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Welcome to The Visible Embryo, a comprehensive educational resource on human development from conception to birth.

The Visible Embryo provides visual references for changes in fetal development throughout pregnancy and can be navigated via fetal development or maternal changes.

The National Institutes of Child Health and Human Development awarded Phase I and Phase II Small Business Innovative Research Grants to develop The Visible Embryo. Initally designed to evaluate the internet as a teaching tool for first year medical students, The Visible Embryo is linked to over 600 educational institutions and is viewed by more than ' million visitors each month.


WHO International Clinical Trials Registry Platform
The World Health Organization (WHO) has created a new Web site to help researchers, doctors and patients obtain reliable information on high-quality clinical trials. Now you can go to one website and search all registers to identify clinical trial research underway around the world!



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Disclaimer: The Visible Embryo web site is provided for your general information only. The information contained on this site should not be treated as a substitute for medical, legal or other professional advice. Neither is The Visible Embryo responsible or liable for the contents of any websites of third parties which are listed on this site.
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Pregnancy Timeline by SemestersFetal liver is producing blood cellsHead may position into pelvisBrain convolutions beginFull TermWhite fat begins to be madeWhite fat begins to be madeHead may position into pelvisImmune system beginningImmune system beginningPeriod of rapid brain growthBrain convolutions beginLungs begin to produce surfactantSensory brain waves begin to activateSensory brain waves begin to activateInner Ear Bones HardenBone marrow starts making blood cellsBone marrow starts making blood cellsBrown fat surrounds lymphatic systemFetal sexual organs visibleFinger and toe prints appearFinger and toe prints appearHeartbeat can be detectedHeartbeat can be detectedBasic Brain Structure in PlaceThe Appearance of SomitesFirst Detectable Brain WavesA Four Chambered HeartBeginning Cerebral HemispheresFemale Reproductive SystemEnd of Embryonic PeriodEnd of Embryonic PeriodFirst Thin Layer of Skin AppearsThird TrimesterSecond TrimesterFirst TrimesterFertilizationDevelopmental Timeline
Click weeks 0 - 40 and follow fetal growth
Google Search artcles published since 2007
 
August 19, 2011--------News Archive

Hydrodynamics Transform Embryonic Cells Into Us
H
ydrodynamics can contribute to our understanding of how a cluster of embryonic cells can transform into an animal.

New Data on Adenine, a Crucial Building Block of Life
The five nucleic acids making up DNA are some of the few that can withstand ultraviolet light. But adenine turns out to have an extensive range of respones.


August 18, 2011--------News Archive

Change the Environment, Not the Child
National study finds equal benefit for children with cerebral palsy.

Pluripotent Stem Cells Developmentally Immature
Researchers have discovered that though similar, induced pluripotent stem cells are similar to embryonic stem cells, but are much more developmentally immature.


August 17, 2011--------News Archive

Molecular Delivery Serves Gene Therapy Cocktail
Scientists have devised a gene therapy cocktail that has the potential to treat some inherited diseases associated with "misfolded" proteins.

Children of Depressed Mothers Have a Different Brain
MRI scans show their children have an enlarged amygdala.

Discovery Likely to Spur Medicine and Human Health
Scientists have gained new insight into the relationship between two proteins that, out of balance, can prevent normal development of stem cells in the heart.


August 16, 2011--------News Archive

Study Finds New Role for Protein in Hearing
A protein involved in sound sensing in the inner ear may also play a role in transmitting sound information to the brain.

Retinoblastoma Made of Hybrid Cells
Scientists settle a century-old debate about retinoblastoma's beginnings and identify new targets for treating the childhood eye tumor.

Can Oral Care for Babies Prevent Future Cavities?
A recent study confirms the presence of bacteria associated with early childhood caries (ECC) in infant saliva.


August 15, 2011--------News Archive

Slowing the Allergic March
Researchers identify a target that could combat allergies of early childhood.

