Enhanced osteogenesis of 3D printed β-TCP scaffolds with Cissus Quadrangularis extract-loaded polydopamine coatings

Gingerol encapsulated lipid nanoparticles on 3D-printed scaffolds for orthopedic and dental applications

Natural medicinal compounds (NMCs) exhibit medicinal properties and show particular promise in healing bone defects caused by osteosarcoma or fractures. Gingerol (GE) sourced from ginger root (Zingiber officinale) extract, possesses antibacterial, osteogenic, analgesic, antitumorigenic, and anti-inflammatory properties. We encapsulate gingerol within lipid nanoparticles (LNPs) to promote these beneficial properties and provide enhanced stability. These GE LNPs paired with 3D-printed tricalcium phosphate allow for patient-specific drug delivery at the wound site. This system reveals a 16 % and 12 % reduction in burst release of the GE in pH 5.0 and 7.4, respectively. GE LNPs exhibit a 1.3-fold increase in osteoblast viability and 3.3-fold higher cytotoxicity towards osteosarcoma cells compared to untreated scaffolds. Treated scaffolds also show a 4.4-fold reduction in the gram-positive Staphylococcus aureus through cell wall dilation and rupture. Integrating GE LNPs into 3D-printed scaffolds reveals a novel strategy to expedite bone repair and may hold potential in future bone tissue engineering applications.

Irisin mitigates osteoporotic-associated bone loss and gut dysbiosis in ovariectomized mice by modulating microbiota, metabolites, and intestinal barrier integrity

BACKGROUND

Osteoporotic bone defects significantly affect patient health and quality of life. The gut-bone axis plays a crucial role in osteoporosis, and disruptions in gut microbiota are linked to systemic inflammation and compromised bone metabolism. Irisin, a myokine, has shown potential in protecting against osteoporosis, but its mechanisms of action on the gut-bone axis remain unclear. This study aimed to investigate the role of irisin in mitigating osteoporotic bone defects by examining its effects on gut microbiota, related metabolites, and intestinal barrier integrity.

METHODS

An osteoporosis model was created using ovariectomized (OVX) mice. The mice were divided into Sham, OVX, and r-irisin groups. Mice in the r-irisin group received intraperitoneal injections of 100 μg/kg irisin twice weekly for five weeks. Bone parameters were analyzed by micro-CT and histological staining. Gut microbiota composition was examined via 16S rDNA sequencing. Intestinal cytokines and barrier proteins were measured using immunohistochemistry and ELISA. Fecal metabolomic profiling was conducted using liquid chromatography-tandem mass spectrometry (LC-MS/MS), and correlations between gut microbiota, metabolites, and bone metabolism markers were evaluated.

RESULTS

Irisin treatment improved bone mineral density (BMD), bone volume/tissue volume (BV/TV), trabecular bone thickness (Tb.Th), and trabecular number (Tb.N), and reduced trabecular separation (Tb.Sp) in OVX mice. It enhanced new bone formation and collagen deposition. Irisin restored intestinal barrier integrity by increasing tight junction protein expression and reducing inflammatory cytokines in intestinal tissues. It also modulated gut microbiota diversity, reducing Firmicutes and increasing Verrucomicrobiota abundance. Key fecal metabolites, including atractylon (r = - 0.60, P < 0.01) and enterodiol (r = + 0.83, P < 0.01), showed strong correlations with BMD.

CONCLUSION

Irisin mitigates osteoporotic bone defects by enhancing bone formation, restoring intestinal barrier integrity, modulating gut microbiota composition, and influencing fecal metabolites. These preclinical findings highlight irisin's potential to mitigate osteoporosis via the gut-bone axis.

Leveraging the Shape Fidelity of 3D Printed Bone Scaffolds Through Architectural Tailoring of an Emulsion Ink: A Combined Experimental and Computational Analysis

Hierarchical porous, bioactive, and biocompatible scaffolds with customizable multi-functionality are promising alternatives for autografts and allografts in bone tissue engineering. Combining high internal phase emulsion (HIPE) templating with additive manufacturing provides possibilities to produce such multiscale porous scaffolds. 3D printing of HIPE remains a challenging task due to the intense phase separation under high shear extrusion and reported printability (Pr) of either less than or greater than 1. Tuning viscoelastic properties of emulsion is therefore required to achieve a Pr ≈1. This study addresses these issues by preparing Pickering HIPEs using dual networks with synergistic viscous and elastic properties, stabilized by Cloisite 30B interphase. This configuration enhances viscoelasticity and achieves Pr values close to 1 (0.98-1.02). The printed scaffolds exhibit trabecular bone-like, hierarchical interconnected porosity (77%-86%). Computational simulations accurately predict the mechanical, biological, and degradation behavior. Functionalization with Cissus quadrangularis bioactivates the scaffolds, demonstrates in vivo biocompatibility, promotes MC3T3-E1 adhesion, and proliferation, accelerates osteogenesis, and reduces oxidative stress compared to neat PCL scaffolds. This work introduces a facile strategy for "engineering printability" to produce regenerative materials with hierarchical design and holds the potential for developing optimized bone tissue engineering scaffolds.

