Folic acid decorated metal-organic frameworks loaded with doxorubicin for tumor-targeted chemotherapy of osteosarcoma.

Effective cancer therapy usually requires the assistance of well-designed drug carriers. In order to increase the drug accumulation to tumor tissue as well as to reduce the side effects of drug carriers, the hybrid drug delivery system (DDS) was developed by integrating folic acid (FA) and a metal-organic framework (MOF). The anticancer drug doxorubicin (DOX) was preloaded into the MOF nanoparticles during the synthesis process of the MOF nanoparticles. After surface modification with FA, the resulting FA/MOF/DOX nanoparticles were capable of serving as a biocompatible osteosarcoma targeting a DDS to enhance the chemotherapy of osteosarcoma. The dynamic light scattering method revealed that the obtained FA/MOF/DOX nanoparticles were particles with a size around 100 nm. Moreover, FA/MOF/DOX nanoparticles could enhance the delivery efficacy of DOX into MG63 (human osteosarcoma) cells as compared to FA free nanoparticles (MOF/DOX), in which a folate receptor (FR) might be involved. It was worth mentioning that in vitro [methylthio tetrazole (MTT) study in the MG63 cells] and in vivo (anticancer study in the MG63 xenograft model) assays both revealed that FA/MOF/DOX nanoparticles possessed stronger anticancer capability than free DOX or MOF/DOX nanoparticles.

Preparation and Assessment of an Individualized Navigation Template for Lower Cervical Anterior Transpedicular Screw Insertion Using a Three-Dimensional Printing Technique.

STUDY DESIGN: Prospective trial. OBJECTIVE: To establish an individualized navigation template for safe and accurate insertion of lower cervical anterior transpedicular screw (ATPS) based on a three-dimensional (3D) printing technique. SUMMARY OF BACKGROUND DATA: Conventional screw insertion manually under fluoroscopy easily leading to deviation of ATPS screw channel, cervical instrumentation procedures demand the need for a precise technique for screw placement. METHODS: Twenty adult cervical spine specimens (10 men and 10 women, with a mean age of 50.29 ±â€Š6.98) were selected for computed tomography pre- and postoperatively. A 3D lower cervical spine model was reconstructed using Mimics software to measure the screw-related parameters and generate a reverse template with optimal screw channel as well as a prototype using 3D printing. Assisted by the navigation template, bilateral ATPS were inserted into the cadavers. RESULTS: The mean outer width and height of pedicle were 5.31 ±â€Š1.23 and 6.78 ±â€Š1.10 mm, respectively. The average length, sagittal, and axial angles of the optimal screw channel obtained through the optimal entry point were 36.34 ±â€Š4.39 mm, 40.67°â€Š±â€Š5.10°, and 93.7°â€Š±â€Š7.96°, respectively. The adjustable safe ranges of sagittal and axial angles were 3.89°â€Š±â€Š1.13° and 5.64°â€Š±â€Š0.97°, respectively. The axial and sagittal accuracies of the 200 screws were 99.5% and 97%, respectively. The average deviations of the actual entry point and the preset opening in the X, Y, and Z axes were 0.39 ±â€Š0.43, 0.21 ±â€Š0.41, and 0.29 ±â€Š0.14 mm, respectively (P > 0.05). CONCLUSION: An individualized ATPS navigation template was developed using Mimics software and 3D printing prototyping, based on computed tomography, for highly accurate screw insertion. LEVEL OF EVIDENCE: 4.