Comparative effects of controlled release of sodium bicarbonate and doxorubicin on osteoblast and osteosarcoma cell viability

Self-assembled injectable Icariin@ Ti3C2Tx/doxorubicin hydrogel preserving osteogenesis while synergizing photodynamic and chemodynamic therapy for osteosarcoma

Local therapy involving injectable hydrogel systems loaded with doxorubicin (DOX) has garnered significant attention in the realm of osteosarcoma (OS) research. Nevertheless, it has been noted that the local delivery of high-dose DOX exerts a pronounced inhibitory impact on osteogenesis, which is detrimental to the restoration of functional capabilities after OS treatment. To address this challenge, we have designed a self-assembled injectable hydrogel system that integrates photodynamic and chemodynamic therapy, aiming to enhance efficacy while mitigating adverse effects on osteogenic differentiation. In this study, an injectable sodium alginate (SA) hydrogel was fabricated by encapsulating titanium carbide powder (Ti3C2Tx) and osteoprotegerin Icariin (ICA) along with DOX. This hydrogel system demonstrated remarkable drug-loading capacity and sustained drug release. Furthermore, under near-infrared (NIR) irradiation, the hydrogel displayed outstanding photothermal effects, which, in conjunction with chemotherapy and phototherapy, effectively eradicated UMR-106 tumor cells in vitro. The incorporation of ICA not only enhanced the anti-tumor effect but also alleviated the adverse effects of DOX on the osteogenic differentiation inhibition of bone marrow mesenchymal stem cells (BMSCs). In vivo, findings further confirmed that injectable ITD/SA hydrogels can synergistically heighten anti-osteosarcoma effectiveness while mitigating local osteogenic toxicity. Given these benefits, this hydrogel holds extensive application prospects in the local therapy of OS.

Efficient PEGylated magnetic nanoniosomes for co-delivery of artemisinin and metformin: a new frontier in chemotherapeutic efficacy and cancer therapy

Two strategies were employed to modify the performance of the nano-niosome drug delivery system. Initially, the surface of the nano-niosomes underwent modification through the inclusion of polyethylene glycol, thereby altering its properties. Additionally, the core of the nano-niosomes was equipped with Fe3O4 magnetic nanoparticles to impart magnetic characteristics to the system. This study presents the development of PEGylated magnetic nanoniosomes (PMNios) for the co-delivery of artemisinin (ART) and metformin (MET) in cancer therapy, highlighting significant advancements in chemotherapeutic efficacy. The magnetization of the nano-niosomes facilitated the targeted delivery of drugs to specific tissues, while PEGylation improved the bioavailability of the nano-niosomes. These PEGylated magnetic niosomes (PMNios) were then loaded with artemisinin and metformin drugs. The synthesized PMNios were thoroughly evaluated in terms of zeta potential, size, morphology, and entrapment efficiency. The PMNios achieved a drug loading efficiency of 88%. They exhibited an average size of 298 nm, a polydispersity index of 0.32, and a zeta potential of - 19 mV, indicating the complete stability. SEM and TEM images of the PMNios revealed a spherical morphology. Subsequently, the PMNios were compared with other forms of nano-niosomes, including empty niosomes, non-magnetic niosomes, and non-PEGylated niosomes. The encapsulation of the nano-niosomes with magnetic nanoparticles allows for faster delivery of the encapsulated drugs to the tumor site, while PEGylation improved the stability, bioavailability, and controlled release of the PMNios. Furthermore, the in-vitro effectiveness of various formulations of the PMNios against A549, a lung cancer cell line, demonstrated that the PMNios exhibited appropriate toxicity towards cancer cell lines in the presence of an external magnetic field. Gene expression level of Bcl2 were lower for the PMNios-ART-MET system, whereas the level of Bax were higher than the other group. The PMNios-ART-MET system also demonstrated well internalization into the A549 cells and preponderant endocytosis. These findings underscore the novelty and potential of PMNios as a robust platform for the targeted co-delivery of hydrophilic and hydrophobic drugs, promising a new frontier in cancer therapy by enhancing the therapeutic index and minimizing side effects.

