3D Bioprinted Scaffolds Research Articles

Low-intensity pulsed ultrasound promotes cell viability of hUSCs in volumetric bioprinting scaffolds via PI3K/Akt and ERK1/2 pathways.


The study aimed to investigate the impact of low-intensity pulsed ultrasound (LIPUS) on human urinary-derived stem cells (hUSCs) viability within 3D cell-laden gelatin methacryloyl (GelMA) scaffolds.
Methods:
hUSCs were integrated into GelMA bio-inks at concentrations ranging from 2.5% to 10% (w/v) and then bioprinted using a volumetic-based method. Subsequent exposure of these scaffolds to LIPUS under varying parameters or sham irradiation aimed at optimizing the LIPUS treatment. Assessment of hUSCs viability employed Cell Counting Kit-8 (CCK8), cell cycle analysis, and live&dead cell double staining assays. Additionally, Western blot analysis was conducted to determine protein expression levels.
Result:
With 3D bio-printed cell-laden GelMA scaffolds successfully constructed, LIPUS promoted the proliferation of hUSCs. Optimal LIPUS conditions, as determined through CCK8 and live&dead cell double staining assays, was achieved at a frequency of 1.5 MHz, a spatial-average temporal-average intensity (ISATA) of 150 mW/cm2, with an exposure duration of 10 minutes per session administered consecutively for two sessions. LIPUS facilitated the transition from G0/G1 phase to S and G2/M phases and enhanced the phosphorylation of ERK1/2 and PI3K-Akt. Inhibition of ERK1/2 (U0126) and PI3K (LY294002) significantly attenuated LIPUS-induced phosphorylation of ERK1/2 and PI3K-Akt respectively, both of which decreased the hUSC viability within 3D bio-printed GelMA scaffolds.
Conclusion:
Applying a LIPUS treatment at an ISATA of 150 mW/cm2 promotes the growth of hUSCs within 3D bio-printed GelMA scaffolds through modulating ERK1/2 and PI3K-Akt signaling pathways.&#xD.

Three-Dimensional Bioprinting of Tarsal Plates with Adipose-Derived Mesenchymal Stem Cells: Evaluation of Meibomian Gland Reconstruction in a Rat Model

Background: The aim of this study was to develop 3D-bioprinted scaffolds embedded with human adipose-derived stem cells (hADSCs) to reconstruct the tarsal plate in a rat model. Methods: Scaffolds were printed using a 3D bioprinter with a bioink composed of atelocollagen and alginate. hADSCs (5 × 105 cells/mL) were embedded within the bioink. A total of 30 male Sprague Dawley (SD) rats (300 g) were divided into three groups: group 1 (normal control, n = 10), group 2 (3D-bioprinted scaffolds, n = 10), and group 3 (3D-bioprinted scaffolds with hADSCs, n = 10). Four weeks after surgery, a histopathological analysis was performed using hematoxylin and eosin (H&E) staining, Masson’s trichrome (MT) staining, and immunofluorescence staining. Gene expression of SREBP-1, PPAR-γ, FADS-2, and FAS was assessed via real-time polymerase chain reaction (PCR). Results: No abnormalities were observed in the operated eyelids of any of the 30 rats. The histopathological analysis revealed lipid-secreting cells resembling meibocytes in both group 2 and group 3, with more pronounced meibocyte-like cells in group 3. Immunofluorescence staining for phalloidin expression showed a significant increase in group 3. Additionally, the RNA expression of SREBP-1, PPAR-γ, FADS-2, and FAS, all related to lipid metabolism, was elevated in group 3. Conclusions: The 3D-printed scaffolds combined with hADSCs were effective for tarsal plate reconstruction, with the hADSCs notably contributing to the generation of cells associated with lipid metabolism.

