Three-Dimensional Acoustic Assembly Device for Mass Manufacturing of Cell Spheroids.

Cell spheroids are promising three-dimensional (3D) models that have gained wide applications in many biological fields. This protocol presents a method for manufacturing high-quality and high-throughput cell spheroids using a 3D acoustic assembly device through maneuverable procedures. The acoustic assembly device consists of three lead zirconate titanate (PZT) transducers, each arranged in the X/Y/Z plane of a square polymethyl methacrylate (PMMA) chamber. This configuration enables the generation of a 3D dot-array pattern of levitated acoustic nodes (LANs) when three signals are applied. As a result, cells in the gelatin methacryloyl (GelMA) solution can be driven to the LANs, forming uniform cell aggregates in three dimensions. The GelMA solution is then UV-photocured and crosslinked to serve as a scaffold that supports the growth of cell aggregates. Finally, masses of matured spheroids are obtained and retrieved by subsequently dissolving the GelMA scaffolds under mild conditions. The proposed new 3D acoustic cell assembly device will enable the scale-up fabrication of cell spheroids, and even organoids, offering great potential technology in the biological field.

High-throughput fabrication of cell spheroids with 3D acoustic assembly devices.

Acoustic cell assembly devices are applied in cell spheroid fabrication attributed to their rapid, label-free and low-cell damage production of size-uniform spheroids. However, the spheroids yield and production efficiency are still insufficient to meet the requirements of several biomedical applications, especially those that require large quantities of cell spheroids, such as high-throughput screening, macro-scale tissue fabrication, and tissue repair. Here, we developed a novel 3D acoustic cell assembly device combined with a gelatin methacrylamide (GelMA) hydrogels for the high-throughput fabrication of cell spheroids. The acoustic device employs three orthogonal piezoelectric transducers that can generate three orthogonal standing bulk acoustic waves to create a 3D dot-array (25 × 25 × 22) of levitated acoustic nodes, enabling large-scale fabrication of cell aggregates (>13,000 per operation). The GelMA hydrogel serves as a supporting scaffold to preserve the structure of cell aggregates after the withdrawal of acoustic fields. As a result, mostly cell aggregates (>90%) mature into spheroids maintaining good cell viability. We further applied these acoustically assembled spheroids to drug testing to explore their potency in drug response. In conclusion, this 3D acoustic cell assembly device may pave the way for the scale-up fabrication of cell spheroids or even organoids, to enable flexible application in various biomedical applications, such as high-throughput screening, disease modeling, tissue engineering, and regenerative medicine.

Self-assembly and morphological transitions of random amphiphilic poly(ß-D-glucose-co-1-octyl) phosphazenes.

The amphiphilic random copolymer poly(ß-d-glucose-co-1-octyl)phosphazene (PGOP) can undergo continuous morphological transitions in DMF-water mixed solvents. In this study, the ratio of glucose moieties to octyl moieties was controlled via a two-step thiol-ene reaction. As a result, polyphosphazenes with glycosyl functionalization degrees of 58.1% (PGOP-1), 74.1% (PGOP-2) and 87.0% (PGOP-3) were obtained. These amphiphilic polyphosphazenes self-assemble in both water and water-DMF mixtures. Several self-assembled morphologies including spheres, rods and vesicles were formed though careful control of the water content (WC) in the DMF solvent as well as of the hydrophilicity or hydrophobicity of the copolymers. We also found that an increase in the hydrophobic proportion led to faster morphological transitions at a constant WC. The thermodynamics of micellization were also studied by Isothermal Titration Calorimetry (ITC), and the strong hydrophobic interactions in PGOP-1 were demonstrated by their highly exothermic nature. These self-assemblies have potential applications in biosensing, lectin adsorption and drug loading with controlled release.

Preparation of polyphosphazene hydrogels for enzyme immobilization.

We report on the synthesis and application of a new hydrogel based on a methacrylate substituted polyphosphazene. Through ring-opening polymerization and nucleophilic substitution, poly[bis(methacrylate)phosphazene] (PBMAP) was successfully synthesized from hexachlorocyclotriphosphazene. By adding PBMAP to methacrylic acid solution and then treating with UV light, we could obtain a cross-linked polyphosphazene network, which showed an ultra-high absorbency for distilled water. Lipase from Candida rugosa was used as the model lipase for entrapment immobilization in the hydrogel. The influence of methacrylic acid concentration on immobilization efficiency was studied. Results showed that enzyme loading reached a maximum of 24.02 mg/g with an activity retention of 67.25% when the methacrylic acid concentration was 20% (w/w).

Linkage analysis of a region on chromosome 2 with essential hypertension in Chinese families.

OBJECTIVE: To verify the linkage of the candidate regions identified in a previous study (markers D2S168, D2S151, D2S142 on chromosome 2) with hypertension in Chinese families. METHODS: A genetic linkage study focused on chromosome 2 was performed on 240 Chinese families containing 856 patients with essential hypertension. A total of 1080 individuals were genotyped using 9 highly polymorphic microsatellite markers around the candidate regions on chromosome 2 with an average spacing of 5 cM. Non-parametric linkage (NPL), parametric linkage analysis and transmission-disequilibrium test (TDT) with the GENEHUNTER software were used to assess evidence for linkage. RESULTS: Linkage of a region on chromosome 2 around D2S151 and D2S142 with hypertension was confirmed by different statistical methods (NPL, LOD score and TDT). However, the linkage of D2S168 could not be replicated in this extension study. CONCLUSIONS: The data suggest that a region on chromosome 2 at or near the loci of D2S142 and D2S151 may harbor genes responsible for the development of essential hypertension in Chinese.