Thermo Fisher Scientific Introduces Peptide Calibration Reagent to Optimize Liquid Chromatography Performance

"Thermo Fisher Scientific, the world leader in serving science, today announced the availability of the Thermo Scientific Pierce Peptide Retention Time Calibration Mixture for the prediction of peptide retention times on reversed-phase high-performance liquid chromatography (HPLC) columns. 
The convenient, ready-to-use Pierce® Peptide Retention Time Calibration Mixture contains 15 synthetic, heavy peptides mixed at an equimolar ratio to elute across the chromatographic gradient. It can be used with Thermo Scientific Pinpoint Software to predict peptide retention time from sequence alone, using hydrophobicity factors, or to predict peptide retention time between instrument platforms. 

The Pierce Peptide Retention Time Calibration Mixture streamlines the transition from qualitative protein discovery results to the development of targeted mass spectrometry (MS) assays on Thermo Scientific Triple Quadrupole, Orbitrap and Exactive Instruments and all other mass spectrometers. It also saves time in peptide purification by increasing the prediction efficiency of peptide retention profiles. The mixture is useful in evaluating different reversed-phase column and gradient options, monitoring for autosampler and HPLC column performance characteristics and normalizing results between experiments and over time."

In Vivo Imaging From Whole Organ to Single Cell

UVP, LLC announces the release of the new iBox® Explorer™ Fluorescence Microscope at ASM. The Explorer system combines the technology from its macro imager, the iBox Scientia™ Imaging System, with new micro imaging technology that incorporates imaging tissues, tissue margins and individual cells. The Explorer provides breakthrough advances in its dual lighting system and software controlled objectives. The Explorer system supplies the benefit of using one complete system for macro and micro in vivo animal fluorescent imaging. 
"The iBox Explorer is significant for speed and versatility," according to Sean Gallagher (VP and CTO UVP). "Enabling the rapid and multiplexed fluorescence detection of tumor margins and micro metastasis, the Explorer cleanly separates normal from cancer tissues via the cell's fluorescent signature. Operating in the visible and NIR wavelengths, the Explorer yields detailed images of tissues and cells or, using the joy stick, 'flies' across an area such as the open abdominal region or skin flap of a mouse for rapid screening." In addition to imaging both the whole organ and cells of small animals, the Explorer delivers optical configurations that are parcentered and parfocal, allowing seamless imaging through the magnification ranges. 

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NSF Gives Three Life-Science Projects $1.2M Grant to Test Microsoft’s Azure Cloud

Three life-science projects are among 13 teams that will have free access to Microsoft’s Azure cloud-computing platform for two years as part of an agreement between Microsoft and the National Science Foundation.

The life-science projects, led by researchers at Virginia Polytechnic Institute; the University of North Carolina, Charlotte; and the J. Craig Venter Institute, were awarded a total of $1.2 million in grants under the program, which kicked off in 2010 (BI02/10/2010). The awardees were announced last week.

In addition to providing access to the cloud, Microsoft will provide a support team, tools, applications, and data collections to help the scientists integrate cloud technology into their research.

An NSF review board considered the “appropriateness” of each proposal to the Azure platform’s capabilities, Reed Beaman, a program director at the agency, told BioInform.

For example, he said, the reviewers considered the fact that the platform is very strong in so-called “embarrassingly parallel” computations and in its ability to deploy web services.

He observed that in addition to providing Microsoft an opportunity to test the limits of its cloud computing platform, the partnership saves research dollars that would otherwise have been spent on hardware.

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Get SMRT: Pacific Biosciences Unveils Software Suite with Commercial Launch

April 29, 2011 | Third-generation sequencing company Pacific Biosciences (PacBio) began commercial shipment of its PacBio RS single-molecule sequencer this week. The instrument has been in beta testing at 11 institutions in North America and elsewhere for the past year. A notable success was the recent sequencing and identification of the cholera strain sweeping Haiti after the devastating 2010 earthquake.  