Hydrogel composition and mechanical stiffness of 3D bioprinted cell-loaded scaffolds promote cartilage regeneration

ObjectiveTo investigate the impact of different component ratios and mechanical stiffness of the gelatin-sodium alginate composite hydrogel scaffold, fabricated through 3D bioprinting, on the viability and functionality of chondrocytes.MethodsThree different concentrations of hydrogel, designated as low, medium, and high, were prepared. The rheological properties of the hydrogel were characterized to optimize printing parameters. Subsequently, the printability and shape fidelity of the cell-loaded hydrogel scaffolds were statistically evaluated, and the chondrocyte viability was observed. Dynamic mechanical analysis was conducted to measure the modulus, thereby assessing the scaffold’s stiffness. Following a 21-day culture period, RT-PCR, histological staining, and immunostaining were employed to assess chondrocyte activity, chondrosphere aggregates formation, and cartilage matrix production.ResultsBased on rheological analysis, optimal printing temperatures for each group were determined as 27.8°C, 28.5°C, and 30°C. The optimized printing parameters could ensure the molding effect of the scaffolds on the day of printing, with the actual grid area of the scaffolds was close to the theoretical grid area. And the scaffolds exhibited good cell viability (93.24% ± 0.99%, 92.04% ± 1.49%, and 88.46% ± 1.53%). After 7 days of culture, the medium and high concentration groups showed no significant change in grid area compared to the day of printing (p > 0.05), indicating good morphological fidelity. As the hydrogel’s bicomponent ratio increased, both the storage modulus and loss modulus increased, while the loss factor remained relatively constant. The highest number of chondrocytes-formed chondrosphere aggregates in the medium concentration group was observed by light microscopy. RT-PCR results indicated significantly higher expression levels of chondrogenic genes SOX9, Agg, and Col-II in the low and medium concentration groups compared to the high concentration group (p < 0.05). Histological staining results showed that the middle concentration group formed the highest number of typical cartilage lacunae.ConclusionThe aforementioned results indicate that in 3D bioprinted cell-loaded GA-SA composite hydrogel scaffolds, the scaffolds with the composition ratio (10:3) and mechanical stiffness (∼155 kPa) exhibit sustained morphological fidelity, effectively preserve the hyaline phenotype of chondrocytes, and are more conducive to cartilage regeneration.

Evaluation of 3D bioprinted skin scaffolds in mice along with gold nanoparticles exposure

Evaluation of 3D bioprinted skin scaffolds in mice along with gold nanoparticles exposure

Unleashing innovation: 3D-printed biomaterials in bone tissue engineering for repairing femur and tibial defects in animal models - a systematic review and meta-analysis.

3D-printed scaffolds have emerged as an alternative for addressing the current limitations encountered in bone reconstruction. This study aimed to systematically review the feasibility of using 3D bio-printed scaffolds as a material for bone grafting in animal models, focusing on femoral and tibial defects. The primary objective of this study was to evaluate the efficacy, safety, and overall impact of these scaffolds on bone regeneration. Electronic databases were searched using specific search terms from January 2013 to October 2023, and 37 relevant studies were finally included and reviewed. We documented the type of scaffold generated using the 3D printed techniques, detailing its characterization and rheological properties including porosity, compressive strength, shrinkage, elastic modulus, and other relevant factors. Before incorporating them into the meta-analysis, an additional inclusion criterion was applied where the regenerated bone area (BA), bone volume (BV), bone volume per total volume (BV/TV), trabecular thickness (Tb. Th.), trabecular number (Tb. N.), and trabecular separation (Tb. S.) were collected and analyzed statistically. 3D bio-printed ceramic-based composite scaffolds exhibited the highest capacity for bone tissue regeneration (BTR) regarding BV/TV of femoral and tibial defects of animal models. The ideal structure of the printed scaffolds displayed optimal results with a total porosity >50% with a pore size ranging between 300- and 400µM. Moreover, integrating additional features and engineered macro-channels within these scaffolds notably enhanced BTR capacity, especially observed at extended time points. In conclusion, 3D-printed composite scaffolds have shown promise as an alternative for addressing bone defects.

