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Leukemia treatment given shot in the arm by artificial bone marrow development

Leukemia treatment given shot in the arm by artificial bone marrow development
Scanning electron microscopy of stem cells (yellow / green) in a scaffold structure (blue) serving as a basis for the artificial bone marrow (Photo: C. Lee-Thedieck/KIT)
Scanning electron microscopy of stem cells (yellow / green) in a scaffold structure (blue) serving as a basis for the artificial bone marrow (Photo: C. Lee-Thedieck/KIT)
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The development of artificial bone marrow stands to greatly increase the availability of treatment for leukemia sufferers (Photo: C. Lee-Thedieck/KIT)
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The development of artificial bone marrow stands to greatly increase the availability of treatment for leukemia sufferers (Photo: C. Lee-Thedieck/KIT)
Scanning electron microscopy of stem cells (yellow / green) in a scaffold structure (blue) serving as a basis for the artificial bone marrow (Photo: C. Lee-Thedieck/KIT)
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Scanning electron microscopy of stem cells (yellow / green) in a scaffold structure (blue) serving as a basis for the artificial bone marrow (Photo: C. Lee-Thedieck/KIT)

European researchers have announced a breakthrough in the development of artificial bone marrow which expands the ability of scientists to reproduce stem cells in the lab and could lead to increased availability of treatment for leukemia sufferers.

One of the main treatments for the blood cancer is the injection of hematopoietic stem cells (HSCs). These HSCs can either be harvested from a compatible donor or cultivated from the patient’s own bone marrow in the lab.

The greatest challenges in producing HSCs in the lab has been their limited longevity outside of the bone marrow environment. This problem may soon be circumvented with the creation of an artificial bone marrow by the Young Investigators Group for Stem Cell– Material Interactions.

Headed by Dr. Cornelia Lee-Thedieck the group consists of scientists from the KIT Institute of Functional Interfaces (IFG), the Max Planck Institute for Intelligent Systems, Stuttgart, and Tübingen University.

The cultivation of HSCs with current methods is limited as they quickly change into mature blood cells in culture in a process known as differentiation. HSCs are capable of developing into one of 10 different cell types. These mature cells are short lived and are not capable of self-renewal. HSCs, however, can continuously self-renew in healthy bone marrow. So the challenge facing researchers has been creating a surrogate for bone marrow in the lab which allows for the cultivation of HSCs.

Using macroporous hydrogel scaffolds the Young Investigators Group produced a substance that mimics the spongy structure of trabecular bone, the material within bone where bone marrow is held. To this hydrogel architecture a number of proteins found in bone marrow were added for the HSCs to bind to. Other conditions important for HSC self-renewal in trabecular bone were also created by adding mesenchymal stem cells (MSCs) from bone marrow and umbilical cord.

When tested by adding HSCs from umbilical cord blood to the artificial bone marrow it was found that the cells were both able to self-renew and retain their ability to differentiate. The next step for the research is to identify how the behavior of stem cells can be manipulated by synthetic materials.

The team hopes within the next ten to fifteen years this research could lead to the development of an artificial environment for the reproduction of stem cells and the treatment of leukemia.

The research was recently published in the journal Biomaterials.

Source: Karlsruhe Institute of Technology

1 comment
1 comment
Walter Komarnicki
sounds promising