In a briefing with Bio-IT World, PacBio staffers Kevin Corcoran, Jon Sorenson and Edwin Hauw previewed the new suite of software tools on the RS sequencer. The SMRT (single molecule/real time) Analysis software suite features web-based software, an analysis pipeline framework, and algorithms for sequence alignment and de novo assembly.  

“We’re accelerating the development of software with the community,” says Kevin Corcoran. “A key feature of third-generation sequencing is that [the technology] doesn’t match up with what’s out there now. The key features of the PacBio system include fast time to result, high granularity, long read lengths, and new sequencing modes, including a circular mode and strobe sequencing.”  

PacBio’s single-molecule sequencing system offers significantly longer read lengths (1,000 bases on average) than its second-generation sequencing rivals, and faster run times. That said, the total sequence throughput per run is currently less than other commercial platforms. The single-read accuracy hovers in the 85-90% range.   

A revelatory feature of the SMRT software portal is that it captures kinetic information – the time for each registered nucleotide to be captured and incorporated into the growing DNA strand. “This is the first time you can watch DNA polymerase in real time, so that kinetic information will provide additional applications that have never been enabled before,” says Corcoran.   

The genome browser is called SMRT View. “This takes advantage of our longer reads and kinetic information,” says Sorenson. It includes strobe and consensus sequence modes, allowing the user tovisualize and interact with secondary analysis sequence data. PacBio says the interactive graphical representations of variants, quality values, and other metrics is the first data visualization application that can visualize kinetics and structure information unique to PacBio's SMRT technology.

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Published Study Validates New Protein Enrichment Approach For Low-Abundance Biomarker Detection

Hercules, CA — April 20, 2011 — University of Minnesota researchers found that Bio-Rad Laboratories' ProteoMiner protein enrichment kit enhanced identification of changes to low-abundance proteins and detection of post-translationally modified (PTM) proteins in human saliva. These findings offer promise for improving differential proteomic analyses and biomarker studies aimed at identifying disease-specific proteins and their PTM variants in various types of biological samples and fluids. The study was published in the Dec. 13, 2010, issue of the Journal of Proteome Research.

ven when highly sensitive mass spectrometers are used to analyze complex biological samples and bodily fluids, high-abundance proteins obscure the detection of lower-abundance proteins and their post-translational modifications," said Sri Bandhakavi, who led the study at the University of Minnesota in 2010. (Bandhakavi is now a senior scientist at Bio-Rad.) "These lower-abundance proteins and PTMs are often of most interest to researchers, given their association with specific disease or physiological states."

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UC Berkeley Starts Synthetic Biology Institute

"Agilent will serve as a founding industry partner for the new Synthetic Biology Institute, which will involve Lawrence Berkeley National Laboratory and will focus on synthetic bio and bioengineering."
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U of Minnesota Spends $3.6M NIH Grant on Supercomputer for Biological and Medical Research

The University of Minnesota Supercomputing Institute for Advanced Computational Research has installed a new high-performance computing system from SGI, christened Koronis, that it will use for multi-scale modeling, chemical dynamics, bioinformatics, computational biology, and biomedical imaging.

The university purchased the 1,152-core system with a $3.6 million grant from the National Institutes of Health's National Center for Research Resources. It will support NIH-funded research projects at the university.

Jeff McDonald, assistant director of high-performance computing operations at MSI, told BioInform that the latest purchase is the largest system at MSI and that it was selected because its shared memory capabilities best fit the researchers' needs.

In the grant abstract, the researchers wrote that the new system will help 33 research groups supported by 91 NIH grants "tackle ... the acquisition, analysis and visualization of petascale data from high-performance computing and high-throughput technologies."

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Global Market for Bioinformatics to touch $2.4 billion in 2011

"According to the new market research report from Industry Experts ‘Bioinformatics – A Global Market Overview’, global market for bioinformatics is estimated at about $2.4 billion in 2011 and further projected to reach $7.6 billion by 2017 registering a CAGR of 18.3% during the period 2007-2017.

At the beginning of the “genomic revolution”, Bioinformatics was applied in creating and maintaining a database that stored biological information, such as nucleotide and amino acid sequences. Development of this type of database involved not only design issues but also the development of complex interfaces, whereby researchers could access existing data, in addition to submitting new or revised data.