Functionalized 3D-printed GelMA/Laponite hydrogel scaffold promotes BMSCs recruitment through osteoimmunomodulatory enhance osteogenic via AMPK/mTOR signaling pathway

The migration and differentiation of bone marrow mesenchymal stem cells (BMSCs) play crucial roles in bone repair processes. However, conventional scaffolds often lack of effectively inducing and recruiting BMSCs. In our study, we present a novel approach by introducing a 3D-bioprinted scaffold composed of hydrogels, with the addition of laponite to the GelMA solution, aimed at enhancing scaffold performance. Both in vivo and in vitro experiments have confirmed the outstanding biocompatibility of the scaffold. Furthermore, for the first time, Apt19s has been chemically modified onto the surface of the hydrogel scaffold, resulting in a remarkable enhancement in the migration and adhesion of BMSCs. Moreover, the scaffold has demonstrated robust osteogenic differentiation capability in both in vivo and in vitro environments. Additionally, the hydrogel scaffold has shown the ability to induce the polarization of macrophages from M1 to M2, thereby facilitating the osteogenic differentiation of BMSCs via the bone immune pathway. Through RNA-seq analysis, it has been revealed that macrophages regulate the osteogenic differentiation of BMSCs through the AMPK/mTOR signaling pathway. In summary, the functionalized GelMA/Laponite scaffold offers a cost-effective approach for tailored in situ bone regeneration.

3D bioprinting techniques and hydrogels for osteochondral integration regeneration

Despite considerable advancements in regenerative medicine, restoring the osteochondral interface and facilitating the integration of osteochondral regeneration remain significant clinical conundrums. This challenge is predominantly attributed to the scarcity of appropriate tissue engineering materials for replacing osteochondral defects and facilitating tissue regeneration. 3D bioprinting constitutes a promising approach for bone fabrication, as it not only allows for the design of precise personalized scaffolds but also encapsulates cells and growth factors, with the potential to replicate the functions of native tissues. Many critical properties of hydrogels, such as their mechanical properties, elasticity, and bioactivity, make them the most prevalently utilized bioinks in tissue engineering. In addition, their structure can be easily adjusted to meet the needs of different situations. Therefore, 3D-bioprinted hydrogel scaffolds may have promising prospects for integrated osteochondral repair and are receiving increasing attention. In this review, we describe the current problems encountered in the field of osteochondral integration repair and review the latest advances in current 3D printing technology and 3D bioprinting hydrogel scaffolds. We propose prospects for the development of novel 3D-bioprinted hydrogel scaffolds, providing cues for future research directions.

Innovative Strategies in 3D Bioprinting for Spinal Cord Injury Repair.

Spinal cord injury (SCI) is a catastrophic condition that disrupts neurons within the spinal cord, leading to severe motor and sensory deficits. While current treatments can alleviate pain, they do not promote neural regeneration or functional recovery. Three-dimensional (3D) bioprinting offers promising solutions for SCI repair by enabling the creation of complex neural tissue constructs. This review provides a comprehensive overview of 3D bioprinting techniques, bioinks, and stem cell applications in SCI repair. Additionally, it highlights recent advancements in 3D bioprinted scaffolds, including the integration of conductive materials, the incorporation of bioactive molecules like neurotrophic factors, drugs, and exosomes, and the design of innovative structures such as multi-channel and axial scaffolds. These innovative strategies in 3D bioprinting can offer a comprehensive approach to optimizing the spinal cord microenvironment, advancing SCI repair. This review highlights a comprehensive understanding of the current state of 3D bioprinting in SCI repair, offering insights into future directions in the field of regenerative medicine.

Advances in Filament Structure of 3D Bioprinted Biodegradable Bone Repair Scaffolds.

Conventional bone repair scaffolds can no longer meet the high standards and requirements of clinical applications in terms of preparation process and service performance. Studies have shown that the diversity of filament structures of implantable scaffolds is closely related to their overall properties (mechanical properties, degradation properties, and biological properties). To better elucidate the characteristics and advantages of different filament structures, this paper retrieves and summarizes the state of the art in the filament structure of the three-dimensional (3D) bioprinted biodegradable bone repair scaffolds, mainly including single-layer structure, double-layer structure, hollow structure, core-shell structure and bionic structures. The eximious performance of the novel scaffolds was discussed from different aspects (material composition, ink configuration, printing parameters, etc.). Besides, the additional functions of the current bone repair scaffold, such as chondrogenesis, angiogenesis, anti-bacteria, and anti-tumor, were also concluded. Finally, the paper prospects the future material selection, structural design, functional development, and performance optimization of bone repair scaffolds.

