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1. Cell-Laden Composite Hydrogel Bioinks with Human Bone Allograft Particles to Enhance Stem Cell Osteogenesis

   https://doi.org/10.3390/polym14183788  

   Gharacheh, Hadis; Guvendiren, Murat (September 2022, Polymers)

   There is a growing demand for bone graft substitutes that mimic the extracellular matrix properties of the native bone tissue to enhance stem cell osteogenesis. Composite hydrogels containing human bone allograft particles are particularly interesting due to inherent bioactivity of the allograft tissue. Here, we report a novel photocurable composite hydrogel bioink for bone tissue engineering. Our composite bioink is formulated by incorporating human allograft bone particles in a methacrylated alginate formulation to enhance adult human mesenchymal stem cell (hMSC) osteogenesis. Detailed rheology and printability studies confirm suitability of our composite bioinks for extrusion-based 3D bioprinting technology. In vitro studies reveal high cell viability (~90%) for hMSCs up to 28 days of culture within 3D bioprinted composite scaffolds. When cultured within bioprinted composite scaffolds, hMSCs show significantly enhanced osteogenic differentiation as compared to neat scaffolds based on alkaline phosphatase activity, calcium deposition, and osteocalcin expression. 

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2. 3D Bioprinting of Cell‐Laden Hydrogels for Improved Biological Functionality

   https://doi.org/10.1002/adma.202103691  

   Hull, Sarah M.; Brunel, Lucia G.; Heilshorn, Sarah C. (October 2021, Advanced Materials)

   null (Ed.)

   The encapsulation of cells within gel-phase materials to form bioinks offers distinct advantages for next-generation 3D bioprinting. 3D bioprinting has emerged as a promising tool for patterning cells, but the technology remains limited in its ability to produce biofunctional, tissue-like constructs due to a dearth of materials suitable for bioinks. While early demonstrations commonly used viscous polymers optimized for printability, these materials often lacked cell compatibility and biological functionality. In response, advanced materials that exist in the gel phase during the entire printing process are being developed, since hydrogels are uniquely positioned to both protect cells during extrusion and provide biological signals to embedded cells as the construct matures during culture. Here, an overview of the design considerations for gel-phase materials as bioinks is presented, with a focus on their mechanical, biochemical, and dynamic gel properties. Current challenges and opportunities that arise due to the fact that bioprinted constructs are active, living hydrogels composed of both acellular and cellular components are also evaluated. Engineering hydrogels with consideration of cells as an intrinsic component of the printed bioink will enable control over the evolution of the living construct after printing to achieve greater biofunctionality. 

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3. Single‐Particle Tracking Microelectrophoresis Analysis of Charge and Cargo Loading on Gene Delivery Microbubbles

   https://doi.org/10.1002/ppsc.202400187  

   Huynh, Katherine T; Armstrong, Randall; Speese, Sean; Schutt, Carolyn E (April 2025, Particle & Particle Systems Characterization)

   Abstract Lipid‐coated microbubbles are an important class of gene delivery vehicles activated by ultrasound to locally deliver their DNA payloads to cells. Negatively charged DNA is electrostatically loaded onto the positively charged surface of microbubbles that contain a cationic lipid shell. Characterizing the zeta potential of individual cationic microbubbles to determine a population distribution and how this is affected by DNA complexation is critical to maximize DNA loading and circulation time. Traditional zeta potential analysis provides an ensemble charge measurement for a particle population but cannot measure individual particles to determine a distribution. Here, single‐particle tracking microelectrophoresis technology is applied to measure zeta potentials of individual microbubbles synthesized with different ratios of 1,2‐distearoyl‐3‐trimethylammonium‐propane (DSTAP) cationic lipid as well as loaded with increasing amounts of DNA. Results show that at 0 mol% DSTAP all microbubbles are negatively charged, and at 10 mol% half are positive. All particles are positive at 20 mol% DSTAP but the population shifts to negative values upon incubation with 0.01 pg DNA/microbubble. Analyzing zeta potential on the individual microbubble level is a powerful tool to understand DNA loading across a population of microbubbles and enables microbubble surface charge and nucleic acid loading optimization for delivery applications. 