Market for Bioinformatics product categories analyzed in this study includes Bioinformatics Content, Bioinformatics Analysis Software & Services and Bioinformatics IT Infrastructure & Other Services. The report also includes the market analysis for end-use application analysis of Bioinformatics – Biopharma & Diagnostics, Genomics, Agriculture, Chemicals and Environmental & Other."

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Canadian Human Proteome Project Workshop

Canadian Human Proteome Project Workshop Part 2, MaRS District Discovery, TorontoFebruary 22, 2011
MaRS District Discovery
Toronto, Ontario

The Canadian National Proteomics Network is promoting a Canadian Human Proteomics Project (CHPP), which will leverage Canada’s existing strengths in proteomics, health research and technology. A position paper is currently being developed based on the outcomes of the first CHPP Workshop held on January 16-17, 2011 in conjunction with the Annual Proteomics Conference in Cell Biology in Barbados. The CHPP Working Group will present the first draft of this position paper and invite feedback and further development of the project from the research community, clinicians and industry partners. As members of the CNPN and CNPN Board of Directors, the goal of the organizers of the Workshop is to present a final version of the position paper to Canadian and provincial funding agencies in the Spring of 2011 with the intent of stimulating interest for a nationwide funding competition to support a CHPP.

We invite you to participate in the development of a CHPP during our full-day Workshop on February 22. The Workshop will consist of presentations from leaders around the world participating in the Human Proteome Project, discussion of the goals and potential projects for CHPP, and key strategies for engaging national funding agencies and industry partners. 

Highly Sensitive & Specific Chromatin Immunoprecipitation (ChIP) Assay Kit from Porvair Filtration Group

orvair Filtration Group has developed a new technology that has particular relevance to the rapidly expanding Epigenetics market and will be unveiling it at the Epigenetics World Congress in Boston in April 2011. Using a new approach, based on a rigid porous polymer matrix rather than the traditional sepharose or magnetic beads, Porvair has developed a novel Chromatin ImmunoPrecipitation (ChIP) assay kit called Chromatrap™.

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DNAnexus Launches First Complete Cloud-Based Solution for Genomic Variation Identification

DNAnexus, Inc. announces the availability of a comprehensive set of new informatics tools that enable life science researchers to efficiently analyze and manage large-scale genomic variation datasets in a cloud-based workflow. DNAnexus will discuss results from a study using this solution at the 12th annual Advances in Genome Biology and Technology (AGBT) meeting in Marco Island, Florida. 
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Meetings/workshops on bioinformatics and computational biology in China

1.	[ID=365924]ICBBE — 5th Intl Conference on Bioinformatics and Biomedical Engineering
	10 May 2011 → 11 May 2011; Wuhan, China
	weblink: http://www.icbbe.org/2011

2.	[ID=385350]5th International Conference On Bioinformatics And Biomedical Engineering
	10 May 2011 → 12 May 2011; Wuhan, China
	weblink: http://www.icbbe.org/2011

3.	[ID=372265]iCCBE 2011 — The 5th International Conference on Bioinformatics and Biomedical Engineering
	13 May 2011 → 15 May 2011; Wuhan, China
	weblink: http://www.icbbe.org/2011/Home.aspx
4.	[ID=398091]CBB2011 — 2011 International Conference on Computational Biology and Bioinformatics
	28 Oct 2011 → 30 Oct 2011; Shanghai, China
	abstract: The 2011 International Conference on Computational Biology and Bioinformatics (CBB2011) will take place in Shanghai China, 28-30 October, 2011. The conference CBB2011 is held under the World Congress on Engineering and Technology 2011(CET2011). The CET 2011 is composed of several conferences on the frontier topics in the engineering and technological subjects.
	weblink: http://www.engii.org/cet2011/CBB2011.aspx

University Uses Thermo Fisher Scientific ICP-MS for Reliable and Efficient Sulfur Detection in Proteins

"Thermo Fisher Scientific Inc. announced that the University of Oviedo’s analytical spectrometry research group has implemented the Thermo Scientific XSERIES 2 ICP-MS to perform reliable and interference-free sulfur detection in proteins.