3D Bioprinting Photo-Crosslinkable Hydrogels for Bone and Cartilage Repair.

Three-dimensional (3D) bioprinting has become a promising strategy for bone manufacturing, with excellent control over geometry and microarchitectures of the scaffolds. The bioprinting ink for bone and cartilage engineering has thus become the key to developing 3D constructs for bone and cartilage defect repair. Maintaining the balance of cellular viability, drugs or cytokines’ function, and mechanical integrity is critical for constructing 3D bone and/or cartilage scaffolds. Photo-crosslinkable hydrogel is one of the most promising materials in tissue engineering; it can respond to light and induce structural or morphological transition. The biocompatibility, easy fabrication, as well as controllable mechanical and degradation properties of photo-crosslinkable hydrogel can meet various requirements of the bone and cartilage scaffolds, which enable it to serve as an effective bio-ink for 3D bioprinting. Here, in this review, we first introduce commonly used photo-crosslinkable hydrogel materials and additives (such as nanomaterials, functional cells, and drugs/cytokine), and then discuss the applications of the 3D bioprinted photo-crosslinkable hydrogel scaffolds for bone and cartilage engineering. Finally, we conclude the review with future perspectives about the development of 3D bioprinting photo-crosslinkable hydrogels in bone and cartilage engineering.

Spatiotemporal delivery of BMP-2 and FGF-18 in 3D-bioprinted tri-phasic osteochondral scaffolds enhanced compartmentalized osteogenic and chondrogenic differentiation of mesenchymal stem cells isolated from rats with varied organizational morphologies

Replicating the heterogeneous structure and promoting compartmentalized osteogenesis/chondrogenesis are critical considerations in designing scaffolds for osteochondral tissue regeneration. However, desirable osteochondral regeneration cannot be achieved mainly due to the absence of effective delivery strategies for growth factors (GFs) and the insufficiency of desirable organizational morphologies for seed cells. Herein, we developed a tri-phasic osteochondral scaffold consisting of bone morphogenetic protein-2 (BMP-2)-loaded subchondral layer, fibroblast growth factor-18 (FGF-18)-loaded cartilage layer, and an interface layer that acted as a barrier to reduce the mutual interference of GFs, via cryogenic 3D bioprinting. BMP-2 could exert osteogenic effects for 14 days, and FGF-18 could exert chondrogenic effects for 21 days, demonstrating the time-controlled release function of BMP-2 and FGF-18. By further seeding discrete rat bone marrow mesenchymal stem cells (rBMSCs) and rBMSC microspheres, respectively, onto the subchondral layer and cartilage layer, the engineered cell-laden osteochondral tissue was constructed. The spatiotemporal release of BMP-2 and FGF-18 in the subchondral layer and cartilage layer promoted the osteogenic differentiation of discrete rBMSCs and chondrogenic differentiation of rBMSC microspheres in the subchondral layer and cartilage layer, respectively. In summary, by seeding rBMSCs with varied organizational morphologies in 3D-printed osteochondral scaffolds with a spatiotemporally controlled strategy, engineered osteochondral tissue with compartmentalized osteogenic/chondrogenic differentiation potent can be formed, displaying a facile and promising way to achieve desirable osteochondral tissue regeneration.

3D bioprinted mesenchymal stem cell laden scaffold enhances subcutaneous vascularization for delivery of cell therapy

Subcutaneous delivery of cell therapy is an appealing minimally-invasive strategy for the treatment of various diseases. However, the subdermal site is poorly vascularized making it inadequate for supporting engraftment, viability, and function of exogenous cells. In this study, we developed a 3D bioprinted scaffold composed of alginate/gelatin (Alg/Gel) embedded with mesenchymal stem cells (MSCs) to enhance vascularization and tissue ingrowth in a subcutaneous microenvironment. We identified bio-ink crosslinking conditions that optimally recapitulated the mechanical properties of subcutaneous tissue. We achieved controlled degradation of the Alg/Gel scaffold synchronous with host tissue ingrowth and remodeling. Further, in a rat model, the Alg/Gel scaffold was superior to MSC-embedded Pluronic hydrogel in supporting tissue development and vascularization of a subcutaneous site. While the scaffold alone promoted vascular tissue formation, the inclusion of MSCs in the bio-ink further enhanced angiogenesis. Our findings highlight the use of simple cell-laden degradable bioprinted structures to generate a supportive microenvironment for cell delivery.Graphical

