A powerful
tool in medicine would be the ability to produce a tissue-scaffold which allows
for tissue which has been lost due to disease or trauma to be replaced with
fresh stem-cells. There are many barriers to the developemtn of this tool one
of which is ensuring that the stem-cells have the appropriate anchoring sites
as well as the correct growth factors to ensure their appropriate growth and
development. Recently, researchers working jointly at Fudan University (China),
Tianjin Medical University (China), Ewha Women’s University (Korea), and
University of Michigan utilized Maleimide-PEG-PLGA (PolyVivo AI136) and
fluorescently conjugated PLGA-FPR648 (Polyvivo AV008) from PolySciTech (www.polyscitech.com) to generate a scaffold which
allowed for controlled release of differentiation factors. They used the
developed scaffold to repair ischemic tissue in a mouse model. This research
holds promise to enable tissue repair and regeneration by successfully growing
differentiated stem-cells into damaged areas. Read more: Li, Ruixiang, Zhiqing
Pang, Huining He, Seungjin Lee, Jing Qin, Jian Wu, Liang Pang, Jianxin Wang,
and Victor C. Yang. "Drug depot-anchoring hydrogel: A self-assembling
scaffold for localized drug release and enhanced stem cell
differentiation." Journal of Controlled Release (2017). http://www.sciencedirect.com/science/article/pii/S016836591730706X
“Abstract:
Localized and long-term delivery of growth factors has been a long-standing
challenge for stem cell-based tissue engineering. In the current study, a
polymeric drug depot-anchoring hydrogel scaffold was developed for the
sustained release of macromolecules to enhance the differentiation of stem
cells. Self-assembling peptide (RADA16)-modified drug depots (RDDs) were
prepared and anchored to a RADA16 hydrogel. The anchoring effect of RADA16
modification on the RDDs was tested both in vitro and in vivo. It was shown
that the in vitro leakage of RDDs from the RADA16 hydrogel was significantly
less than that of the unmodified drug depots (DDs). In addition, the in vivo
retention of injected hydrogel-incorporated RDDs was significantly longer than
that of hydrogel-incorporated unmodified DDs. A model drug, vascular
endothelial growth factor (VEGF), was encapsulated in RDDs (V-RDDs) as drug
depot that was then anchored to the hydrogel. The release of VEGF could be
sustained for 4 weeks. Endothelial progenitor cells (EPCs) were cultured on the
V-RDDs-anchoring scaffold and enhanced cell proliferation and differentiation
were observed, compared with a VEGF-loaded scaffold. Furthermore, this scaffold
laden with EPCs promoted neovascularization in an animal model of hind limb
ischemia. These results demonstrate that self-assembling hydrogel-anchored
drug-loaded RDDs are promising for localized and sustained drug release, and
can effectively enhance the proliferation and differentiation of resident stem
cells, thus lead to successful tissue regeneration. Graphical abstract: Schematic
illustration of a vascular endothelial growth factor (VEGF)-loaded
RDDs-anchoring hydrogel. The RADA16 peptide is the basic self-assembling unit
forming fiber and constructing hydrogel; poly (lactic-co-glycolic acid) (PLGA)
based, VEGF-loaded drug depots (DDs) were modified using the RADA16 peptide
(V-RDDs) to anchor them to the skeleton of the hydrogel; PEG was applied as a
spacer to ensure the full stretch of the RADA16 peptide. VEGF demonstrated
sustained release into the hydrogel to enhance the proliferation and
differentiation of resident EPCs. Keywords: PLGA; RADA16 hydrogel; Sustained
release; Endothelial progenitor cells; Vascular endothelial growth factor;
Tissue regeneration”
