈥 chunks of genetic material that are either repeated or missing from the genome entirely 鈥 were identified between healthy and schizophrenic people . But the study was too small to implicate specific CNVs in causing the disease.

Quantity matters

Now, in the biggest study of its kind, the International Schizophrenia Consortium has collected further evidence about the role of CNVs in the condition.

The researchers examined the genomes of 3391 schizophrenics and found that they had around 15% more CNVs on average than the 3181 healthy controls.

This supports the idea that the sheer increase in CNVs alone could be a risk factor for schizophrenia.

Another study, led by of the University of Aberdeen, UK, and deCODE genetics, Iceland, looked at 66 specific CNVs in 1400 schizophrenics and 33,000 healthy participants.

Missing regions

The team was able to identify several CNVs that are linked to a much higher risk of developing schizophrenia, but occur relatively rarely 鈥 in as few as one in 1000 schizophrenics.

They found three missing chromosome regions that raised the risk of developing schizophrenia by as much as 15 times. Importantly, two of these regions were also highlighted in the ISC study above, making it likely that these regions are a real risk factor.

Using yet a different approach, of Cardiff University, UK, and colleagues looked for variations of single 鈥渓etters鈥 (SNPs) of the genetic code that were significantly more common in people with schizophrenia, occurring in as many as one in 10.

Common variant

In a study of more than 360,000 SNPs, they found three convincing associations in specific genes, one of which increases the risk by about 1%. The gene, called ZNF804A, may play a role in regulating the activity of other genes.

鈥淭he variation in that gene makes for a very small increase in risk, but it鈥檚 also very common,鈥 O鈥橠onovan says. 鈥淭ogether, the new studies show that many of us carry some risk genes for schizophrenia, but the people that have the illness simply carry more of them.鈥

鈥淭his is a provocative and important set of findings,鈥 says , at the National Institute of Mental Health in Bethesda, Maryland. But he adds that the rarity of the genetic variations means that the findings account for less than half a percent of schizophrenia cases.

鈥淲e don鈥檛 know yet if these results will translate to the other 99.5% of people with a schizophrenia diagnosis,鈥 he says. 鈥淲e鈥檒l have to further interrogate these regions and see whether common variants within them predict the more common forms of the disorder.鈥

No simple test

There are likely to be many more genetic variants that are associated with schizophrenia coming to light 鈥 maybe as many as thousands, says St Clair. 鈥淚 wouldn鈥檛 have said that even a year ago, but that鈥檚 the way it鈥檚 looking.鈥

That means that a simple genetic test is still a long way off. But both St Clair and O鈥橠onovan believe that identifying some of the genes in the pathway 鈥 and where they can be found 鈥 is already a big step forward.

, a lead author on the deCODE study, likens the situation to that of Alzheimer鈥檚 disease.

鈥淭he findings of the rare Alzheimer鈥檚 mutations contributed hugely to the understanding of how Alzheimer鈥檚 works,鈥 he says. 鈥淥ne of the hopes is that as more studies like these come out in the near future, we can also understand the physiology of schizophrenia.鈥

Journal references: ();

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Robot chef gets a boost from wireless kitchen /article/1911445-robot-chef-gets-a-boost-from-wireless-kitchen/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Mon, 14 Jul 2008 14:53:00 +0000 http://dn14313 The kitchen robot, called B21, can operate in a real kitchen that has been set up with RFID tags
The kitchen robot, called B21, can operate in a real kitchen that has been set up with RFID tags
(Image: Ingo Kresse)

Go on, put your feet up. A new household robot that keeps track of the contents of your kitchen and can learn simple tasks could soon be making you dinner while you relax.

The new robot, developed at the Technical University of Munich, exploits the use of radio-frequency identification (RFID) tags on dishes and utensils in its 鈥溾 to sidestep some of the object-recognition difficulties that have plagued previous household robots.

鈥淚f you want to interpret and understand everyday activities using vision data, it鈥檚 very complicated, error-prone, and resource intensive,鈥 says , who led the research. 鈥淚f you do it with RFID tags, there is very little sensor information, but it鈥檚 highly correlated with the activities you are performing.鈥

As a result, the robot knows where everything is, and it can learn simple tasks simply by observing the movements of the objects.