Gene Clue in the Development of Rheumatoid Arthritis
Findings will help lead to personalized therapies for common, complex illnesses characterized by abnormal immune responses.

Sight Re-Constructs Moving Objects: One by One
Our visual system groups areas of the world with similar characteristics, such as color, shape, or motion.

WHO Child Growth Charts

A pandemic of ailments called the "allergic march" -- the gradual acquisition of overlapping allergic diseases that commonly begins in early childhood -- has frustrated both parents and physicians. For the last three decades, an explosion of eczema, food allergies, hay fever, and asthma have afflicted children in the United States, the European Union, and many other countries. What causes the march and how to derail it has remained elusive.

Now, in this week's Nature, David Artis, PhD, associate professor Microbiology, Perelman School of Medicine, University of Pennsylvania, and a team of collaborating international scientists, identified that expression of the protein TSLP may influence susceptibility to multiple allergic diseases.

It appears TSLP is regulating the maturation of basophils, an uncommon type of white blood cell. Specifically, TSLP elicits the maturation of a population of distinct basophils that promotes allergic inflammation.

"A fundamental question regarding the allergic march is if a child has eczema, for example, which is associated with TSLP production in skin cells, why would some of those children subsequently be more susceptible to other allergic diseases at different sites of the body such as the gut or the lung?" asks Artis. "Although we have known that TSLP is associated with allergic diseases for many years, how this biological messenger might influence multiple allergic diseases has been a puzzle."

The origins of the present study lie in previous reports that showed that different versions of the gene encoding TSLP, an inflammation-producing cytokine, are associated with increased susceptibility to multiple allergic disorders, and that exaggerated TSLP production is associated with asthma, eczema, and food allergies in children.

Together, these studies indicate that TSLP could be a critical regulator of multiple cytokine-associated allergic inflammatory diseases. In this new report, mice overexpressing TSLP developed allergic inflammation in their lungs, skin, and gut that was associated with very high levels of basophils.

"The critical findings are that TSLP appears to activate the development and maturation of early-stage basophils in the bone marrow and that TSLP elicits a distinct type of basophil," explains first author Mark Siracusa, PhD, a Ruth L. Kirschstein National Research Service Fellow in the Artis lab. Based on these findings, the researchers speculate that this basophil maturation could promote allergic reactions at multiple tissue sites.

To translate these findings to patient populations, Artis and colleagues teamed up with a group of pediatricians at the Children's Hospital of Philadelphia to examine basophil responses in children that suffer from the food allergy-associated disease, eosinophilic esophagitis, which causes inflammation of the esophagus. Previous studies have shown that TSLP is overexpressed in food allergy patients.

The team showed in the Nature paper that in children with food allergies basophils exhibited a different molecular make-up compared to non-allergy patients.

"It's promising that after more than 130 years since basophils were first discovered by Paul Ehrlich in Germany, we are still finding out new things about this cell population that could help in the design of new drugs to prevent or better fight allergic diseases," concludes Artis.

With more than 50 percent of Americans estimated to suffer from at least one allergic disease, says Artis, the team is hoping that targeting TSLP and basophils may offer new therapies for multiple allergic diseases.

In addition to Artis and Siracusa, co-authors are Steven A. Saenz, David A. Hill, Brian S. Kim, Travis A. Doering, E. John Wherry, and Taku Kambayashi, all from Penn, as well as Mark B. Headley and Steven F. Ziegler, Benaroya Research Institute, University of Washington School of Medicine; Heidi K. Jessup, Lori Siegel and Michael R. Comeau, Amgen Inc., Seattle; Emily C. Dudek, Antonella Cianferoni, & Jonathan M. Spergel, Children's Hospital of Philadelphia; and Masato Kubo, RIKEN Yokohama Institute, Tokyo University of Science.

The research was supported by the National Institutes of Health National Institute of Allergy and Infectious Diseases and the Burroughs Wellcome Fund.

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