Biofabrication of reinforced 3D-scaffolds using two-component hydrogels

Boere, Kristel W. M.; Blokzijl, Maarten M.; Visser, Jetze; Linssen, J. Elder A.; Malda, Jos; Hennink, Wim E.; Vermonden, Tina

doi:10.1039/c5tb01645b

Cited by 60 publications

(53 citation statements)

References 49 publications

(98 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…When encapsulating the same number of chondrocytes homogeneously in the hydrogel (condition B), differentiating cell clusters rich in GAGs and collagen type II formed. The formation of such clusters is often observed in cartilage tissue engineering using cell-laden hydrogel constructs, and was also reported for gelMA-based constructs after 2 months of subcutaneous implantation in a rat model (Boere et al, 2015). For a complete mimicry of cartilage architecture, these clusters should mature and reorganize according to the zone in which they are located; however this will depend also on the degradation profile of the hydrogel and its longer-term performance, which could be the subject of future studies.…”

Section: Contribution Of Endogenous and Delivered Cells In Cartilage mentioning

confidence: 99%

Ex vivo model unravelling cell distribution effect in hydrogels for cartilage repair

Mouser

2018

ALTEX

View full text Add to dashboard Cite

Summary The implantation of chondrocyte-laden hydrogels is a promising cartilage repair strategy. Chondrocytes can be spatially positioned in hydrogels and thus in defects, while current clinical cell therapies introduce chondrocytes in the defect depth. The main aim of this study was to evaluate the effect of spatial chondrocyte distribution on the reparative process. To reduce animal experiments, an ex vivo osteochondral plug model was used and evaluated. The role of the delivered and endogenous cells in the repair process was investigated. Full thickness cartilage defects were created in equine osteochondral plugs. Defects were filled with (A) chondrocytes at the bottom of the defect, covered with a cell-free hydrogel, (B) chondrocytes homogeneously encapsulated in a hydrogel, and (C, D) combinations of A and B with different cell densities. Plugs were cultured for up to 57 days, after which the cartilage and repair tissues were characterized and compared to baseline samples. Additionally, at day 21, the origin of cells in the repair tissue was evaluated. Best outcomes were obtained with conditions C and D, which resulted in well-integrated cartilage-like tissue that completely filled the defect, regardless of the initial cell density. A critical role of the spatial chondrocyte distribution in the repair process was observed. Moreover, the osteochondral plugs stimulated cartilage formation in the hydrogels when cultured in the defects. The resulting repair tissue originated from the delivered cells. These findings confirm the potential of the osteochondral plug model for the optimization of the composition of cartilage implants and for studying repair mechanisms.

show abstract

Section: Contribution Of Endogenous and Delivered Cells In Cartilage mentioning

confidence: 99%

Ex vivo model unravelling cell distribution effect in hydrogels for cartilage repair

Mouser

2018

ALTEX

View full text Add to dashboard Cite

show abstract

“…This reinforced construct exhibited an elastic modulus of 9 kPa after 3 h, and showed high cell viability of chondrocytes. 118 In another study, a photopolymerizable and thermosensitive A-B-A type triblock copolymer ink was developed. 119 The ink was composed of poly( N -(2-hydroxypropyl)methacrylamide lactate) A-blocks partially functionalized with methacrylate groups, and poly(ethylene glycol) B-blocks.…”

Section: Inks: 3d Printable Biomaterialsmentioning

confidence: 99%

Designing Biomaterials for 3D Printing

Guvendiren

Molde

Soares

et al. 2016

ACS Biomater. Sci. Eng.

607

494

View full text Add to dashboard Cite

Three-dimensional (3D) printing is becoming an increasingly common technique to fabricate scaffolds and devices for tissue engineering applications. This is due to the potential of 3D printing to provide patient-specific designs, high structural complexity, rapid on-demand fabrication at a low-cost. One of the major bottlenecks that limits the widespread acceptance of 3D printing in biomanufacturing is the lack of diversity in “biomaterial inks”. Printability of a biomaterial is determined by the printing technique. Although a wide range of biomaterial inks including polymers, ceramics, hydrogels and composites have been developed, the field is still struggling with processing of these materials into self-supporting devices with tunable mechanics, degradation, and bioactivity. This review aims to highlight the past and recent advances in biomaterial ink development and design considerations moving forward. A brief overview of 3D printing technologies focusing on ink design parameters is also included.

show abstract

“…A common composite choice for thermoresponsive “bioinks” consists of HA or chondroitin sulfate mixed with a thermoresponsive polymer. Numerous groups have tested different thermoresponsive materials in this regard, from poly(N-isopropylacrylamide) (pNIPAAM) (Kesti et al ., 2015) to triblock copolymers composed of PEG linked to N-(2-hydroxypropyl) methacrylamide (HPMA) (Boere et al ., 2015). …”

Section: B Advances In the Processing Of Hydrogel Scaffoldsmentioning

confidence: 99%

Recent advances in hydrogels for cartilage tissue engineering

Vega¹,

Kwon²,

Burdick

2017

eCM

240

171

View full text Add to dashboard Cite

Articular cartilage is a load-bearing tissue that lines the surface of bones in diarthrodial joints. Unfortunately, this avascular tissue has a limited capacity for intrinsic repair. Treatment options for articular cartilage defects include microfracture and arthroplasty; however, these strategies fail to generate tissue that adequately restores damaged cartilage. Limitations of current treatments for cartilage defects have prompted the field of cartilage tissue engineering, which seeks to integrate engineering and biological principles to promote the growth of new cartilage to replace damaged tissue. To-date, a wide range of scaffolds and cell sources have emerged towards cartilage tissue engineering, with a focus on recapitulating microenvironments present during development or in adult tissue to induce the formation of cartilaginous constructs with biochemical and mechanical properties of native tissue. Hydrogels have emerged as a promising scaffold due to the wide range of properties that are possible and the ability to entrap cells within the material. Towards improving cartilage repair, hydrogel design has advanced in recent years to improve their utility. Some of these advances include the development of improved network crosslinking (e.g., double-networks), new techniques to process hydrogels (e.g., 3D printing), and the better incorporation of biological signals (e.g., controlled release). This review summarizes these innovative approaches to engineer hydrogels towards cartilage repair, with an eye towards eventual clinical translation.

show abstract

Biofabrication of reinforced 3D-scaffolds using two-component hydrogels

Cited by 60 publications

References 49 publications

Ex vivo model unravelling cell distribution effect in hydrogels for cartilage repair

Ex vivo model unravelling cell distribution effect in hydrogels for cartilage repair

Designing Biomaterials for 3D Printing

Recent advances in hydrogels for cartilage tissue engineering

Contact Info

Product

Resources

About