4 research outputs found
Tissue-Adhesive Hydrogel Spray System for Live Cell Immobilization on Biological Surfaces
Gelatin hydrogels are used as three-dimensional cell
scaffolds
and can be prepared using various methods. One widely accepted approach
involves crosslinking gelatin amino groups with poly(ethylene glycol)
(PEG) modified with N-hydroxysuccinimide ester (PEG-NHS).
This method enables the encapsulation of live cells within the hydrogels
and also facilitates the adhesion of the hydrogel to biological tissues
by crosslinking their surface amino groups. Consequently, these hydrogels
are valuable tools for immobilizing cells that secrete beneficial
substances in vivo. However, the application of gelatin hydrogels
is limited due to the requirement for several minutes to solidify
under conditions of neutral pH and polymer concentrations suitable
for live cells. This limitation makes it impractical for use with
biological tissues, which have complex shapes or inclined surfaces,
restricting its application to semi-closed spaces. In this study,
we propose a tissue-adhesive hydrogel that can be sprayed and immobilized
with live cells on biological tissue surfaces. This hydrogel system
combines two components: (1) gelatin/PEG-NHS hydrogels and (2) instantaneously
solidifying PEG hydrogels. The sprayed hydrogel solidified within
5 s after dispensing while maintaining the adhesive properties of
the PEG-NHS component. The resulting hydrogels exhibited protein permeability,
and the viability of encapsulated human mesenchymal stem/stromal cells
(hMSCs) remained above 90% for at least 7 days. This developed hydrogel
system represents a promising approach for immobilizing live cells
on tissue surfaces with complex shapes
Tissue-Adhesive Hydrogel Spray System for Live Cell Immobilization on Biological Surfaces
Gelatin hydrogels are used as three-dimensional cell
scaffolds
and can be prepared using various methods. One widely accepted approach
involves crosslinking gelatin amino groups with poly(ethylene glycol)
(PEG) modified with N-hydroxysuccinimide ester (PEG-NHS).
This method enables the encapsulation of live cells within the hydrogels
and also facilitates the adhesion of the hydrogel to biological tissues
by crosslinking their surface amino groups. Consequently, these hydrogels
are valuable tools for immobilizing cells that secrete beneficial
substances in vivo. However, the application of gelatin hydrogels
is limited due to the requirement for several minutes to solidify
under conditions of neutral pH and polymer concentrations suitable
for live cells. This limitation makes it impractical for use with
biological tissues, which have complex shapes or inclined surfaces,
restricting its application to semi-closed spaces. In this study,
we propose a tissue-adhesive hydrogel that can be sprayed and immobilized
with live cells on biological tissue surfaces. This hydrogel system
combines two components: (1) gelatin/PEG-NHS hydrogels and (2) instantaneously
solidifying PEG hydrogels. The sprayed hydrogel solidified within
5 s after dispensing while maintaining the adhesive properties of
the PEG-NHS component. The resulting hydrogels exhibited protein permeability,
and the viability of encapsulated human mesenchymal stem/stromal cells
(hMSCs) remained above 90% for at least 7 days. This developed hydrogel
system represents a promising approach for immobilizing live cells
on tissue surfaces with complex shapes
Tissue-Adhesive Hydrogel Spray System for Live Cell Immobilization on Biological Surfaces
Gelatin hydrogels are used as three-dimensional cell
scaffolds
and can be prepared using various methods. One widely accepted approach
involves crosslinking gelatin amino groups with poly(ethylene glycol)
(PEG) modified with N-hydroxysuccinimide ester (PEG-NHS).
This method enables the encapsulation of live cells within the hydrogels
and also facilitates the adhesion of the hydrogel to biological tissues
by crosslinking their surface amino groups. Consequently, these hydrogels
are valuable tools for immobilizing cells that secrete beneficial
substances in vivo. However, the application of gelatin hydrogels
is limited due to the requirement for several minutes to solidify
under conditions of neutral pH and polymer concentrations suitable
for live cells. This limitation makes it impractical for use with
biological tissues, which have complex shapes or inclined surfaces,
restricting its application to semi-closed spaces. In this study,
we propose a tissue-adhesive hydrogel that can be sprayed and immobilized
with live cells on biological tissue surfaces. This hydrogel system
combines two components: (1) gelatin/PEG-NHS hydrogels and (2) instantaneously
solidifying PEG hydrogels. The sprayed hydrogel solidified within
5 s after dispensing while maintaining the adhesive properties of
the PEG-NHS component. The resulting hydrogels exhibited protein permeability,
and the viability of encapsulated human mesenchymal stem/stromal cells
(hMSCs) remained above 90% for at least 7 days. This developed hydrogel
system represents a promising approach for immobilizing live cells
on tissue surfaces with complex shapes
Microscopic Structure of the “Nonswellable” Thermoresponsive Amphiphilic Conetwork
We investigated the microscopic structure
of the nonswellable hydrogel
using small-angle neutron scattering (SANS). The hydrogel consisted
of four-armed thermoresponsive prepolymer units embedded in a homogeneous
network of four-armed poly(ethylene glycol) (Tetra-PEG). The structure
of the hydrogel was similar to that of the ordinary Tetra-PEG hydrogels
at temperatures below 16.6 °C, whereas discrete spherical domains
were formed at temperatures above 19.5 °C. The number of prepolymer
units contained in one domain was much larger than unity, indicating
that multiple thermoresponsive prepolymer units as well as Tetra-PEG
units gathered to form a domain. Formation of domains much larger
than a single prepolymer unit led to significant frustration of the
matrix polymer network outside the domains. This frustration enhanced
the elastic energy of the matrix network which would cancel the osmotic
pressure and induce significant macroscopic shrinking. The selection
mechanism of the domain size could qualitatively be explained by the
balance between the interfacial and conformational free energies