The analytical spectrometry research group at the University of Oviedo in Asturias, Spain aims to solve the analytical challenges encountered by science and technology. Within this framework, a small sub-group has been established focusing on the development of inductively coupled plasma-mass spectrometry (ICP-MS) based analytical methods for the quantification of biopolymers such as DNA and proteins. One of the principal issues faced by the group is the interference from gas-based polyatomics such as oxygen in the determination of sulfur when using a low resolution instrument. To eliminate these problems, the group selected the Thermo Scientific XSERIES 2 ICP-MS with collision/reaction cell technology (CRC).

Quantitative protein analysis is currently one of the most demanding applications in analytical chemistry. Mass spectrometric techniques such as electrospray ionization-mass spectrometry (ESI-MS) and matrix assisted laser desorption ionization-mass spectrometry (MALDI-MS) have traditionally played a key role in protein analysis. However, the potential of ICP-MS has recently been recognized for the determination of proteins. Although ICP-MS detection does not provide any structural information, its outstanding capability to quantify most of the elements proves valuable for accurate protein quantification. Keeping pace with the latest technological developments, the University of Oviedo’s research group has coupled the XSERIES 2 ICP-MS with a reversed-phase capillary liquid chromatography (μLC) system to facilitate precise determination of sulfur isotopes in standard proteins.

Dr. Jörg Bettmer of the University of Oviedo’s analytical spectrometry research group comments, “The Thermo Scientific XSERIES 2 ICP-MS was chosen because no other quadrupole-based system matches its capabilities in terms of accuracy, reliability and overall efficiency. The implementation of the instrument has allowed us to achieve reliable, interference-free detection of sulfur isotopes. It has enabled us to determine sulfur-containing standard proteins in an accurate and efficient manner that had not been previously possible.”

The XSERIES 2 offers outstanding productivity in a quadrupole ICP-MS for both routine and high-performance analytical applications. By using the system, laboratories can achieve their analytical objectives faster, with greater confidence and less hands-on time from the operator. The innovative ion lens design of the instrument enables simple field upgrade to collision cell technology (CCT) performance without affecting the normal (non-CCT mode) sensitivity or background. The cell is also compatible with a range of reactive gases, such as pure oxygen for interference suppression in challenging matrices."

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Global Biotechnology Instrumentation Market to Reach US$5.8 Billion by 2015, According to a New Report by Global Industry Analysts, Inc.

Biotechnology Instrumentation sector continues to display healthy growth supported by biotech research expansion in pharmaceutical operations, forensics, agriculture environmental monitoring, and animal husbandry sectors. Demand for faster and economical ways to produce drugs for the pharmaceutical industry, proteomics, genomics, functional genomics and combinatorial chemistry have led to the advancements of bioinstrumentation in recent years. The use of bioinstrumentation techniques has become simple and more accessible. The routine biological tests in forensic laboratories and food technology facilities are performed by instruments such as off-the-shelf kits of PCR primers, automated analytical equipment, and automated synthesizers.

Universities, particularly medical schools, are the largest end-users of biotech instruments. Product enhancements, such as automation and better reproducibility, have led to an increased demand from pharmaceutical companies. Emerging sectors in drug discovery arena such as genomics, proteomics, DNA chips, combinatorial chemistry, and high throughput screening, are fueling the demand for bioinstrumentation by the life science industry. Rapid advancements in biotechnology and pharmaceutical research require complicated analysis and purification methods. An unprecedented interest in these fields led to a significant increase in the use of analytical techniques such as HPLC, Gas Chromatography, and Mass Spectrometry.

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A single blood drop could detect heart disease, cancer

A University of Victoria researcher hopes to change the nature of testing forheart disease, cancer and drug toxicity using a highly sensitive and fast machine that would only require a single drop of blood from a patient.