Tauroursodeoxycholic acid combined with selenium accelerates bone regeneration in ovariectomized rats

More recently, increased studies have revealed that antioxidants can cure osteoporosis by inhibiting oxidative stress. Tauroursodeoxycholic acid (TUDCA) and Selenium (Se) have been confirmed to possess potent anti-oxidative effects and accelerate bone regeneration. In addition, very little is currently known about the effects of a combination with Se and TUDCA on bone defects in osteoporotic states. We, therefore, aimed to assess the protective effect of combination with Se and TUDCA on bone regeneration and investigate the effect and underlying mechanisms. When MC3T3-E1 was cultured in the presence of H2H2, Se, TUDCA and Se/TUDCA therapy could increase the matrix mineralization and promote expression of anti-oxidative stress markers in MC3T3-E1, while reducing intracellular reactive oxygen species (ROS) and mitochondrial ROS levels. Meanwhile, silent information regulator type 1 (SIRT1) was upregulated in response to Se, TUDCA and Se/TUDCA exposures in H2H2 treated-MC3T3-E1. In the OVX rat model, Se, TUDCA and Se/TUDCA showed a clear positive effect against impaired bone repair in osteoporosis. The results above demonstrate that Se/TUDCA exhibits superior efficacy in both cellular and animal experiments, as compared to Se and TUDCA. In conclusion, combination with Se and TUDCA stimulates bone regeneration and is a promising candidate for promoting bone repair in osteoporosis.

Ginger extract loaded Fe2O3/MgO-doped hydroxyapatite: Evaluation of biological properties for bone-tissue engineering

Since antiquity, the medicinal properties of naturally sourced biomolecules such as ginger (Zingiber officinale) extract are documented in the traditional Indian and Chinese medical systems. However, limited work is performed to assess the potential of ginger extracts for bone-tissue engineering. Our work demonstrates the direct incorporation of ginger extract on iron oxide-magnesium oxide (Fe2O3 and MgO) co-doped hydroxyapatite (HA) for enhancement in the biological properties. The addition of Fe2O3 and MgO co-doping system and ginger extract with HA increases the osteoblast viability up to ~ 1.4 times at day 11. The presence of ginger extract leads to up to ~ 9 times MG-63 cell viability reduction. The co-doping does not adversely affect the release of ginger extract from the graft surface in the biological medium at pH 7.4 for up to 28 days. Assessment of antibacterial efficacy according to the modified ISO 22196: 2011 standard method indicates that the combined effects of Fe2O3, MgO, and ginger extract lead to ~ 82 % more bacterial cell reduction, compared to the control HA against S. aureus. These ginger extract-loaded artificial bone grafts with enhanced biological properties may be utilized as a localized site-specific delivery vehicle for various bone tissue engineering applications.

Vitamin D3 Release from MgO Doped 3D Printed TCP Scaffolds for Bone Regeneration

Regenerating bone tissue in critical-sized craniofacial bone defects remains challenging and requires the implementation of innovative bone implants with early stage osteogenesis and blood vessel formation. Vitamin D3 is incorporated into MgO-doped 3D-printed scaffolds for defect-specific and patient-specific implants in low load-bearing areas. This novel bone implant also promotes early stage osteogenesis and blood vessel development. Our results show that vitamin D3-loaded MgO-doped 3D-printed scaffolds enhance osteoblast cell proliferation 1.3-fold after being cultured for 7 days. Coculture studies on osteoblasts derived from human mesenchymal stem cells (hMSCs) and osteoclasts derived from monocytes show the upregulation of genes related to osteoblastogenesis and the downregulation of RANK-L, which is essential for osteoclastogenesis. Release of vitamin D3 also inhibits osteoclast differentiation by 1.9-fold after a 21-day culture. After 6 weeks, vitamin D3 release from MgO-doped 3D-printed scaffolds enhances the new bone formation, mineralization, and angiogenic potential. The multifunctional 3D-printed scaffolds can improve early stage osteogenesis and blood vessel formation in craniofacial bone defects.

