Creating a Blood Vessel from Stem Cells

The technology for creating new tissues from stem cells has taken a giant leap forward. Two tablespoons of blood are all that is needed to grow a brand new blood vessel in just seven days. This is shown in a new study from Sahlgrenska Acadedmy and Sahlgrenska University Hospital published in EBioMedicine.

Just three years ago, a patient at Sahlgrenska University Hospital received a blood vessel transplant grown from her own stem cells.

Missing a vein

Professors Sumitran-Holgersson and Olausson have published a new study in EBioMedicine based on two other transplants that were performed in 2012 at Sahlgrenska University Hospital. The patients, two young children, had the same condition as in the first case – they were missing the vein that goes from the gastrointestinal tract to the liver.

"Once again we used the stem cells of the patients to grow a new blood vessel that would permit the two organs to collaborate properly," Professor Olausson says.

Stroke of genius

This time, however, Professor Sumitran-Holgersson, found a way to extract stem cells that did not necessitate taking them from the bone marrow.

"Drilling in the bone marrow is very painful," she says. "It occurred to me that there must be a way to obtain the cells from the blood instead."

The fact that the patients were so young fueled her passion to look for a new approach. The method involved taking 25 milliliter (approximately 2 tablespoons) of blood, the minimum quantity needed to obtain enough stem cells.

Blood willingly cooperates

Professor Sumitran-Holgersson's idea turned out to surpass her wildest expectations – the extraction procedure worked perfectly the very first time.

"Not only that, but the blood itself accelerated growth of the new vein," Professor Sumitran-Holgersson says. “The entire process took only a week, as opposed to a month in the first case. The blood contains substances that naturally promote growth."
 

More groups of patients can benefit

Professors Olausson and Sumitran-Holgersson have treated three patients so far. Two of the three patients are still doing well and have veins that are functioning as they should. In the third case the child is under medical surveillance and the outcome is more uncertain.

They researchers have now reached the point that they can avoid taking painful blood marrow samples and complete the entire process in the matter of a week.

"We believe that this technological progress can lead to dissemination of the method for the benefit of additional groups of patients, such as those with varicose veins or myocardial infarction, who need new blood vessels," Professor Holgersson says. “Our dream is to be able to grow complete organs as a way of overcoming the current shortage from donors.”

source
http://goo.gl/tPCA43

3D-Printed Heart Saves The Life Of A 14 Month Old Kid

3D-printing is one of the greatest technologies to come out in the past few years. It has been used by various industries in different fields and has allowed us to unveil new horizons. There is no doubt that this technology is revolutionizing the world, but now it’s even saving lives.

14-month old, Roland Lian Cung Bawi, from Owensboro, Kentucky was diagnosed with four congenital heart defects. He was admitted into the Kosair Children’s Hospital in Louisville, Kentucky where doctors knew immediately that the boy would need surgery. The only obstacle in the way was that doctor’s could not tell precisely what was wrong until they were in the middle of the surgery.

Surgeon Erie Austin realized that creating a 3D model of the boy’s heart would help study the defects and save the boy’s life. Dr. Austin called the Speed School of Engineering at the University of Louisville and told her of the problem and suggested a solution. The engineering department provided her a MakerBot 3D printer which would allow them to make a 3D model of the boy’s heart using 2D CT scans just as Dr. Austin had imagined. Tim Gornet, manager of the University’s Rapid Prototyping Center, was the one who the surgeon reached out to and his positive response helped save the boy’s life.

The Rapid Prototyping Center created a model made from a polymer known as ‘Ninja Flex’ which was 1.5 times larger than the boy’s heart (for easier inspection). Three general pieces of flexible filaments were made in the $2500 printer in 20 hours. The replica cost $600 to create, according to Gornet. The model helped doctors study the defects and come up with solutions before the critical surgery and on February 10th, 2014, Roland’s heart was repaired by Dr. Austin in what is the first use of 3-D printing for treating a pediatric heart patient.

The boy was released from the hospital on February 14th and and returned on February 21st for monitoring checks which showed good results. Thanks to Dr. Austin’s forward thinking and the savvy engineering team from the University of Louisville, a young life was saved and a new step was taken in medical technology that can save countless lives in the near future.

source

http://goo.gl/jfCvrc