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[chubtoad]

http://www.scienceda...31014072010.htm
Source: Massachusetts Institute Of Technology
Date: 2003-10-14

MIT Engineers Report New Approach To Tissue Engineering

MIT engineers report a new approach to creating three-dimensional samples of human tissue that could push researchers closer to their ultimate goal: tissues for therapeutic applications and replacement organs. The technique could also help answer questions in cell and developmental biology.
The team "seeded" human embryonic stem cells, which have the potential to differentiate into a variety of specialized cells, onto a biodegradable polymer scaffold. By treating the scaffold/stem cell structure with chemical cues, or growth factors, known to stimulate the formation of specific cell types, the researchers coaxed the stem cells to form tissues with characteristics of developing human cartilage, liver, nerves and blood vessels.
"Here we show for the first time that polymer scaffolds … promoted proliferation, differentiation and organization of human embryonic stem cells into 3D structures," the researchers wrote in a paper to appear the week of Oct. 13 in the online edition of the Proceedings of the National Academy of Sciences.

Further, the resulting tissues continued to thrive when implanted in mice with suppressed immune systems (to eliminate rejection). They expressed human proteins, and integrated with the host's blood-vessel networks.

"For me it was very exciting to see that these [stem] cells could move around and start to 'talk' with one another, generating the different cell types common to a given tissue and organizing into that tissue," said Shulamit Levenberg, first author of the paper and a research associate in the Department of Chemical Engineering.

The technique could also have an impact on the study of cell and developmental biology. "When you give cells a three-dimensional structure [on which to grow], it's really a lot more like what's happening in the embryo," said Levenberg, a mother of four whose youngest child is seven months old.

Levenberg's colleagues on the work are Robert Langer, the Germeshausen Professor of Chemical and Biomedical Engineering; MIT alumna Ngan Huang (S.B. 2002); Erin Lavik, a postdoctoral fellow in the MIT-Harvard Division of Health Sciences and Technology who is now a professor at Yale; Arlin Rogers of MIT's Division of Comparative Medicine; and Joseph Itskovitz-Eldor of the Technion in Israel.

The work provides a new approach to prodding stem cells to grow into different tissues. Before, researchers created a variety of cell types from one batch of stem cells, then isolated the cell type of interest. The isolated cells were then grown on a given medium, such as a polymer scaffold. The same MIT team did just that last year with the endothelial cells that blood vessels are composed of.

This time around, the MIT researchers seeded stem cells directly into the scaffold. "We found that with different growth factors, we could push them in different directions," said Levenberg.

The polymer scaffold is key. "The scaffold provides physical cues for cell orientation and spreading, and pores provide space for remodeling of tissue structures," the researchers wrote.
The scaffold was carefully engineered. "If the scaffold is too soft," for example, "it collapses under the cells' mechanical forces," said Levenberg. The team also used two different polymers to create the scaffold. "One degrades quickly, the other more slowly," she said. "That gives cells room to grow while still retaining a support structure for them."

The work was supported by the National Institutes of Health. The human embryonic stem cells are from an NIH-approved line.

[Lazarus Long]

Hi Chubtoad, here is a followup article and I thought I would let you know that we have this thread available for these types of posts.

General MedTech & New Methods

Eventually we should do some housecleaning and merge some threads but for now if you want to keep posting them individually to bring them to everyone's attention thats fine.

It is certainly a very important and relevant article and the reason consolidating them is important is so we can begin to create a systematic approach to study making such research easier here in the forum for new arrivals IMO. We are beginning to gather a remarkable database thanks to the help of individuals such as you. Thank you.

http://news.bbc.co.u...lth/3188340.stm

'Bio-scaffolds' spark organ hope
Saturday, 18 October, 2003

The scaffold became clogged with cell growth

Human cells have been grown on tiny frames - raising hopes that it may be possible to create whole organs for transplant. The microscopic "scaffolds" - made in the US - release chemicals which help produce various cell types.

Scientists say it will still be many years before whole new organs can be "grown to order" in a laboratory.

However, the 3D tissue samples produced could help doctors study how diseases progress and spread through the body.

The key advance made by the research team, from the Massachusetts Institute of Technology (MIT), is to prompt human "stem cells" to develop into different cell types, such as cartilage, liver, nerve and blood vessel.

"Stem cells" are found in the human embryo, and have the ability to become every different cell type in the body, given the right conditions.

The idea is that the cells grow into the required structure, creating their own "matrix" to support themselves, as well as a blood supply to keep themselves alive.

Disappearing frame

To achieve this, the polymer "frame" on which they are grown is designed to degrade at the right point so it does not get in the way.

The MIT scaffold was actually built from two different types of material, one designed to disappear quickly, and another to provide lasting support.

When the tissue structures they had created were implanted into mice, they continued to thrive, and actually integrated with the blood vessel networks in the animals. Dr Shulamit Levenberg, one of the authors of the research, published in the Proceedings of the National Academy of Sciences, said: "When you give cells a three-dimensional structure on which to grow, it's really a lot more like what's happening in the embryo."

The cells were exposed to chemical "growth factors", which helped prompt them to grow and to become different types of human cell.

Huge task

Many different research teams around the world are working on ways to encourage their cells to grow in three dimensions rather than just two.

When you give cells a three-dimensional structure on which to grow, it's really a lot more like what's happening in the embryo
Dr Shulamit Levenberg, MIT 

Dr Ying Yang, from Keele University, said that the various factors involved were highly complex - and that it would be some time before scientists could recreate the exact conditions which accompany growth of new tissues within the body.

She said: "What we know is that cells grown on our three-dimensional structures are currently not the same as those which grow naturally in the body."

She said that a variety of factors - the number and type of growth factor chemicals used, their concentration, and the timing of their application - could all be subtly adjusted in order to find the right combination.

Her own research involves placing the developing structure under a mechanical force to produce a more life-like structure. She said: "Our research has already shown that structures built under mechanical force produce better proteins."

She agreed that the growing of replacement organs for transplantation was some distance away.