Cissus Extracts in Dentistry: A Comprehensive Review on its Untapped Potential

Natural products have received a lot of attention in a variety of medical sectors, including dentistry. Cissus, a flowering plant genus, has long been used for its therapeutic benefits. The purpose of this review is to thoroughly investigate the possibilities of Cissus extracts in dentistry. To that end, we used specific selection criteria for the selection of pertinent scientific articles published in the scientific information databases of PubMed, Web of Science, Google Scholar, Scopus, and ProQuest. We found that the diverse array of bioactive compounds found in varied species of Cissus holds promise for applications ranging from oral wound healing to periodontal health. This review summarizes known studies on antibacterial, anti-inflammatory, and tissue-regenerative characteristics of Cissus extracts, shedding light on their potential significance in modernizing modern dental practices. It exerts that Cissus extracts have the potential to supplement established dentistry therapies by providing all-natural remedies for a variety of oral health conditions.

Natural medicine delivery from 3D printed bone substitutes

Unmet medical needs in treating critical-size bone defects have led to the development of numerous innovative bone tissue engineering implants. Although additive manufacturing allows flexible patient-specific treatments by modifying topological properties with various materials, the development of ideal bone implants that aid new tissue regeneration and reduce post-implantation bone disorders has been limited. Natural biomolecules are gaining the attention of the health industry due to their excellent safety profiles, providing equivalent or superior performances when compared to more expensive growth factors and synthetic drugs. Supplementing additive manufacturing with natural biomolecules enables the design of novel multifunctional bone implants that provide controlled biochemical delivery for bone tissue engineering applications. Controlled release of naturally derived biomolecules from a three-dimensional (3D) printed implant may improve implant-host tissue integration, new bone formation, bone healing, and blood vessel growth. The present review introduces us to the current progress and limitations of 3D printed bone implants with drug delivery capabilities, followed by an in-depth discussion on cutting-edge technologies for incorporating natural medicinal compounds embedded within the 3D printed scaffolds or on implant surfaces, highlighting their applications in several pre- and post-implantation bone-related disorders.

Multifunctional polydopamine - Zn2+-curcumin coated additively manufactured ceramic bone grafts with enhanced biological properties

The lack of site-specific chemotherapeutic agents after osteosarcoma surgeries often induces severe side effects. We propose the utilization of curcumin as an alternative natural chemo-preventive drug for tumor-specific delivery systems with 3D printed tricalcium phosphate (TCP) based artificial bone grafts. The poor bioavailability and hydrophobic nature of curcumin restrict its clinical use. We have used polydopamine (PDA) coating with Zn2+ functionalization to enhance the curcumin release in the biological medium. The obtained PDA-Zn2+ complex is characterized by X-ray photoelectron spectroscopy (XPS). The presence of PDA-Zn2+ coating leads to ~2 times enhancement in curcumin release. We have computationally predicted and validated the optimized surface composition by a novel multi-objective optimization method. The experimental validation of the predicted compositions indicates that the PDA-Zn2+ coated curcumin immobilized delivery system leads to a ~12 folds decrease in osteosarcoma viability on day 11 as compared to only TCP. The osteoblast viability shows ~1.4 folds enhancement. The designed surface shows the highest ~90 % antibacterial efficacy against gram-positive and gram-negative bacteria. This unique strategy of curcumin delivery with PDA-Zn2+ coating is expected to find application in low-load bearing critical-sized tumor-resection sites.

Novel coatings for the continuous repair of human bone defects

Bone defects are the second most common tissue grafts after blood. However, bone grafts face several problems, such as bone scaffolds, which have low bioactivity and are prone to corrosion. Much of the current research on bone scaffolds is focused on the mechanical aspects such as structure and strength. Surface modification of the bone scaffold is carried out in terms of the mechanical structure or structural design of the bone scaffold with reference to a bionic structure. However, with the development of mechanical designs, materials science, and medicine, many studies have reported that promoting bone growth by modifying the structure of the scaffold or coating is not possible. Therefore, the application of a bioactive coating to the surface of the bone scaffold is particularly important to generate a synergistic effect between the structure and active coating. In this article, we present several perspectives to improve the bioactivity of bone scaffolds, including corrosion resistance, loading of bioactive coatings or drugs on bone scaffolds, improved adhesion to the surface of the bone scaffolds, immune response modulation, and drawing on bionic structures during manufacturing.

