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1. Investigation and Characterization of Cell Aggregation During and After Inkjet-Based Bioprinting of Cell-Laden Bioink

   https://doi.org/10.1115/1.4054640  

   Xu, Heqi; Martinez Salazar, Dulce Maria; Shahriar, Md; Xu, Changxue (October 2022, Journal of Manufacturing Science and Engineering)

   Abstract Recently, 3D bioprinting techniques have been broadly recognized as a promising tool to fabricate functional tissues and organs. The bioink used for 3D bioprinting consists of biological materials and cells. Because of the dominant gravitational force, the suspended cells in the bioink sediment resulting in the accumulation and aggregation of cells. This study primarily focuses on the quantification of cell sedimentation-induced cell aggregation during and after inkjet-based bioprinting. The major conclusions are summarized as follows: (1) as the printing time increases from 0 min to 60 min, the percentage of the cells forming cell aggregates at the bottom of the bioink reservoir increases significantly from 3.6% to 54.5%, indicating a severe cell aggregation challenge in 3D bioprinting, (2) during inkjet-based bioprinting, at the printing time of only 15 min, more than 80% of the cells within the nozzle have formed cell aggregates. Both the individual cells and cell aggregates tend to migrate to the vicinity of the nozzle centerline mainly due to the weak shear-thinning properties of the bioink, and (3) after the bioprinting process, the mean cell number per microsphere increases significantly from 0.38 to 1.05 as printing time increases from 0 min to 15 min. The maximum number of cells encapsulated within one microsphere is ten, and 29.8% of the microspheres with cells encapsulated have contained small or large cell aggregates at the printing time of 15 min. 

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2. Laser-based bioprinting for multilayer cell patterning in tissue engineering and cancer research

   https://doi.org/10.1042/EBC20200093  

   Yang, Haowei; Yang, Kai-Hung; Narayan, Roger J.; Ma, Shaohua (August 2021, Essays in Biochemistry)

   Jang, Jinah (Ed.)

   Abstract 3D printing, or additive manufacturing, is a process for patterning functional materials based on the digital 3D model. A bioink that contains cells, growth factors, and biomaterials are utilized for assisting cells to develop into tissues and organs. As a promising technique in regenerative medicine, many kinds of bioprinting platforms have been utilized, including extrusion-based bioprinting, inkjet bioprinting, and laser-based bioprinting. Laser-based bioprinting, a kind of bioprinting technology using the laser as the energy source, has advantages over other methods. Compared with inkjet bioprinting and extrusion-based bioprinting, laser-based bioprinting is nozzle-free, which makes it a valid tool that can adapt to the viscosity of the bioink; the cell viability is also improved because of elimination of nozzle, which could cause cell damage when the bioinks flow through a nozzle. Accurate tuning of the laser source and bioink may provide a higher resolution for reconstruction of tissue that may be transplanted used as an in vitro disease model. Here, we introduce the mechanism of this technology and the essential factors in the process of laser-based bioprinting. Then, the most potential applications are listed, including tissue engineering and cancer models. Finally, we present the challenges and opportunities faced by laser-based bioprinting. 

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3. Cell-laden bioink circulation-assisted inkjet-based bioprinting to mitigate cell sedimentation and aggregation

   https://doi.org/10.1088/1758-5090/ac8fb7  

   Liu, Jiachen; Shahriar, Md; Xu, Heqi; Xu, Changxue (October 2022, Biofabrication)

   Abstract Three-dimensional (3D) bioprinting precisely deposits picolitre bioink to fabricate functional tissues and organs in a layer-by-layer manner. The bioink used for 3D bioprinting incorporates living cells. During printing, cells suspended in the bioink sediment to form cell aggregates through cell-cell interaction. The formation of cell aggregates due to cell sedimentation have been widely recognized as a significant challenge to affect the printing reliability and quality. This study has incorporated the active circulation into the bioink reservoir to mitigate cell sedimentation and aggregation. Force and velocity analysis were performed, and a circulation model has been proposed based on iteration algorithm with the time step for each divided region. It has been found that (a) the comparison of the cell sedimentation and aggregation with and without the active bioink circulation has demonstrated high effectiveness of active circulation to mitigate cell sedimentation and aggregation for the bioink with both a low cell concentration of 1 × 10⁶cells ml⁻¹and a high cell concentration of 5 × 10⁶cells ml⁻¹; and (b) the effect of circulation flow rate on cell sedimentation and aggregation has been investigated, showing that large flow rate results in slow increments in effectiveness. Besides, the predicted mitigation effectiveness percentages on cell sedimentation by the circulation model generally agrees well with the experimental results. In addition, the cell viability assessment at the recommended maximum flow rate of 0.5 ml min⁻¹has demonstrated negligible cell damage due to the circulation. The proposed active circulation approach is an effective and efficient approach with superior performance in mitigating cell sedimentation and aggregation, and the resulting knowledge is easily applicable to other 3D bioprinting techniques significantly improving printing reliability and quality in 3D bioprinting. 