Called a mass spectrometer, this machine determines the weight of protein molecules in the blood, and would allow researchers to determine if key marker proteins related to heart disease or cancer are present. The mass spectrometer being used in this research is among the most sensitive spectrometers that are commercially available, and is currently the only one of its kind in Canada.

Dr. Christoph Borchers at the University of Victoria-Genome BC Proteomics Centre will use the Agilent ion funnel 6490 mass spectrometer to develop methodologies for early diagnostic tests. These tests will detect and measure biomarkers, which are proteins in a patient’s blood that can signal early and subtle health changes. Dr. Borchers hopes to apply the technology to develop inexpensive, fast, and reproducible biomarker tests for early diagnosis of cardiovascular disease (CVD), the leading cause of death in the Western hemisphere.

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Hope Offered For New Diagnostics Following Research Into Synthetic Antibodies

Antibodies are watchdogs of human health, continuously prowling the body and registering minute changes associated with infection or disease with astonishing acuity. They also serve as biochemical memory banks, faithfully recording information about pathogens they encounter and efficiently storing this data for later use. 

Stephen Albert Johnston, Neal Woodbury and their colleagues at the Biodesign Institute at Arizona State University have been exploring mechanisms of antibody activity, particularly the ability of these sentries to bind - with high affinity and specificity - to their protein targets. A more thorough understanding of the antibody universe may lead to a new generation of rapid, low-cost diagnostic tools and speed the delivery of new vaccines and therapeutics. 

Borrowing a script from nature, the group has been working to construct synthetic antibodies or synbodies, through a simple method developed in Johnston's Center for Innovations in Medicine. They have also examined the broad portrait of antibody activity revealed in a sample of blood, harnessing this information for the presymptomatic diagnosis of disease. These immunosignatures, as Johnston has named them, provide a dynamic report card on human health. 

In a pair of new papers, the group demonstrated a simple means of improving the binding affinity of synbodies, which are composed of 20 unit chains of amino acids, strung together in random order. They also used random peptide sequences spotted onto glass microarray slides to mine information concerning the active regions or epitopes of naturally occurring antibodies. These two projects recently appeared in the journals PloS ONE and Molecular and Cellular Proteomics, respectively. 

While antibodies have been in use for biomedical research for a long time, conventional techniques for producing them have been time consuming and expensive. Normally, antibodies used for research are produced in animals, which respond to a given injected protein by producing a protein-specific antibody, which may then be extracted. 

In earlier work, Johnston's group showed that high-affinity antibody mimics can be produced synthetically by simple means. Their technique turns the traditional production approach on its head. Rather than beginning with a given protein and trying to generate a corresponding antibody, the new method involves building a synthetic antibody first, later determining the protein it effectively binds with, by screening it against a library of potential protein mates. 

The first step in this process is to generate random strings of 20 amino acids. Roughly 10,000 such random peptides are then spotted onto a glass microarray slide. The protein one is seeking an antibody to is screened against this random sequence array and peptides with high binding affinity are identified. Two such peptides can be linked together to form a synbody, whose binding affinity is the product of each separate peptide. In this way, two weakly binding peptides join forces to form a high affinity unit, useful for investigations into the proteome, the vast domain of proteins essential to virtually all biological processes. 
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Global Bioinformatics Market to Reach US$5.0 Billion by 2015

