Polyion complex fiber and capsule formed by self-assembly of poly-L-Lysine and gellan at solution interfaces

Yamamoto, Hiroyuki; Horita, Chikako; Senoo, Yukiko; Nishida, Atsushi; Ohkawa, Kousaku

doi:10.1002/1097-4628(20010118)79:3<437::aid-app60>3.0.co;2-q

Cited by 39 publications

(10 citation statements)

References 41 publications

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“…The PEC fibrous scaffold is designed to take advantage of the complementary merits of these two classes of biomaterials. Interfacial polyelectrolyte complexation has been used to produce polyion complex fibers like poly(lysine)–gellan [28] and water-soluble chitin–alginate [4] and we have previously applied this concept to encapsulate different biologics, including cells, using the alginate–chitin polyelectrolyte pair [4,6]. However, these alginate– chitin PEC fibers were mechanically weak and suboptimal for cell adhesion and proliferation.…”

Section: Discussionmentioning

confidence: 99%

Collagen-based fibrous scaffold for spatial organization of encapsulated and seeded human mesenchymal stem cells

et al. 2009

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Living tissues consist of groups of cells organized in a controlled manner to perform a specific function. Spatial distribution of cells within a three-dimensional matrix is critical for the success of any tissue-engineering construct. Fibers endowed with cell-encapsulation capability would facilitate the achievement of this objective. Here we report the synthesis of a cell-encapsulated fibrous scaffold by interfacial polyelectrolyte complexation (IPC) of methylated collagen and a synthetic terpolymer. The collagen component was well distributed in the fiber, which had a mean ultimate tensile strength of 244.6 ± 43.0 MPa. Cultured in proliferating medium, human mesenchymal stem cells (hMSCs) encapsulated in the fibers showed higher proliferation rate than those seeded on the scaffold. Gene expression analysis revealed the maintenance of multipotency for both encapsulated and seeded samples up to 7 days as evidenced by Sox 9, CBFA-1, AFP, PPARγ2, nestin, GFAP, collagen I, osteopontin and osteonectin genes. Beyond that, seeded hMSCs started to express neuronal-specific genes such as aggrecan and MAP2. The study demonstrates the appeal of IPC for scaffold design in general and the promise of collagen-based hybrid fibers for tissue engineering in particular. It lays the foundation for building fibrous scaffold that permits 3D spatial cellular organization and multi-cellular tissue development.

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Section: Discussionmentioning

confidence: 99%

Collagen-based fibrous scaffold for spatial organization of encapsulated and seeded human mesenchymal stem cells

et al. 2009

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“…When a negatively charged polyelectrolyte such as alginate or g-PGA is introduced, a polyion complex can be formed by electrostatic attraction at the interfaces [18,19]. This phenomenon was used to fabricated fibers and capsules in several previous studies [20][21][22][23][24][25][26][27]. However, it is quite difficult to obtain a homogeneous solution of g-PGA and chitosan.…”

Section: Introductionmentioning

confidence: 99%

Preparation of γ-PGA/chitosan composite tissue engineering matrices

et al. 2005

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“…The method designed using polymer and interfacial chemistry was simple, versatile, and practiced under conditions that were closer to natural conditions. Most recently, we have succeeded in preparing water‐insoluble self‐assembled capsules and fibers by forming PICs as a thin film between two oppositely charged polyelectrolyte aqueous solutions, and by skillfully controlling the interface made out of the thin film 19–23. Our first work involved the formation and the characteristics of polysaccharide PIC fibers and capsules formed by electrostatic interactions with cationic chitosan19 [(1 → 4)‐2‐amino‐2‐deoxy‐ β ‐ D ‐glucan] and anionic gellan20 (comprising 1,3‐ β ‐ D ‐glucose, 1,4‐ β ‐ D ‐glucuronic acid, 1,4‐ β ‐ D ‐glucose, and 1,4‐ α ‐ L ‐rhamnose), in aqueous solutions 21.…”

Section: Introductionmentioning

confidence: 99%

“…Our first work involved the formation and the characteristics of polysaccharide PIC fibers and capsules formed by electrostatic interactions with cationic chitosan19 [(1 → 4)‐2‐amino‐2‐deoxy‐ β ‐ D ‐glucan] and anionic gellan20 (comprising 1,3‐ β ‐ D ‐glucose, 1,4‐ β ‐ D ‐glucuronic acid, 1,4‐ β ‐ D ‐glucose, and 1,4‐ α ‐ L ‐rhamnose), in aqueous solutions 21. The poly( α , L ‐lysine) (PLL)/gellan22 and chitosan/poly( α , L ‐glutamic acid) (PLG)23 PIC fibers and capsules are the first and second PIC materials composed of polysaccharides and polypeptides.…”

Section: Introductionmentioning

confidence: 99%

Preparation of Silk‐Like Fibers Designed by Self‐Assembled Ionic Polypeptides

Hachisu

Ohkawa

Yamamoto

2003

Macromolecular Bioscience

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Natural protein fibers, such as silk, having high‐performance characteristics have been important materials in biopolymer research. This article reports the development of a silk‐like extensible poly(α,L‐amino acid) fiber inspired by self‐assembly of polypeptides in living systems. Electrostatic interaction was employed as the driving force for building the fiber, and we succeeded in spinning the fiber from an aqueous solution interface between poly(α,L‐lysine) (PLL) and poly(α,L‐glutamic acid) (PLG). When the PLL/PLG fiber was formed, the conformations of PLL and PLG were changed from random to β‐structures. A remarkable feature of the PLL/PLG fiber is the high extensibility. Mechanical stretching of the PLL/PLG fiber resulted in a change from an extensible fiber to a rigid and strong fiber. These features depend on the molecular conformation and the deviation in the amino acid composition of the PLL/PLG fibers. This concept and the poly(α,L‐amino acid) fibers themselves allow the production of new protein fibers and aid the development of the science of protein folding as well as giving insight into the noncovalent interactions involved in self‐assembly.SEM micrograph showing that the surface of the stretched fiber is smooth.magnified imageSEM micrograph showing that the surface of the stretched fiber is smooth.

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Polyion complex fiber and capsule formed by self-assembly of poly-L-Lysine and gellan at solution interfaces

Cited by 39 publications

References 41 publications

Collagen-based fibrous scaffold for spatial organization of encapsulated and seeded human mesenchymal stem cells

Collagen-based fibrous scaffold for spatial organization of encapsulated and seeded human mesenchymal stem cells

Preparation of γ-PGA/chitosan composite tissue engineering matrices

Preparation of Silk‐Like Fibers Designed by Self‐Assembled Ionic Polypeptides

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