Localized delivery of metformin via 3D printed GelMA-Nanoclay hydrogel scaffold for enhanced treatment of diabetic bone defects.

Background: Diabetic bone defects present significant challenges for individuals with diabetes. While metformin has been explored for bone regeneration via local delivery, its application in treating diabetic bone defects remains under-explored. In this study, we aim to leverage 3D printing technology to fabricate a GelMA-Nanoclay hydrogel scaffold loaded with metformin specifically for this purpose. The objective is to assess whether the in situ release of metformin can effectively enhance osteogenesis, angiogenesis, and immunomodulation in the context of diabetic bone defects. Materials and methods: Utilizing 3D printing technology, we constructed a GelMA-Nanoclay-Metformin hydrogel scaffold with optimal physical properties and biocompatibility. The osteogenic, angiogenic, and immunomodulatory characteristics of the hydrogel scaffold were thoroughly investigated through both in vitro and in vivo experiments. Results: GelMA10%-Nanoclay8%-Metformin5mg/mL was selected as the bioink for 3D printing due to its favorable swelling rate, degradation rate, mechanical strength, and drug release rate. Through in vitro investigations, the hydrogel scaffold extract, enriched with metformin, demonstrated a substantial enhancement in the proliferation and migration of BMSCs within a high-glucose microenvironment. It effectively enhances osteogenesis, angiogenesis, and immunomodulation. In vivo experimental outcomes further underscored the efficacy of the metformin-loaded GelMA-Nanoclay hydrogel scaffold in promoting superior bone regeneration within diabetic bone defects. Conclusions: In conclusion, while previous studies have explored local delivery of metformin for bone regeneration, our research is pioneering in its application to diabetic bone defects using a 3D printed GelMA-Nanoclay hydrogel scaffold. This localized delivery approach demonstrates significant potential for enhancing bone regeneration in diabetic patients, offering a novel approach for treating diabetic bone defects. The translational potential of this article: Our study demonstrates, for the first time, the successful loading of the systemic antidiabetic drug metformin onto a hydrogel scaffold for localized delivery. This approach exhibits significant efficacy in mending diabetic bone defects, presenting a promising new avenue for the treatment of such conditions.

3D printed PLGA/MgO/PDA composite scaffold by low-temperature deposition manufacturing for bone tissue engineering applications.

Introduction: Bones are easily damaged. Biomimetic scaffolds are involved in tissue engineering. This study explored polydopamine (PDA)-coated poly lactic-co-glycolic acid (PLGA)-magnesium oxide (MgO) scaffold properties and its effects on bone marrow mesenchymal stem cells (BMSCs) osteogenic differentiation. Methods: PLGA/MgO scaffolds were prepared by low-temperature 3D printing technology and PDA coatings were prepared by immersion method. Scaffold structure was observed by scanning electron microscopy with an energy dispersive spectrometer (SEM-EDS), fourier transform infrared spectrometer (FTIR). Scaffold hydrophilicity, compressive/elastic modulus, and degradation rates were analyzed by water contact angle measurement, mechanical tests, and simulated-body fluid immersion. Rat BMSCs were cultured in scaffold extract. Cell activity on days 1, 3, and 7 was detected by MTT. Cells were induced by osteogenic differentiation, followed by evaluation of alkaline phosphatase (ALP) activity on days 3, 7, and 14 of induction and Osteocalcin, Osteocalcin, and Collagen I expressions. Results: The prepared PLGA/MgO scaffolds had dense microparticles. With the increase of MgO contents, the hydrophilicity was enhanced, scaffold degradation rate was accelerated, magnesium ion release rate and scaffold extract pH value were increased, and cytotoxicity was less when magnesium mass ratio was less than 10%. Compared with other scaffolds, compressive and elastic modulus of PLGA/MgO (10%) scaffolds were increased; BMSCs incubated with PLGA/MgO (10%) scaffold extract had higher ALP activity and Osteocalcin, Osteopontin, and Collagen I expressions. PDA coating was prepared in PLGA/MgO (10%) scaffolds and the mechanical properties were not affected. PLGA/MgO (10%)/PDA scaffolds had better hydrophilicity and biocompatibility and promoted BMSC osteogenic differentiation. Conclusion: Low-temperature 3D printing PLGA/MgO (10%)/PDA scaffolds had good hydrophilicity and biocompatibility, and were conducive to BMSC osteogenic differentiation.

Method for location of puncture point guided by digital mammography image.

The main purpose of this study was to develop a method that can optimize the algorithm for puncture point calculation, and therefore improve the accuracy of X-ray guided breast biopsy. The proposed method is: first, select two guiding points; then, use the guiding points to construct X-ray cone-beams, so the joining section of the cone-beams can be used to determine the puncture target point. The method was verified by a phantom emulation, in which the calculated target-points were all found within the central part of the target lesion, and far away from the boarder of the lesion (change the x-ray tube angle by 15° would only cause a slight deviation no more than 1.4 mm), the accuracy is enough to fulfill the needs of biopsy operation. This study also found out that, the shorter the distance between the guiding point and the center of the lesion's project, the nearer the calculated biopsy-point will be to the actual lesion center.

[The development of a guide device for stereotactic core-needle biopsy of the breast].

To meet the need of accurate positioning for biopsy gun in the breast biopsy operation, a new stereotactic biopsy guide device have been developed to adapt to the domestic mammary machine, which can help physician to carry out biopsy operation more accurately and effectively. The guide device has the motion model, measurement model and display model and can realize linear motion and display real-time displacement values in X, Y and Z direction. The experimental results showed that the guide device could be well fixed in the domestic mammary machine, and achieved good accuracy and repeatability in each direction. Depending on the displacement values, physician can change the space of biopsy gun accurately.