See videos of the robot and (.avi format).

Surfing for recipes

鈥淪etting the table is very easily recognised from cups and plates disappearing from the cupboard and appearing on the table, and cleaning up later is characterised by the same objects disappearing from the table and appearing in the dishwasher,鈥 Beetz says.

The team is also working to integrate a number of open-source software packages to enable the robots to get instructions from the internet, in the same way that some search for images .

Robots would search how-to websites like , converting natural language into robot-friendly instructions using language software called .

They could then optimise the algorithms based on their particular environment, such as carrying four plates to the table rather than making four trips with one plate.

And while they are online, they can share what they have learned. Beetz plans a repository of information on which robots can share data about specific tasks, recipes, and handy household tips. 鈥淭he hard step will be to have the first robot doing it. But then they would share everything,鈥 he says.

Intelligent environment

鈥淚t鈥檚 very interesting and promising work,鈥 says Stanford University roboticist .

鈥淚f you have sensors just on the robot, the range of things the robot can perceive is very limited,鈥 he says. 鈥淚f it is able to use sensors embedded in an intelligent environment, it鈥檚 as if the robot has many more eyes and sensors and can immediately act much more intelligently in a new environment.鈥

For the robot鈥檚 core software, Beetz and colleagues chose 鈥 an open-source software architecture that is becoming a standard for robotics and sensors. Player was pioneered by Brian Gerkey, a co-author of the study.

The team plans to make all of its findings available and to publish all of the software that it develops, hopefully to bring you robot dinners that much sooner.

Journal reference:

Robots 鈥 Learn more about the robotics revolution in our continually updated .

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Miniaturised scanner zooms in on disease /article/1908881-miniaturised-scanner-zooms-in-on-disease/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Tue, 08 Jul 2008 12:15:00 +0000 http://dn14274 A handheld nuclear magnetic resonance (NMR) scanner that can diagnose diseases and identify pathogens has been built by scientists in the US.

The revolutionary scanner is many times smaller than conventional NMR spectroscopy machines, which require huge magnets to create the powerful magnetic fields necessary to make them work.

Nuclear magnetic resonance spectroscopy works by lining up nuclei in a sample using a powerful magnetic field and then zapping them with radio waves that cause them to wobble, or precess.

This precession induces currents in a nearby coil which can be used to determine the chemical structure of the molecules that contain the nuclei. The same process is used in magnetic resonance imaging machines to make non-invasive images of human bodies. The new device does not produce images, however.

Weaker fields

In conventional NMR spectroscopy machines, powerful fields are necessary to line up individual nuclei.

However, at Harvard Medical School in Cambridge, Massachusetts, US, and colleagues have found that magnetic nanoparticles generate a much larger signal than single nuclei, and can thus be detected using the weaker fields from small permanent magnets.

The trick that Weissleder and colleagues have perfected is to coat these nanoparticles with molecules that bind to specific biomolecules, or bacteria and viruses.

This binding process causes the nanoparticles to clump together, producing a measurable change in the signal they produce. In this way, the team says it can identify a large variety of biological targets.

The team has squeezed the electronics that detect and interpret the signals onto a chip (pdf format).

Small and sensitive

What鈥檚 more, the researchers have also designed a microfluidics network that shuttles the samples around and concentrates them in volumes of just five millionths of a litre (5 microlitres) 鈥 some 60 times less than conventional systems.

鈥淭he smaller the system, the better the sensitivity in terms of absolute amount of sample that can be detected,鈥 says Hakho Lee, lead author on the research.

The prototype device has eight tiny coils, each of which can monitor nanoparticles sensitive to different biomolecules. Future devices could employ many more such coils.

The result is a prototype machine that is 800 times more sensitive than standard NMR scanners used in many laboratories, says Weissleder.

The team put the prototype through its paces, showing that it is sensitive enough to detect just 10 bacteria in a given sample. By loading each of the eight microcoils with different nanoparticles, the system could distinguish between simulated blood samples representing healthy individuals, those with cancer, and those with diabetes, by looking for eight different biomarker molecules.