3D-bioprinted GelMA/gelatin/amniotic membrane extract (AME) scaffold loaded with keratinocytes, fibroblasts, and endothelial cells for skin tissue engineering

Gelatin-methacryloyl (GelMA) is a highly adaptable biomaterial extensively utilized in skin regeneration applications. However, it is frequently imperative to enhance its physical and biological qualities by including supplementary substances in its composition. The purpose of this study was to fabricate and characterize a bi-layered GelMA-gelatin scaffold using 3D bioprinting. The upper section of the scaffold was encompassed with keratinocytes to simulate the epidermis, while the lower section included fibroblasts and HUVEC cells to mimic the dermis. A further step involved the addition of amniotic membrane extract (AME) to the scaffold in order to promote angiogenesis. The incorporation of gelatin into GelMA was found to enhance its stability and mechanical qualities. While the Alamar blue test demonstrated that a high concentration of GelMA (20%) resulted in a decrease in cell viability, the live/dead cell staining revealed that incorporation of AME increased the quantity of viable HUVECs. Further, gelatin upregulated the expression of KRT10 in keratinocytes and VIM in fibroblasts. Additionally, the histological staining results demonstrated the formation of well-defined skin layers and the creation of extracellular matrix (ECM) in GelMA/gelatin hydrogels during a 14-day culture period. Our study showed that a 3D-bioprinted composite scaffold comprising GelMA, gelatin, and AME can be used to regenerate skin tissues.

3D-bioprinted anti-senescence organoid scaffolds repair cartilage defect and prevent joint degeneration via miR-23b/ELOVL5-mediated metabolic rewiring

IntroductionOsteoarthritis (OA) is the most prevalent degenerative disease worldwide and commonly occurs among the elderly. At present, there is no effective treatment for OA. When OA develops to the end stage, arthroplasty is generally operated to improve the life quality of patients. Targeting senescence has been considered as a therapeutic approach for OA in recent years. Methods & resultsIn this study, we have identified P16 gene as a novel target for anti-senescence strategy and harnessed small interfering RNA (siRNA) technology to fabricate P16-siRNA encapsulated PLGA microspheres. We combined this with our previously successful three-dimensional (3D) culture of functionally bioengineered chondrogenic synovial mesenchymal stromal cell (SMSC) organoids. This served as the primary component of the bio-ink for 3D bioprinting, culminating in the creation of P16-siRNA PLGA µS and SMSC organoid hydrogel-polymer composite scaffold (PPSOH). Its superior capabilities of cartilage repair were confirmed through in vivo and in vitro experimentations. In the rabbit model of knee cartilage defects, PPSOH not only restored the superior characteristics of native healthy hyaline cartilage but also maintained post-implanted joint function. It prevented development of joint degeneration resulting from cartilage defects by mitigating intra-articular inflammatory responses and cellular senescence. Our usage of miRNA and RNA sequencing reveals that PPSOH targets the miR-23b/ELOVL5 axis and rewired cellular metabolism, therefore regulating glycolysis and fatty acid oxidation. This effectively alleviates cellular senescence, promotes relief from OA, and facilitates cartilage regeneration. ConclusionPPSOH scaffold could effectively alleviate cellular senescence, foster relief from OA, and facilitate cartilage regeneration. Further experiments disclosed that PPSOH targets the miR-23b/ELOVL5 axis and rewired cellular metabolism by regulating glycolysis and fatty acid oxidation. Therefore, PPSOH could be used as potential therapy for cartilage repair in osteoarthritic patients.