Tumor microenvironment reprogramming by nanomedicine to enhance the effect of tumor immunotherapy

With the rapid development of the fields of tumor biology and immunology, tumor immunotherapy has been used in clinical practice and has demonstrated significant therapeutic potential, particularly for treating tumors that do not respond to standard treatment options. Despite its advances, immunotherapy still has limitations, such as poor clinical response rates and differences in individual patient responses, largely because tumor tissues have strong immunosuppressive microenvironments. Many tumors have a tumor microenvironment (TME) that is characterized by hypoxia, low pH, and substantial numbers of immunosuppressive cells, and these are the main factors limiting the efficacy of antitumor immunotherapy. The TME is crucial to the occurrence, growth, and metastasis of tumors. Therefore, numerous studies have been devoted to improving the effects of immunotherapy by remodeling the TME. Effective regulation of the TME and reversal of immunosuppressive conditions are effective strategies for improving tumor immunotherapy. The use of multidrug combinations to improve the TME is an efficient way to enhance antitumor immune efficacy. However, the inability to effectively target drugs decreases therapeutic effects and causes toxic side effects. Nanodrug delivery carriers have the advantageous ability to enhance drug bioavailability and improve drug targeting. Importantly, they can also regulate the TME and deliver large or small therapeutic molecules to decrease the inhibitory effect of the TME on immune cells. Therefore, nanomedicine has great potential for reprogramming immunosuppressive microenvironments and represents a new immunotherapeutic strategy. Therefore, this article reviews strategies for improving the TME and summarizes research on synergistic nanomedicine approaches that enhance the efficacy of tumor immunotherapy.

Doxorubicin loaded octacalcium phosphate particles as controlled release drug delivery systems: Physico-chemical characterization, in vitro drug release and evaluation of cell death pathway

Mastering new and efficient ways to obtain successful drug delivery systems (DDS) with controlled release became a paramount quest in the scientific community. Increase of malignant bone tumors and the necessity to optimize an approach of localized drug delivery require research to be even more intensified. Octacalcium phosphate (OCP), with a number of advantages over current counterparts is extensively used in bone engineering. The aim of the present research was to synthesize bioactive and biocompatible doxorubicin (DOX) containing OCP particles. DOX-OCP was successfully obtained in situ in an exhaustive range of added drug (1-20 wt%, theoretical loading). Based on XRD, above 10 wt% of DOX, OCP formation was inhibited and the obtained product was low crystalline α-TCP. In-vitro drug release was performed in pH 7.4 and 6.0. In both pH environments DOX had a continuous release over six weeks. However, the initial drug burst for pH 7.4, in the first 24 h, ranged from 15.9 ± 1.3 % to 33.5 ± 12 % and for pH 6.0 23.7 ± 1.5 % to 36.2 ± 12 %.The DOX-OCP exhibited an inhibitory effect on viability of osteosarcoma cell lines MG63, U2OS and HOS. In contrast, MC3T3-E1 cells (IC50 > 0.062 µM) displayed increased viability and proliferation from 3rd to 7th day. Testing of the DDS on ferroptotic markers (CHAC1, ACSL4 and PTGS2) showed that OCP-DOX does not induce ferroptotic cell death. Moreover, the evaluation of protein levels of cleaved PARP, by western blotting analysis, corroborated that apoptosis is the main pathway of programmed cell death in osteosarcoma cells induced by DOX-OCP.

