Adual approach to create highly fun

Adual approach to create highly functionalized and architecturally
sound vasculature was recently developed by West and colleagues,
who used a PEG hydrogel tailored with RGD- and MMP-sensitive
peptides to support vascular network formation. They then applied
the hydrogel to a microfluidic system in order to mimic native
vascular organization and function (Moon et al., 2010). PEG-based
hydrogels tailored with RGD- and MMP-sensitive peptides have
been widely used for supporting vascular network formation (Moon
et al., 2009, 2010; Cuchiara et al., 2012; Turturro et al., 2013). The
authors first encapsulated HUVECs and mesenchymal progenitors
(10T1/2 cells) that exhibited a perivascular cell morphology within
PEG hydrogels containing both RGD peptides and MMP-sensitive
sites (Cuchiara et al., 2012). They found that the hydrogel supported
rapid vascular morphogenesis of the HUVEC and 10T1/2 cells, and
that the synthetic matrix was soon replaced with newly formed
basement membrane proteins, such as laminin and collagen type IV.
The authors then applied the engineered vasculatures to perfusable
microfabricated channels, thus culturing the HUVECs and 10T1/2
cells encapsulated within the synthetic hydrogels inside the
microchannels (Cuchiara et al., 2012). The use of microchannels
represents an innovative approach to perfusing and integrating the
vasculature with nutrient-containing fluids in vitro. Using this
approach, they found that nutrient transport within the system shifts
from simple diffusion to vessel-supported convective transport and
extra-vessel diffusion, meaning that the transport of nutrients was
more efficient and more closely replicated that of bona fide vascular
beds. This integrated approach has considerable value because it
mimics the complex in vivo environment using emerging
microfabrication technologies, and therefore holds great potential
for tissue-engineering applications in vivo.