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4. Sheet-based extrusion bioprinting: a new multi-material paradigm providing mid-extrusion micropatterning control for microvascular applications

   https://doi.org/10.1088/1758-5090/ad30c8  

   Hooper, Ryan; Cummings, Caleb; Beck, Anna; Vazquez-Armendariz, Javier; Rodriguez, Ciro; Dean, David (March 2024, Biofabrication)

   Abstract As bioprinting advances into clinical relevance with patient-specific tissue and organ constructs, it must be capable of multi-material fabrication at high resolutions to accurately mimick the complex tissue structures found in the body. One of the most fundamental structures to regenerative medicine is microvasculature. Its continuous hierarchical branching vessel networks bridge surgically manipulatable arteries (∼1–6 mm) to capillary beds (∼10µm). Microvascular perfusion must be established quickly for autologous, allogeneic, or tissue engineered grafts to survive implantation and heal in place. However, traditional syringe-based bioprinting techniques have struggled to produce perfusable constructs with hierarchical branching at the resolution of the arterioles (∼100-10µm) found in microvascular tissues. This study introduces the novel CEVIC bioprinting device (i.e.ContinuouslyExtrudedVariableInternalChanneling), a multi-material technology that breaks the current extrusion-based bioprinting paradigm of pushing cell-laden hydrogels through a nozzle as filaments, instead, in the version explored here, extruding thin, wide cell-laden hydrogel sheets. The CEVIC device adapts the chaotic printing approach to control the width and number of microchannels within the construct as it is extruded (i.e. on-the-fly). Utilizing novel flow valve designs, this strategy can produce continuous gradients varying geometry and materials across the construct and hierarchical branching channels with average widths ranging from 621.5 ± 42.92%µm to 11.67 ± 14.99%µm, respectively, encompassing the resolution range of microvascular vessels. These constructs can also include fugitive/sacrificial ink that vacates to leave demonstrably perfusable channels. In a proof-of-concept experiment, a co-culture of two microvascular cell types, endothelial cells and pericytes, sustained over 90% viability throughout 1 week in microchannels within CEVIC-produced gelatin methacryloyl-sodium alginate hydrogel constructs. These results justify further exploration of generating CEVIC-bioprinted microvasculature, such as pre-culturing and implantation studies. 

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5. Extrusion‐Based 3D Bioprinting of Adhesive Tissue Engineering Scaffolds Using Hybrid Functionalized Hydrogel Bioinks

   https://doi.org/10.1002/adbi.202300124  

   Chen, Shuai; Tomov, Martin L.; Ning, Liqun; Gil, Carmen J.; Hwang, Boeun; Bauser‐Heaton, Holly; Chen, Haifeng; Serpooshan, Vahid (July 2023, Advanced Biology)

   Abstract Adhesive tissue engineering scaffolds (ATESs) have emerged as an innovative alternative means, replacing sutures and bioglues, to secure the implants onto target tissues. Relying on their intrinsic tissue adhesion characteristics, ATES systems enable minimally invasive delivery of various scaffolds. This study investigates development of the first class of 3D bioprinted ATES constructs using functionalized hydrogel bioinks. Two ATES delivery strategies, in situ printing onto the adherend versus printing and then transferring to the target surface, are tested using two bioprinting methods, embedded versus air printing. Dopamine‐modified methacrylated hyaluronic acid (HAMA‐Dopa) and gelatin methacrylate (GelMA) are used as the main bioink components, enabling fabrication of scaffolds with enhanced adhesion and crosslinking properties. Results demonstrate that dopamine modification improved adhesive properties of the HAMA‐Dopa/GelMA constructs under various loading conditions, while maintaining their structural fidelity, stability, mechanical properties, and biocompatibility. While directly printing onto the adherend yields superior adhesive strength, embedded printing followed by transfer to the target tissue demonstrates greater potential for translational applications. Together, these results demonstrate the potential of bioprinted ATESs as off‐the‐shelf medical devices for diverse biomedical applications. 

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