Multiple applications

鈥淭he biggest advantage is that we don鈥檛 need sample preparation or purification steps,鈥 Lee says. The nanoparticles are simply added to whatever samples are present. 鈥淭his method could provide an easy and fast way to diagnose almost any kind of disease, such as bacterial infection or cancers in point-of-care settings 鈥 right next to the patient or in developing countries.鈥

The device could also be used to test for water purity or even applied to gaseous samples, to search for airborne pathogens or pollutants.

Other researchers are impressed with the work. 鈥淚f you came to my lab you would see that our spectrometers occupy whole rooms, and we are always struggling with sensitivity in NMR experiments,鈥 says , an NMR spectroscopist at the University of Edinburgh.

鈥淭hey have been able to improve the sensitivity such that they can detect just a few bacteria. It鈥檚 quite remarkable that they can detect down to that limit,鈥 he says.

Weissleder has filed a patent for the design and started a company called to market the devices.

Journal reference:

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Pac-Man supercontinent ate itself to pieces /article/1908906-pac-man-supercontinent-ate-itself-to-pieces/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Sun, 06 Jul 2008 17:00:00 +0000 http://dn14259
A map of Pangaea, illustrating the Paleo-Tethys sea
A map of Pangaea, illustrating the Paleo-Tethys sea
(Image: Wikimedia Commons/Kieff)
One of the structures of the Ibero-Armorican Arc in Asturias, northern Spain. The rocks are Ordovician in age, around 475 million years ago, and the stresses resulted in the collision strained their originally horizontal shape into the concave
One of the structures of the Ibero-Armorican Arc in Asturias, northern Spain. The rocks are Ordovician in age, around 475 million years ago, and the stresses resulted in the collision strained their originally horizontal shape into the concave 鈥淯鈥 shape that we can see now.
(Image: G Guti茅rrez-Alonso)
The team takes rock samples: G Gutierrez Alonso, orienting the samples and Arlo Weil drilling. The results obtained using this technique have helped understand the supercontinent's evolution
The team takes rock samples: G Gutierrez Alonso, orienting the samples and Arlo Weil drilling. The results obtained using this technique have helped understand the supercontinent鈥檚 evolution
(Image: Isabel Corral)

The reason you are sitting where you are right now may be because Pangaea, the most recent supercontinent to gather together all the world鈥檚 landmasses together, ate itself nearly 300 million years ago.

Convection in the Earth鈥檚 mantle shifts the floating continental plates around, eventually driving them together into supercontinents every few hundred million years. We know supercontinents eventually break up again, but it is not clear how they do this.

of the University of Salamanca in Spain and colleagues think they may be able to explain the most recent break up which split Pangaea into today鈥檚 continents. They have proposed a mechanism called 鈥溾, which would explain several geological mysteries better than prior theories.

In standard subduction, one tectonic plate slips under another. The situation could have been slightly different 300 million years ago because Pangaea was shaped like a pie with one piece missing. This area was occupied by an ocean called Paleo-Tethys.

Who ate all the pies?

The new theory has it that, as Pangaea鈥檚 southern coast moved northward, the ocean began to close up. Eventually, the continent鈥檚 southern continental shelf was subducted beneath the northern coast.

鈥淚t鈥檚 like a cat trying to bite its own tail,鈥 says Fernando Corf煤, a geologist at the , and one of Guti茅rrez-Alonso鈥檚 collaborators.

The theory predicts that the land in Pangaea鈥檚 centre would have compressed, explaining the Iberian-Armorican Arc, a twisted mountain range that is known to have stretched from modern-day Turkey up to the UK and then down to Spain.

Meanwhile, the rest of the pie would have stretched to breaking point, allowing surrounding oceanic plates to move into the gaps. This explains why a number of ancient rifts, including ones that can be visited today in Norway and Madagascar, were once arranged radially like the spokes of a bicycle.

Journal reference: , DOI: 10.1038/ngeo250

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Pet cats may trigger eczema in children /article/1909115-pet-cats-may-trigger-eczema-in-children/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Tue, 24 Jun 2008 16:36:00 +0000 http://dn14196 Nature and nurture both play a role in eczema, but few genes have been linked to specific environmental risks. Now a gene mutation that predisposes youngsters to the skin condition seems to pose a greater risk if they are also exposed to cats.