3D printed hydroxyapatite-nacre-starch based bone grafts: Evaluation of biological and mechanical properties

The possibilities of utilizing nacre as a reinforcing material to manufacture 3D printed bone grafts are yet to be explored. This work reports the feasibility of fabricating 3D printed nacre-hydroxyapatitestarch composite bone graft substitutes, emphasizing the effects of nacre addition on biological and mechanical properties. Pressure-less extrusion-based 3D printing of ceramic-polymer viscous slurry is challenging due to the composition and process-parameter variations. To overcome these challenges, a dual extrusion solid freeform fabricator (SFF) has been designed. An increase in nacre loading improves the compressive strength from 9.5 ± 0.1 MPa to 11.7 ± 0.2 MPa, without any post-processing or sintering. Nacre's in vitro osteogenic properties lead to a slight increase in hFOB cellular attachment on the graft surface by day 11. The fabricated structures show good mechanical integrity during the dissolution study in simulated body fluid (SBF). These bone graft substitutes may be utilized to repair low load bearing skeletal defects.

An updated review on application of 3D printing in fabricating pharmaceutical dosage forms

The concept of "one size fits all" followed by the conventional healthcare system has drawbacks in providing precise pharmacotherapy due to variation in the pharmacokinetics of different patients leading to serious consequences such as side effects. In this regard, digital-based three-dimensional printing (3DP), which refers to fabricating 3D printed pharmaceutical dosage forms with variable geometry in a layer-by-layer fashion, has become one of the most powerful and innovative tools in fabricating "personalized medicine" to cater to the need of therapeutic benefits for patients to the maximum extent. This is achieved due to the tremendous potential of 3DP in tailoring various drug delivery systems (DDS) in terms of size, shape, drug loading, and drug release. In addition, 3DP has a huge impact on special populations including pediatrics, geriatrics, and pregnant women with unique or frequently changing medical needs. The areas covered in the present article are as follows: (i) the difference between traditional and 3DP manufacturing tool, (ii) the basic processing steps involved in 3DP, (iii) common 3DP methods with their pros and cons, (iv) various DDS fabricated by 3DP till date with discussing few research studies in each class of DDS, (v) the drug loading principles into 3D printed dosage forms, and (vi) regulatory compliance.

Influence of random and designed porosities on 3D printed tricalcium phosphate-bioactive glass scaffolds

Calcium phosphate (CaP)-based ceramics are a popular choice for bone-graft applications due to their compositional similarities with bone. Similarly, Bioactive glass (BG) is also common for bone tissue engineering applications due to its excellent biocompatibility and bone binding ability. We report tricalcium phosphate (TCP)-BG (45S5 BG) composite scaffolds using conventional processing and binder jetting-based 3D printing (3DP) technique. We hypothesize that BG's addition in TCP will enhance densification via liquid phase sintering and improve mechanical properties. Further, BG addition to TCP should modulate the dissolution kinetics in vitro. This work's scientific objective is to understand the influence of random vs. designed porosity in TCP-BG ceramics towards variations in compressive strength and in vitro biocompatibility. Our findings indicate that a 5 wt % BG in TCP composite shows a compressive strength of 26.7 ± 2.7 MPa for random porosity structures having a total porosity of ~47.9%. The same composition in a designed porosity structure shows a compressive strength of 21.3 ± 2.9 MPa, having a total porosity of ~54.1%. Scaffolds are also tested for their dissolution kinetics and in vitro bone cell materials interaction, where TCP-BG compositions show favorable bone cell materials interactions. The addition of BG enhances a flaky hydroxycarbonate apatite (HCA) layer in 8 weeks in vitro. Our research shows that the porous TCP- BG scaffolds, fabricated via binder jetting method with enhanced mechanical properties and dissolution properties can be utilized in bone graft applications.

A Numerical Study of Fluid Flow in the Porous Structure of Biological Scaffolds

Tissue engineering (TE) is one of the promising areas that aims to address the global problem of organ and tissue shortages. The successful development of TE, particularly in bone tissue engineering, consists of the use of modern methods that allow the creation of scaffolds, the physicochemical, mechanical, and structural parameters of which will allow achieving the desired clinical results. The vast possibilities of the rapidly developing technology of three-dimensional (3D) printing, which allows the creation of individual scaffolds with high precision, has led to various developments in bone tissue TE. In this work, for the successful use of three-dimensional printing in TE to ensure the diffusion of nutrients during cell cultivation throughout the entire structure of the scaffold, a model of a rotating scaffold is proposed, and the movement of the diffusion flow of nutrient fluid is calculated based on Darcy’s law, which regulates the flow of fluids through porous media. The conducted studies of the rate of diffusion flow of nutrients based on glucose in the porous structure of scaffolds with a 10% content of calcium hydroxyapatite demonstrated the promise of using a model of a rotating composite scaffold in TE of bone tissue. The results show that at a scaffold rotation speed of 12 rpm, the diffusion flow rate of nutrients in the composite scaffolds porous structure is practically not affected by their geometric shape.