Tissues and organ printing: An evolution of technology and materials

Since its beginnings, three-dimensional printing (3DP) technology has been successful because of ongoing advances in operating principles, the range of materials and cost-saving measures. However, the 3DP technological progressions in the biomedical sector have majorly taken place in the last decade after the evolution of novel 3DP systems, generally categorised as bioprinters and biomaterials to provide a replacement, transplantation or regeneration of the damaged organs and tissue constructs of the human body. There is now substantial scientific literature accessible to support the benefits of digital healthcare procedures with the help of bioprinters. It is of the highest significance to know the fundamental principles of the available printers and the compatibility of biomaterials as their feedstock, notwithstanding the huge potential of bioprinting systems to manufacture organs and other human body components. This paper provides a precise and helpful reading of the different categories of bioprinters, suitable biomaterials, numerical simulations and modelling and examples of much acknowledged clinical practices. The paper will also cite the prominent issues that still have not received desired solutions. Overall, the article will be of great use for all the professionals, scholars and engineers concerned with the 3DP, bioprinting and biomaterials.

Enwrapping Polydopamine on Doxorubicin-Loaded Lamellar Hydroxyapatite/Poly(lactic-co-glycolic acid) Composite Fibers for Inhibiting Bone Tumor Recurrence and Enhancing Bone Regeneration

Simultaneous prevention of bone tumor recurrence and promotion of repairing bone defects resulting from tumorectomy remain a challenge. Herein, we report a polydopamine (PDA)-coated composite scaffold consisting of doxorubicin (DOX)-loaded lamellar hydroxyapatite (LHAp) and poly(lactic-co-glycolic acid) (PLGA) in an attempt to reach dual functions of tumor inhibition and bone repair. The DOX was intercalated into LHAp, and the DOX-loaded LHAp was incorporated into PLGA solution to prepare a DOX-intercalated LHAp/PLGA (labeled as DH/PLGA) scaffold that was coated with PDA to obtain a PDA@DH/PLGA scaffold. The morphology, structure, wettability, mechanical properties, drug release, biocompatibility, and in vitro and in vivo bioactivities of the PDA@DH/PLGA scaffold were evaluated. It is found that PDA coating not only improves hydrophilicity and mechanical properties, but also leads to more sustainable drug release. More importantly, the PDA@DH/PLGA scaffold shows significantly inhibited growth of tumor cells initially and subsequent improved adhesion and proliferation of osteoblasts. In addition, the PDA coating improves the bioactivity of the DH/PLGA scaffold as suggested by the in vitro biomineralization. Further in vivo study demonstrates the improved bone growth around PDA@DH/PLGA over DH/PLGA after 20 days of drug release. The dual functional PDA@DH/PLGA scaffold shows great promise in the treatment of bone tumor.

Design strategies and evolving role of biomaterial assisted treatment of osteosarcoma

Osteosarcoma is the most commonly diagnosed form of bone cancer. It is characterized by a high risk of developing lung metastasis as the disease progresses. Standard treatment includes combination of surgical intervention, chemotherapy and radiotherapy. However, the non-specificity of potent chemotherapeutic agents often leads to major side effects. In this review, we discuss the role of various classes of biomaterials, including both organic as well as inorganic in realizing the local and systemic delivery of therapeutic agents like drugs, radioisotopes and even gene silencing agents to treat osteosarcoma. Biomaterial assisted unconventional therapies such as targeted therapy, nanotherapy, magnetic hyperthermia, gene therapy, photothermal and photodynamic therapies are also being explored. A wide variety of biomaterials including lipids, carbon-based materials, polymers, silica, bioactive glass, hydroxyapatite and metals are designed as delivery systems with the desired loading efficiency, release profile, and on-demand delivery. Among others, liposomal carriers have attracted a great deal of attention due to their capability to encapsulate both hydrophobic and hydrophilic drugs. Polymeric systems have high drug loading efficiency and stability and can even be tailored to achieve desired size and physiochemical properties. Carbon-based systems can also be seen as an upcoming class of therapeutics with great potential in treating different types of cancer. Inorganic materials like silica nanoparticles have high drug payload owing to their mesoporous structure. On the other hand, ceramic materials like bioactive glass and hydroxyapatite not only act as excellent delivery vectors but also participate in osteo-regeneration activity. These multifunctional biomaterials are also being investigated for their theranostic abilities to monitor cancer ablation. This review systematically discusses the vast landscape of biomaterials along with their challenges and respective opportunities for osteosarcoma therapy.