Alendronate releasing silk fibroin 3D bioprinted scaffolds for application in bone tissue engineering: Effects of alginate concentration on printability, mechanical properties and stability

3D bioprinting uses biomaterials combined with cells to develop living constructs. This study explores the optimization of natural polymers, including silk fibroin, gelatin, and alginate, as bioink for 3D bioprinting in bone tissue engineering. The physicochemical properties of the bioink were thoroughly examined, revealing high water uptake and reduced degradation rate due to the addition of silk fibroin. The compressive modulus increased with higher alginate concentration. Rheological analysis confirmed shear-thinning properties and viscoelasticity of the ink. Through meticulous parameter optimization, the ink achieved the highest print accuracy with 4 % w/v alginate content. The printed scaffolds exhibited both macro and micro porosity, making them suitable for bone tissue regeneration. Furthermore, the scaffolds remained stable in culture medium for 36 days. The optimal composition for the hydrogel was determined to be a blend of 5 % fibroin, 7 % gelatin, and 4 % alginate in equal ratios. The bioink demonstrated excellent biocompatibility and, when supplemented with alendronate, enhanced alkaline phosphatase activity in MG-63 osteoblast-like cells. This finding indicates the commitment of cells toward the osteoblastic phenotype. Overall, this study successfully optimized the bioink and bioprinting process for bone tissue engineering applications, highlighting its promising potential for future advancements in the field.

A comparative analysis of 3D bioprinted gelatin-hyaluronic acid-alginate scaffold and microfracture for the management of osteochondral defects in the rabbit knee joint.

This study aims to compare the radiological, biomechanical, and histopathological results of microfracture treatment and osteochondral damage repair treatment with a new scaffold product produced by the three-dimensional (3D) bioprinting method containing gelatin-hyaluronic acid-alginate in rabbits with osteochondral damage. A new 3D bioprinted scaffold consisting of gelatin, hyaluronic acid, and alginate designed by us was implanted into the osteochondral defect created in the femoral trochlea of 10 rabbits. By randomization, it was determined which side of 10 rabbits would be repaired with a 3D bioprinted scaffold, and microfracture treatment was applied to the other knees of the rabbits. After six months of follow-up, the rabbits were sacrificed. The results of both treatment groups were compared radiologically, biomechanically, and histopathologically. None of the rabbits experienced any complications. The magnetic resonance imaging evaluation showed that all osteochondral defect areas were integrated with healthy cartilage in both groups. There was no significant difference between the groups in the biomechanical load test (p=0.579). No statistically significant difference was detected in the histological examination using the modified Wakitani scores (p=0.731). Our study results showed that 3D bioprinted scaffolds exhibited comparable radiological, biomechanical, and histological properties to the conventional microfracture technique for osteochondral defect treatment.

Multi-modal imaging for dynamic visualization of osteogenesis and implant degradation in 3D bioprinted scaffolds

In situ monitoring of bone regeneration enables timely diagnosis and intervention by acquiring vital biological parameters. However, an existing gap exists in the availability of effective methodologies for continuous and dynamic monitoring of the bone tissue regeneration process, encompassing the concurrent visualization of bone formation and implant degradation. Here, we present an integrated scaffold designed to facilitate real-time monitoring of both bone formation and implant degradation during the repair of bone defects. Laponite (Lap), CyP-loaded mesoporous silica (CyP@MSNs) and ultrasmall superparamagnetic iron oxide nanoparticles (USPIO@SiO2) were incorporated into a bioink containing bone marrow mesenchymal stem cells (BMSCs) to fabricate functional scaffolds denoted as C@M/GLU using 3D bioprinting technology. In both in vivo and in vitro experiments, the composite scaffold has demonstrated a significant enhancement of bone regeneration through the controlled release of silicon (Si) and magnesium (Mg) ions. Employing near-infrared fluorescence (NIR-FL) imaging, the composite scaffold facilitates the monitoring of alkaline phosphate (ALP) expression, providing an accurate reflection of the scaffold's initial osteogenic activity. Meanwhile, the degradation of scaffolds was monitored by tracking the changes in the magnetic resonance (MR) signals at various time points. These findings indicate that the designed scaffold holds potential as an in situ bone implant for combined visualization of osteogenesis and implant degradation throughout the bone repair process.