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4. Rapid Volumetric Bioprinting of Decellularized Extracellular Matrix Bioinks

   https://doi.org/10.1002/adma.202304846  

   Lian, Liming; Xie, Maobin; Luo, Zeyu; Zhang, Zhenrui; Maharjan, Sushila; Mu, Xuan; Garciamendez‐Mijares, Carlos_Ezio; Kuang, Xiao; Sahoo, Jugal_Kishore; Tang, Guosheng; et al (March 2024, Advanced Materials)

   Abstract Decellularized extracellular matrix (dECM)‐based hydrogels are widely applied to additive biomanufacturing strategies for relevant applications. The extracellular matrix components and growth factors of dECM play crucial roles in cell adhesion, growth, and differentiation. However, the generally poor mechanical properties and printability have remained as major limitations for dECM‐based materials. In this study, heart‐derived dECM (h‐dECM) and meniscus‐derived dECM (Ms‐dECM) bioinks in their pristine, unmodified state supplemented with the photoinitiator system of tris(2,2‐bipyridyl) dichlororuthenium(II) hexahydrate and sodium persulfate, demonstrate cytocompatibility with volumetric bioprinting processes. This recently developed bioprinting modality illuminates a dynamically evolving light pattern into a rotating volume of the bioink, and thus decouples the requirement of mechanical strengths of bioprinted hydrogel constructs with printability, allowing for the fabrication of sophisticated shapes and architectures with low‐concentration dECM materials that set within tens of seconds. As exemplary applications, cardiac tissues are volumetrically bioprinted using the cardiomyocyte‐laden h‐dECM bioink showing favorable cell proliferation, expansion, spreading, biomarker expressions, and synchronized contractions; whereas the volumetrically bioprinted Ms‐dECM meniscus structures embedded with human mesenchymal stem cells present appropriate chondrogenic differentiation outcomes. This study supplies expanded bioink libraries for volumetric bioprinting and broadens utilities of dECM toward tissue engineering and regenerative medicine. 

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5. Characterizing the Process Physics of Ultrasound-Assisted Bioprinting

   https://doi.org/10.1038/s41598-019-50449-w  

   Chansoria, Parth; Shirwaiker, Rohan (September 2019, Scientific Reports)

   Abstract 3D bioprinting has been evolving as an important strategy for the fabrication of engineered tissues for clinical, diagnostic, and research applications. A major advantage of bioprinting is the ability to recapitulate the patient-specific tissue macro-architecture using cellular bioinks. The effectiveness of bioprinting can be significantly enhanced by incorporating the ability to preferentially organize cellular constituents within 3D constructs to mimic the intrinsic micro-architectural characteristics of native tissues. Accordingly, this work focuses on a new non-contact and label-free approach called ultrasound-assisted bioprinting (UAB) that utilizes acoustophoresis principle to align cells within bioprinted constructs. We describe the underlying process physics and develop and validate computational models to determine the effects of ultrasound process parameters (excitation mode, excitation time, frequency, voltage amplitude) on the relevant temperature, pressure distribution, and alignment time characteristics. Using knowledge from the computational models, we experimentally investigate the effect of selected process parameters (frequency, voltage amplitude) on the critical quality attributes (cellular strand width, inter-strand spacing, and viability) of MG63 cells in alginate as a model bioink system. Finally, we demonstrate the UAB of bilayered constructs with parallel (0°–0°) and orthogonal (0°–90°) cellular alignment across layers. Results of this work highlight the key interplay between the UAB process design and characteristics of aligned cellular constructs, and represent an important next step in our ability to create biomimetic engineered tissues. 

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