Bioinformatics, one of the most vibrant industries in the current scenario, is at the forefront of the biotech revolution. The market is projected to transform into a major industry within the next few years. Driving the revolution is genomics, a set of advanced tools designed for large data acquisition and analysis. New tools are not only pushing the development of drug discovery, but also fundamentally changing the nature of biological research. The success of Human Genome Project and breakthrough technologies in drug discovery initiatives spells significant investment opportunities for the industry. As new players enter the market, and existing companies grow in size and revenue, competition in the bioinformatics industry is likely to intensify significantly.
Globally, pharmaceutical companies are increasingly seeking help from biotechnology to alleviate concerns related to increasing number of blockbuster drugs going off-patent, narrow product pipelines, and high drug development costs. Bioinformatics can be applied in every stage of the R&D processes in biotechnology as well as the pharmaceutical sectors. The emergence of genomics and its ever-growing application in the research and development processes have created soaring amount of data, creating significant opportunities for bioinformatics. Data management tools based on bioinformatics have helped companies in easing the task of R&D analysis, thereby enhancing their productivity by way of identifying new biomarkers for toxicity and drug efficacy, diagnostic biomarkers as well as new drug targets. Bioinformatics help utilization of the gene and protein data and construct interactive models that aid in identifying disease pathways and effects of compounds.
Going forwards, the penetration of genomics in drug discovery is expected to increase further, which bodes tremendous market prospects for bioinformatics. In addition, more and more spending is expected to be made in research and development from pharmaceutical companies, of which a major chunk is expected to end up in the area of bioinformatics. Bioinformatics is a multifaceted market, characterized by a host of licensing and research and development collaborations. Worldwide bioinformatics market is primarily concentrated in the United States and Europe. The industry represents one of the fastest growing fields offering economic opportunities in various areas.
The US represents the largest regional market for bioinformatics worldwide, followed by Europe, as stated by the new market research report on Bioinformatics. However, Asia-Pacific is projected to record the fastest growth over the analysis period. Japanese market is projected to post a CAGR of 13.5% during the analysis period. Segment wise, Biocontent represents the largest product segment in the global bioinformatics market. Bioinformatics Software represents the fastest growing product segment. Demand for Bioinformatics hardware is projected to rise by 9.5% during the analysis period.
The global bioinformatics industry is highly fragmented, with several companies offering only specific services and a very few companies delivering comprehensive solutions for their clients' R&D needs. Large-scale presence of smaller companies and high fragmentation is due to lower entry barriers and existence of large IT companies in the sector. Major players profiled in the report include 3rd Millennium, Inc, Accelrys, Inc., Affymetrix, Agilent Technologies, BioWisdom Ltd, Celera Group, Gene Logic, IBM Life Sciences, Life Technologies Corporation, and Rosetta Inpharmatics.
The research report titled "Bioinformatics: A Global Strategic Business Report" announced by Global Industry Analysts Inc., provides a comprehensive review of the bioinformatics market, current market trends, key growth drivers, recent product introductions, recent industry activity, and profiles of major/niche global as well as regional market participants. The report provides annual sales estimates and projections for bioinformatics market for the years 2007 through 2015 for the following geographic markets - US, Canada, Japan, Europe, Asia-Pacific, and Rest of World. Key segments analyzed include Software (Bioinformatics), Biocontent (Bioinformatics), and Hardware (Bioinformatics). Also, a seven-year (2000-2006) historic analysis is provided for additional perspective.
For more details about this comprehensive market research report, please visit -
www.strategyr.com/Bioinformatics_Market_Report.asp


Read more: http://www.sfgate.com/cgi-bin/article.cgi?f=/g/a/2011/01/10/prweb8052230.DTL#ixzz1BJeau2Po

Scientists find the 'master switch' for key immune cells in inflammatory diseases

Scientists have identified a protein that acts as a "master switch" in certain white blood cells, determining whether they promote or inhibit inflammation. The study, published in the journal Nature Immunology, could help researchers look for new treatments for diseases such as rheumatoid arthritis that involve excessive inflammation.

Inflammatory responses are an important defence that the body uses against harmful stimuli such as infections or tissue damage, but in many conditions, excessive inflammation can itself harm the body. In rheumatoid arthritis, the joints become swollen and painful, but the reasons why this happens are not well understood.

Cells of the immune system called macrophages can either stimulate inflammation or suppress it by releasing chemical signals that alter the behaviour of other cells. The new study, by scientists from Imperial College London, has shown that a protein called IRF5 acts as a molecular switch that controls whether macrophages promote or inhibit inflammation.

The results suggest that blocking the production of IRF5 in macrophages might be an effective way of treating a wide range of autoimmune diseases, such as rheumatoid arthritis, inflammatory bowel disease, lupus, and multiple sclerosis. In addition, boosting IRF5 levels might help to treat people whose immune systems are compromised.

