Redifferentiation of High-Throughput Generated Fibrochondrocyte Micro-Aggregates: Impact of Low Oxygen Tension

Front. Bioeng. Biotechnol.

Fernandez

Vercruysse

et al. 2020

Self Cite

To date, the treatment of articular cartilage lesions remains challenging. A promising strategy for the development of new regenerative therapies is hybrid bioprinting, combining the principles of developmental biology, biomaterial science, and 3D bioprinting. In this approach, scaffold-free cartilage microtissues with small diameters are used as building blocks, combined with a photo-crosslinkable hydrogel and subsequently bioprinted. Spheroids of human bone marrow-derived mesenchymal stem cells (hBM-MSC) are created using a high-throughput microwell system and chondrogenic differentiation is induced during 42 days by applying chondrogenic culture medium and low oxygen tension (5%). Stable and homogeneous cartilage spheroids with a mean diameter of 116 ± 2.80 µm, which is compatible with bioprinting, were created after 14 days of culture and a glycosaminoglycans (GAG)and collagen II-positive extracellular matrix (ECM) was observed. Spheroids were able to assemble at random into a macrotissue, driven by developmental biology tissue fusion processes, and after 72 h of culture, a compact macrotissue was formed. In a directed assembly approach, spheroids were assembled with high spatial control using the bio-ink based extrusion bioprinting approach. Therefore, 14-day spheroids were combined with a photo-crosslinkable methacrylamide-modified gelatin (gelMA) as viscous printing medium to ensure shape fidelity of the printed construct. The photo-initiators Irgacure 2959 and Li-TPO-L were evaluated by assessing their effect on bio-ink properties and the chondrogenic phenotype. The encapsulation in gelMA resulted in further chondrogenic maturation observed by an increased production of GAG and a reduction of collagen I. Moreover, the use of Li-TPO-L lead to constructs with lower stiffness which induced a decrease of collagen I and an increase in GAG and collagen II production. After 3D bioprinting, spheroids remained viable and the cartilage phenotype was maintained. Our findings demonstrate that hBM-MSC spheroids are able to differentiate into cartilage microtissues and display a geometry compatible with 3D bioprinting. Furthermore, for hybrid bioprinting of these spheroids,

Section: Fabrication Of Non-adhesive Microwellsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Hybrid Bioprinting of Chondrogenically Induced Human Mesenchymal Stem Cell Spheroids

Front. Bioeng. Biotechnol.

Fernandez

Vercruysse

et al. 2020

Self Cite

“…Generation of Spheroids by Micromolding: Spheroids were generated using a non-adhesive microwell system, as previously described. [5,10,65,66] In brief, customized patterned negative polydimethylsiloxane (PDMS) molds (ø = 18 mm, NaMiFab, Ghent University) were placed in the wells of a 6-well plate. A sterile 4.5 w/v% Ultrapure agarose (Life technologies) solution was poured on top of the negative PDMS molds and after solidification at room temperature, agarose microwells were separated from the molds with sterile gloves.…”

Section: Methodsmentioning

confidence: 99%

“…[ 5–7 ] In order to regain phenotype, the native cartilage microenvironment can be mimicked in several ways, for example, by adding growth factors to the culture medium such as TGF‐β [ 8,9 ] or by incubating the cells in a low oxygen environment, as hypoxia results in an increase of cartilage ECM components such as collagen II and aggrecan. [ 10,11 ] The creation of a 3D culture environment, by either encapsulation of cells in a hydrogel or cellular self‐aggregation in 3D cell pellets or spheroids, can also induce chondrogenic (re)differentiation due to the high cell density and the formation of cell–cell and cell–ECM contacts. [ 5,12 ] The latter gives promising prospects to use self‐assembled spheroids as building blocks to generate tissue‐engineered cartilage instead of the conventional single cell suspension.…”

Section: Introductionmentioning

confidence: 99%

Tuning the Phenotype of Cartilage Tissue Mimics by Varying Spheroid Maturation and Methacrylamide‐Modified Gelatin Hydrogel Characteristics

Macromolecular Bioscience

Minne

Tytgat

et al. 2021

Self Cite

In hybrid bioprinting of cartilage tissue constructs, spheroids are used as cellular building blocks and combined with biomaterials for dispensing. However, biomaterial intrinsic cues can deeply affect cell fate and to date, the influence of hydrogel encapsulation on spheroid viability and phenotype has received limited attention. This study assesses this need and unravels 1) how the phenotype of spheroid‐laden constructs can be tuned through adjusting the hydrogel physico–chemical properties and 2) if the spheroid maturation stage prior to encapsulation is a determining factor for the construct phenotype. Articular chondrocyte spheroids with a cartilage specific extracellular matrix (ECM) are generated and different maturation stages, early‐, mid‐, and late‐stage (3, 7, and 14 days, respectively), are harvested and encapsulated in 10, 15, or 20 w/v% methacrylamide‐modified gelatin (gelMA) for 14 days. The encapsulation of immature spheroids do not lead to a cartilage‐like ECM production but when more mature mid‐ or late‐stage spheroids are combined with a certain concentration of gelMA, a fibrocartilage‐like as well as a hyaline cartilage‐like phenotype can be induced. As a proof of concept, late‐stage spheroids are bioprinted using a 10 w/v% gelMA–Irgacure 2959 solution with the aim to test the processing potential of the spheroid‐laden bioink.

“…ASC/HUVEC co‐culture spheroids were generated by using a non‐adherent microwell culture system, as previously described (Berneel, Philips, Declercq, & Cornelissen, 2016; De Moor et al, 2018; Gevaert et al, 2014). In brief, a 3 w/v% ultrapure agarose solution (Life Technologies) dissolved in sterile PBS was heated and poured on top of a negative polydimethylsioloxane (PDMS) customized mould with a diameter of 18 mm and a height of 3 mm.…”

Section: Methodsmentioning

confidence: 99%

High‐throughput fabrication of vascularized adipose microtissues for 3D bioprinting

Benmeridja

Maere

et al. 2020

J Tissue Eng Regen Med

Self Cite

For patients with soft tissue defects, repair with autologous in vitro engineered adipose tissue could be a promising alternative to current surgical therapies. A volumepersistent engineered adipose tissue construct under in vivo conditions can only be achieved by early vascularization after transplantation. The combination of 3D bioprinting technology with self-assembling microvascularized units as building blocks can potentially answer the need for a microvascular network. In the present study, co-culture spheroids combining adipose-derived stem cells (ASC) and human umbilical vein endothelial cells (HUVEC) were created with an ideal geometry for bioprinting. When applying the favourable seeding technique and condition, compact viable spheroids were obtained, demonstrating high adipogenic differentiation and capillary-like network formation after 7 and 14 days of culture, as shown by live/dead analysis, immunohistochemistry and RT-qPCR. Moreover, we were able to successfully 3D bioprint the encapsulated spheroids, resulting in compact viable spheroids presenting capillary-like structures, lipid droplets and spheroid outgrowth after 14 days of culture. This is the first study that generates viable high-throughput (pre-)vascularized adipose microtissues as building blocks for bioprinting applications using a novel ASC/HUVEC co-culture spheroid model, which enables both adipogenic differentiation while simultaneously supporting the formation of prevascular-like structures within engineered tissues in vitro. K E Y W O R D S