Your search keyword '"Bhuiyan DB"' showing total 6 results

1. Real-time assessment of cell concentration and viability onboard a syringe using dielectric impedance spectroscopy for extrusion bioprinting.

Author

Matavosian AA, Griffin AC, Bhuiyan DB, Lyness AM, Bhatnagar V, and Bonassar L

Abstract

Bioprinting produces personalized, cell-laden constructs for tissue regeneration through the additive layering of bio-ink, an injectable hydrogel infused with cells. Currently, bioprinted constructs are assessed for quality by measuring cellular properties post-production using destructive techniques, necessitating the creation of multiple constructs and increasing the production costs of bioprinting. To reduce this burden, cell properties in bio-ink can be measured in real-time during printing. We incorporated DIS onto a syringe for real-time measurement of primary chondrocytes suspended in phosphate buffered saline (PBS) using impedance ( |Z| ) and phase angle ( θ ) from 0.1 - 25,000 kHz. Cell concentration and viability ranged from 0.1×10 6 cells/mL - 125×10 6 cells/mL and from 0%-94%, respectively. Samples with constant or with changing cell concentration were exposed to various flow conditions from 0.5 - 4 mL/min. The background PBS signal was subtracted from the sample, providing insight into the dielectric properties of the cells, labelled as |Z cells | and θ cells . |Z cells | shared a linear correlation with cell concentration and viability. Flow rate had minimal impact on our results, and |Z cells | responded as cell concentration was altered. Notably, sensitivity to these cellular properties was dependent on frequency and was highest for |Z cells | when θ cells was minimized. Cell concentration and viability showed an additive effect on |Z cells | that was modeled across multiple frequencies, and deconvolution of these signals could result in real-time predictions of cell properties in the future. Overall, DIS was found to be a suitable technique for real-time sensing of cell concentration and viability during bioprinting.&#xD., (Creative Commons Attribution license.)

Published

2025

2. In Situ Expansion, Differentiation, and Electromechanical Coupling of Human Cardiac Muscle in a 3D Bioprinted, Chambered Organoid.

Author

Kupfer ME, Lin WH, Ravikumar V, Qiu K, Wang L, Gao L, Bhuiyan DB, Lenz M, Ai J, Mahutga RR, Townsend D, Zhang J, McAlpine MC, Tolkacheva EG, and Ogle BM

Subjects

Action Potentials, Cell Proliferation, Cells, Cultured, Extracellular Matrix Proteins metabolism, Humans, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells metabolism, Induced Pluripotent Stem Cells physiology, Myocardial Contraction, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, Organoids cytology, Organoids metabolism, Bioprinting methods, Cell Differentiation, Myocytes, Cardiac physiology, Organoids physiology, Tissue Engineering methods

Abstract

Rationale: One goal of cardiac tissue engineering is the generation of a living, human pump in vitro that could replace animal models and eventually serve as an in vivo therapeutic. Models that replicate the geometrically complex structure of the heart, harboring chambers and large vessels with soft biomaterials, can be achieved using 3-dimensional bioprinting. Yet, inclusion of contiguous, living muscle to support pump function has not been achieved. This is largely due to the challenge of attaining high densities of cardiomyocytes-a notoriously nonproliferative cell type. An alternative strategy is to print with human induced pluripotent stem cells, which can proliferate to high densities and fill tissue spaces, and subsequently differentiate them into cardiomyocytes in situ., Objective: To develop a bioink capable of promoting human induced pluripotent stem cell proliferation and cardiomyocyte differentiation to 3-dimensionally print electromechanically functional, chambered organoids composed of contiguous cardiac muscle., Methods and Results: We optimized a photo-crosslinkable formulation of native ECM (extracellular matrix) proteins and used this bioink to 3-dimensionally print human induced pluripotent stem cell-laden structures with 2 chambers and a vessel inlet and outlet. After human induced pluripotent stem cells proliferated to a sufficient density, we differentiated the cells within the structure and demonstrated function of the resultant human chambered muscle pump. Human chambered muscle pumps demonstrated macroscale beating and continuous action potential propagation with responsiveness to drugs and pacing. The connected chambers allowed for perfusion and enabled replication of pressure/volume relationships fundamental to the study of heart function and remodeling with health and disease., Conclusions: This advance represents a critical step toward generating macroscale tissues, akin to aggregate-based organoids, but with the critical advantage of harboring geometric structures essential to the pump function of cardiac muscle. Looking forward, human chambered organoids of this type might also serve as a test bed for cardiac medical devices and eventually lead to therapeutic tissue grafting.

Published

2020

3. 3D Printed Organ Models with Physical Properties of Tissue and Integrated Sensors.

Author

Qiu K, Zhao Z, Haghiashtiani G, Guo SZ, He M, Su R, Zhu Z, Bhuiyan DB, Murugan P, Meng F, Park SH, Chu CC, Ogle BM, Saltzman DA, Konety BR, Sweet RM, and McAlpine MC

Abstract

The design and development of novel methodologies and customized materials to fabricate patient-specific 3D printed organ models with integrated sensing capabilities could yield advances in smart surgical aids for preoperative planning and rehearsal. Here, we demonstrate 3D printed prostate models with physical properties of tissue and integrated soft electronic sensors using custom-formulated polymeric inks. The models show high quantitative fidelity in static and dynamic mechanical properties, optical characteristics, and anatomical geometries to patient tissues and organs. The models offer tissue-mimicking tactile sensation and behavior and thus can be used for the prediction of organ physical behavior under deformation. The prediction results show good agreement with values obtained from simulations. The models also allow the application of surgical and diagnostic tools to their surface and inner channels. Finally, via the conformal integration of 3D printed soft electronic sensors, pressure applied to the models with surgical tools can be quantitatively measured., Competing Interests: Competing financial interests The authors declare no competing financial interests.