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Model predicts a drug's likelihood of causing birth defects

Bioinformatic analysis crunches data on drug effects on genes involved in fetal development

Boston, Mass. – When pregnant women need medications, there is often concern about possible effects on the fetus. Although some drugs are clearly recognized to cause birth defects (thalidomide being a notorious example), and others are generally recognized as safe, surprisingly little is known about most drugs' level of risk. Researchers in the Children's Hospital Boston Informatics Program (CHIP) have created a preclinical model for predicting a drug's teratogenicity (tendency to cause fetal malformations) based on characterizing the genes that it targets.

The model, described in the March 2011 issue of Reproductive Toxicology (published online in November), used bioinformatics and public databases to profile 619 drugs already assigned to a pregnancy risk class, and whose target genes or proteins are known. For each of the genes targeted, 7426 in all, CHIP investigators Asher Schachter, MD, MMSc, MS, and Isaac Kohane, MD, PhD, crunched databases to identify genes involved in biological processes related to fetal development, looking for telltale search terms like "genesis," "develop," "differentiate" or "growth."

The researchers found that drugs targeting a large proportion of genes associated with fetal development tended to be in the higher risk classes. Based on the developmental gene profile, they created a model that showed 79 percent accuracy in predicting whether a drug would be in Class A (safest) or Class X (known teratogen).

For example, the cholesterol-lowering drugs cerivastatin, lovastatin, pravastatin and fluvastatin are all in Class X. All of these drugs also targeted very high proportions of high-risk genes (98 to 100 percent). The anti-coagulant warfarin, also in Class X, had a proportion of 88 percent.

When Schachter and Kohane applied the model to drugs across all risk classes, the proportion of developmental genes targeted roughly matched the degree of known risk (see graph). However, the model needs further validation before Schachter is willing to share actual predictions for specific drugs. "We don't want to risk misleading pregnant women from taking necessary medicines," he says.

One difficulty in validating the model is that the "known" teratogenicity it's being tested against often isn't known. Between Class A and Class X are Classes B, C and D, with increasing amounts of risk, but the boundaries between them are based on minimal data. Teratogenic effects may be difficult to spot, since most drugs are taken relatively rarely in pregnancy, some may be taken along with other drugs, and any effects tend to be rare or too subtle to be noted in medical records. Moreover, data from animal testing doesn't necessarily apply to humans.

"A lot of drugs in the middle of the spectrum, and maybe even some in Class A, may cause subtle defects that we haven't detected," says Schachter. "We can't provide a yes/no answer, but we found a pattern that can predict which are riskier."

Given the degree of uncertainty, Schachter and Kohane believe their model may be of interest to drug developers and prescribing physicians, and might provide useful information to incorporate in drug labeling.

"We can now say to patients, 'This drug targets a ton of genes that are involved in developmental processes,'" says Schachter.

Or, conversely, if a young pregnant woman has a heart condition and needs to be treated, physicians may be reassured by a cardiac drug's profile, he adds. "Instead of saying, 'we don't know,' we can now say that the drug is more likely to be safe in pregnancy."

"We have here a prismatic example of the utility of a big-picture, macrobiological approach," says Kohane, director of CHIP. "By combining a comprehensive database of protein targets of drugs and a database of birth defects associated with drugs, we find a promising predictive model of drug risk for birth defects."

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The study was funded by a grant from the National Institute of General Medical Sciences.

Children's Hospital Boston is home to the world's largest research enterprise based at a pediatric medical center, where its discoveries have benefited both children and adults since 1869. More than 1,100 scientists, including nine members of the National Academy of Sciences, 12 members of the Institute of Medicine and 13 members of the Howard Hughes Medical Institute comprise Children's research community. Founded as a 20-bed hospital for children, Children's Hospital Boston today is a 392-bed comprehensive center for pediatric and adolescent health care grounded in the values of excellence in patient care and sensitivity to the complex needs and diversity of children and families. Children's also is the primary pediatric teaching affiliate of Harvard Medical School. For more information about research and clinical innovation at Boston Children's visit: Vector Blog.