Tag Archives: stem cell

Printing–a new way to save a life.

Posted on March 18, 2013 by | 1 comment

A depiction of some of the many organs of the body from Achim Raschka via Wikimedia Commons.

The need for organs for people suffering from disease is ever-growing, and high.

This need has resulted in large scale ethical debates, some doctors opting for more radical ways to harvest organs. At the same time, patients are dying because they were not given a transplant promptly. The current situation in North America is dismal at best.

However, hope does exist! A recent innovation reported by a group of researchers at Heriot-Watt University could solve the problem. How you might wonder? By what scientists are calling “organ printing“.

Organ printing is a technology combining the concept of 3-dimensional printing and stem cells. A 3-dimensional printer is a machine that is able to make 3D objects when given some sort of electronic plan for the object to be printed. Traditionally, 3D printers have used metals or plastics as the ink for making objects. But instead of metal or plastic, an organ printer uses embryonic stem cells as ink; cells that are able to divide and change their identity into any other cells such as heart, lung, kidney or even brain cells, and carry out their function.

A printer that uses cells as ink could make organs! Pictures adapted from Seahen, Jomegat and Osnimf (left to right) via Wikimedia Commons.

You might wonder why this would be considered a huge breakthrough. The discovery of stem cells heralded a large amount of attention. We initially believed that we would be able to grow organs easily; however, over time, we learned that stem cells are more complex than we realized. Stem cell growth is difficult to control. Even though we can currently make a stem cell change its identity into a cell we want it to be, we cannot effectively mesh groups of cells into highly organized layers, like how complex organs such as the heart and kidneys are laid out. Experiments reported as late as three years ago could only make balls of different cell types from stem cells using chemicals. 3D printing using stem cells allows us to organize cells and distribute them the way we want them to be, and so, we could make complex structures with different layers in a consistent way in the near future.

Below, Dr. Anthony Atala talks about organ printing techniques he is researching in his lab.

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By CNN via Youtube.

But how near is the near future? I remain skeptical. Stem cells are complex things, and we have much to learn about them. Just because we place them in the right positions in the right type does not mean that all problems will be solved. Additionally, we have yet to research where to place cells so that they function the right way in an organ. I would think that this technology would take at least 10 years to be relevant to our everyday lives. Only time will tell.

-Shaun

 

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An Origin of Schizophrenia Revealed

Posted on March 4, 2013 by | 5 comments

 

Comparing the prevalence of Schizophrenia with other diseases. From Schizophrenia.com.

Schizophrenia is a mental illness that is characterized by delusions and hallucinations. Because the symptoms affect the cognitive and social functions of an individual, and the prevalence of schizophrenia is high, psychiatrists and psychologists are doing researches to find origins of this illness in order to develop a better treatment for this illness. A recent stem cell research at University at Buffalo revealed that schizophrenia is induced by defects in an important genomic pathway in a stem cell. These defects in the pathway can be responsible for onset of the disorder later in life.  

This important genomic pathway is called the Integrative Nuclear Fibroblast Growth Factor Receptor 1 Signalling (INFS). It is a platform for the integration of signals that come from many other pathways, involving around 160 genes that are linked to schizophrenia. To study the consequences of the defects of INFS, laboratory mice are used as the model organisms.
 
Using the mouse model, the researchers found some interesting results. It was observed in embroynic stem cells that some genes that are linked to schizophrenia binded with Fibroblast Growth Factor Receptor 1 (FGFR1) protein, which is an essential protein for cell division, cell growth and cell differentiation, and also has a cascading effect on the INFS pathway. To test the relationship between FGFR1 protein and schizophrenia, a mutation of FGRR1 protein was made in the mice. This mutation created structural changes in mice’s brain, alterations in mice’s behaviour, and overwhelmed sensory processes in mice. Those symptoms in mice resembled the human disease, schizophrenia. Therefore, it can be concluded that an alteration in the transition from stem cells to neurons will result in schizophrenia. In addition, this study supported that nicotinic agonists (medications that activates the nicotinic acetylcholine receptors in neurons) could help the schizophrenics to have better cognitive functions.  
 

The picture shows that fibroblast growth factor receptor 1 (FGFR1) interacts with multiple genes that are linked to schizophrenia. Arrows point to the nuclei of human embroynic stem cells. Picture from: University at Buffalo, News Centre.

Researchers found an genomic explanation to the causes of schizophrenia using a mouse model. The head researcher, Michal Stachowiak, mentioned that this can lead to a generalized approach to treat schizophrenia if it is sure that a malfunction of a common genomic pathway is the cause for the disorder. He also proposed that possible methods that would stop the illness from developing could be created in the future. I have a high hope for the development of better treatments and even a cure for schizophrenia based on the current understanding of schizophrenia and technologies.

– (Shirley) Yu Chen

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