Published

2018

4. Bone regeneration from human mesenchymal stem cells on porous hydroxyapatite-PLGA-collagen bioactive polymer scaffolds.

Author

Bhuiyan DB, Middleton JC, Tannenbaum R, and Wick TM

Subjects

Bone Regeneration, Bone Substitutes chemistry, Cell Line, Cell Proliferation, Humans, Mesenchymal Stem Cell Transplantation, Polylactic Acid-Polyglycolic Acid Copolymer, Porosity, Tissue Engineering, Collagen chemistry, Durapatite chemistry, Lactic Acid chemistry, Mesenchymal Stem Cells cytology, Osteogenesis, Polyglycolic Acid chemistry, Tissue Scaffolds chemistry

Abstract

We have developed a novel multicomponent nano-hydroxyapatite-poly(D,L-lactide-co-glycolide)-collagen biomaterial (nHAP-PLGA-collagen) with mechanical properties similar to human cancellous bone. To demonstrate the bone forming capacity of nHAP-PLGA-collagen prior to in vivo experiments, nHAP-PLGA-collagen films and 3D porous scaffolds were seeded with human mesenchymal stem cells (hMSCs) to characterize cell proliferation and osteogenic differentiation. Over 21 days hMSCs seeded on 2D nHAP-PLGA-collagen films proliferate, form nodules, deposit mineral and express high alkaline phosphatase activity (ALP) indicating commitment of hMSCs towards osteogenic lineage. When seeded in 3D scaffolds, hMSCs migrate throughout the connected porous network of the nHAP-PLGA-collagen scaffold and proliferate to fill the scaffold voids. Over 35 days, cells express ALP, osteocalcin and deposit minerals with kinetics similar to osteogenesis in vivo. Adipogenic or chondrogenic differentiation is not detected in 3D constructs, indicating that in an osteogenic environment the presence of bone ECM specific molecules in nHAP-PLGA-collagen scaffolds support homogeneous bone tissue development. This ability of nHAP-PLGA-collagen matrices to provide biochemical stimulation to support osteogenesis from stem cells along with its high mechanical strength suggests that nHAP-PLGA-collagen is a suitable biomaterial for bone regeneration. This platform technology of covalently attaching ECM proteins and molecules with synthetic and natural polymers to adjust material properties and biochemical signaling has a potential for a wider range of applications in tissue engineering and regenerative medicine.

Published

2017

5. Solid organ fabrication: comparison of decellularization to 3D bioprinting.

Author

Jung JP, Bhuiyan DB, and Ogle BM

Abstract

Solid organ fabrication is an ultimate goal of Regenerative Medicine. Since the introduction of Tissue Engineering in 1993, functional biomaterials, stem cells, tunable microenvironments, and high-resolution imaging technologies have significantly advanced efforts to regenerate in vitro culture or tissue platforms. Relatively simple flat or tubular organs are already in (pre)clinical trials and a few commercial products are in market. The road to more complex, high demand, solid organs including heart, kidney and lung will require substantive technical advancement. Here, we consider two emerging technologies for solid organ fabrication. One is decellularization of cadaveric organs followed by repopulation with terminally differentiated or progenitor cells. The other is 3D bioprinting to deposit cell-laden bio-inks to attain complex tissue architecture. We reviewed the development and evolution of the two technologies and evaluated relative strengths needed to produce solid organs, with special emphasis on the heart and other tissues of the cardiovascular system.

Published

2016

6. Mechanical properties and osteogenic potential of hydroxyapatite-PLGA-collagen biomaterial for bone regeneration.

Author

Bhuiyan DB, Middleton JC, Tannenbaum R, and Wick TM

Subjects

Bone and Bones, Cell Adhesion, Cell Differentiation, Cell Survival, Humans, Mechanical Phenomena, Mesenchymal Stem Cells cytology, Polylactic Acid-Polyglycolic Acid Copolymer, Tissue Engineering, Tissue Scaffolds chemistry, Biocompatible Materials chemistry, Bone Regeneration physiology, Collagen chemistry, Durapatite chemistry, Lactic Acid chemistry, Osteogenesis, Polyglycolic Acid chemistry

Abstract

A bone graft is a complicated structure that provides mechanical support and biological signals that regulate bone growth, reconstruction, and repair. A single-component material is inadequate to provide a suitable combination of structural support and biological stimuli to promote bone regeneration. Multicomponent composite biomaterials lack adequate bonding among the components to prevent phase separation after implantation. We have previously developed a novel multistep polymerization and fabrication process to construct a nano-hydroxyapatite-poly(D,L-lactide-co-glycolide)-collagen biomaterial (abbreviated nHAP-PLGA-collagen) with the components covalently bonded to each other. In the present study, the mechanical properties and osteogenic potential of nHAP-PLGA-collagen are characterized to assess the material's suitability to support bone regeneration. nHAP-PLGA-collagen films exhibit tensile strength very close to that of human cancellous bone. Human mesenchymal stem cells (hMSCs) are viable on 2D nHAP-PLGA-collagen films with a sevenfold increase in cell population after 7 days of culture. Over 5 weeks of culture, hMSCs deposit matrix and mineral consistent with osteogenic differentiation and bone formation. As a result of matrix deposition, nHAP-PLGA-collagen films cultured with hMSCs exhibit 48% higher tensile strength and fivefold higher moduli compared to nHAP-PLGA-collagen films without cells. More interestingly, secretion of matrix and minerals by differentiated hMSCs cultured on the nHAP-PLGA-collagen films for 5 weeks mitigates the loss of mechanical strength that accompanies PLGA hydrolysis.

Published

2016