In 2006, a mutation in the gene for the protein filaggrin 鈥 which helps keep foreign substances out of the skin 鈥 was shown to increase the risk of eczema. About 9% of people of European origin carry this mutation.

To find out whether an environmental trigger might also play a role, a team led by Hans Bisgaard of the Gentofte University Hospital in Copenhagen, Denmark, who was also involved in the 2006 work, tracked 358 Danish and 460 British children from birth.

About 25% of children without the mutation developed eczema, compared with 45% of those with the mutation. However, of the 16 children who both had the mutation and lived with a cat, 14 developed eczema, all between the ages of one and three months.

鈥淚t has been very hard to prove that there really are environmental factors that trigger those genes,鈥 Bisgaard says. 鈥淭his is proof that there is an interaction, even in the first month of life.鈥 However, Bisgaard says that much more data is needed before any prescriptions can be made for parents.

鈥淚t鈥檚 an interesting and convincing finding,鈥 says Natalija Novak, a dermatologist and epidemiologist at the University of Bonn in Germany. But she says we should now look for other environmental factors that correlate with eczema.

Journal reference: (DOI: 10.1371/journal.pmed.0050131)

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Interview: The cellphone anthropologist /article/1894949-interview-the-cellphone-anthropologist/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Wed, 11 Jun 2008 17:00:00 +0000 http://mg19826602.000 1894949 Common bacteria linked to cot death /article/1909476-common-bacteria-linked-to-cot-death/?utm_campaign=RSS|NSNS&utm_content=currents&utm_medium=RSS&utm_source=NSNS Thu, 29 May 2008 23:01:00 +0000 http://dn14014 There is more reason than ever to believe that two common bacteria are part of the cause of sudden infant death syndrome (SIDS), commonly called cot death.

While many factors contributing to the risk for SIDS have been identified, the mechanism of its cause has remained a mystery. A link to bacterial infections was proposed decades ago, but evidence of the bacteria in SIDS victims has remained scarce.

Now, a team of researchers from the has shown that specific bacteria are more prevalent in SIDS babies.

The team went over the results of autopsies of more than 500 infants who died aged between one week and one year. They then compared the rate of infection by the bacteria Staphylococcus aureus and Escherichia coli in infants whose cause of death was known, and those in SIDS babies.

What they found was that 26% of the autopsies in the explained cases showed infection by the bacteria, whereas in the SIDS cases, the rate of infection was nearly twice that.

Not a diagnostic

鈥淲hat鈥檚 good about this is it鈥檚 a large study at one institution where all the cases were investigated in the same way, so it鈥檚 enabled us to really provide harder evidence,鈥 says Marian Malone, one of the study鈥檚 co-authors.

The prevalence of the bacteria is certainly indicative of a connection with cause of death, but their presence even in explained deaths means that a test for them cannot be used as a diagnostic 鈥 or as evidence for or against other explanations for deaths.

George Haycock, scientific adviser to the UK鈥檚 , warns that there isn鈥檛 just one answer to the SIDS mystery.

鈥淭his is certainly not the cause of SIDS, which is almost certainly multifactorial,鈥 he says. 鈥淓ven in the cases where no cause can be identified, there may be multiple factors operating.鈥

Toxin theory

The role of the bacteria in the so-called bacterial toxin theory could tie some of those multiple factors together. The idea is that the bacteria grow in the upper respiratory tract of babies, releasing toxins that are the ultimate cause of death.

鈥淚t鈥檚 a theory that would fit the facts,鈥 Malone says. 鈥淲e know that prone sleeping 鈥 sleeping on the front 鈥 can increase the number of pathogenic organisms in the upper airway. We know that if the mother has been smoking during pregnancy, it can alter the immune response [to toxins].鈥

Even the genetic differences among SIDS babies are related to immune response. The theory, Malone says, could tie a lot of things together.

鈥淚t鈥檚 another piece of evidence fitting in with lots of other evidence that has been gathering, pointing to these bacteria,鈥 says , a pathologist at the Royal Infirmary, Lancaster, UK. 鈥淣one of this is proof positive, but it鈥檚 another important step to understanding what鈥檚 going on.鈥

Journal reference: , vol 371, p 1848

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