Fused Deposition Modeling 3D-Printed Scaffolds for Bone Tissue Engineering Applications: A Review.

The emergence of bone tissue engineering as a trend in regenerative medicine is forcing scientists to create highly functional materials and scaffold construction techniques. Bone tissue engineering uses 3D bio-printed scaffolds that allow and stimulate the attachment and proliferation of osteoinductive cells on their surfaces. Bone grafting is necessary to expedite the patient's condition because the natural healing process of bones is slow. Fused deposition modeling (FDM) is therefore suggested as a technique for the production process due to its simplicity, ability to create intricate components and movable forms, and low running costs. 3D-printed scaffolds can repair bone defects in vivo and in vitro. For 3D printing, variousmaterials including metals, polymers, and ceramics are often employed but polymeric biofilaments are promising candidates for replacing non-biodegradable materials due to their adaptabilityand environment friendliness. This review paper majorly focuses on the fused deposition modeling approach for the fabrication of 3D scaffolds. In addition, it also provides information on biofilaments used in FDM 3D printing, applications, and commercial aspects of scaffolds in bone tissue engineering.

Calcium Phosphate Biomaterials for 3D Bioprinting in Bone Tissue Engineering.

Three-dimensional bioprinting is a promising technology for bone tissue engineering. However, most hydrogel bioinks lack the mechanical and post-printing fidelity properties suitable for such hard tissue regeneration. To overcome these weak properties, calcium phosphates can be employed in a bioink to compensate for the lack of certain characteristics. Further, the extracellular matrix of natural bone contains this mineral, resulting in its structural robustness. Thus, calcium phosphates are necessary components of bioink for bone tissue engineering. This review paper examines different recently explored calcium phosphates, as a component of potential bioinks, for the biological, mechanical and structural properties required of 3D bioprinted scaffolds, exploring their distinctive properties that render them favorable biomaterials for bone tissue engineering. The discussion encompasses recent applications and adaptations of 3D-printed scaffolds built with calcium phosphates, delving into the scientific reasons behind the prevalence of certain types of calcium phosphates over others. Additionally, this paper elucidates their interactions with polymer hydrogels for 3D bioprinting applications. Overall, the current status of calcium phosphate/hydrogel bioinks for 3D bioprinting in bone tissue engineering has been investigated.

Advancing scaffold porosity through a machine learning framework in extrusion based 3D bioprinting

Three Dimensional (3D) bioprinting holds great promise for tissue and organ regeneration due to its inherent capability to deposit biocompatible materials containing live cells in precise locations. Extrusion-based 3D bioprinting (EBP) method stands out for its ability to achieve a higher cell release rate, ensuring both external and internal scaffold structures. The systematic adjustment of key process parameters of EBP, including nozzle diameter, printing speed, print distance, extrusion pressure, material fraction, and viscosity allows for precise control over filament dimensions, ultimately shaping the desired scaffold porosity as per user specifications. However, managing these factors with all possible interactions simultaneously to achieve the desired filament width can be intricate and resource intensive. This study presents a novel framework designed to construct a predictive model for the filament width of 3D bioprinted scaffolds for various process parameters. A total of 157 experiments have been conducted under various combinations of process parameters and biomaterial’s weight fraction for this study purpose. A regression-based machine learning approach is employed to develop the predictive model utilizing Adj. R2, Mallow’s Cp, and Bayesian Information Criterion (BIC). Following model development, rigorous experimental validations are conducted to assess the accuracy and reliability of the model. Based on the cross-validation of randomly split test data, Adj. R2 model emerges as the highest performing machine learning model (Mean Squared Error, MSE = 0.0816) compared to Mallow’s Cp and BIC (MSE = 0.0841 and 0.0877, respectively) models. The comparative analysis results between the experimental and model’s data demonstrate that our predictive model achieves an accuracy of approximately 85% in filament width prediction. This framework presents a significant advancement in the precise control and optimization of 3D bioprinted scaffold fabrication, offering valuable insights for the advancement of tissue engineering and regenerative medicine applications.