RÉSUMÉ
Hepatocellular carcinoma (HCC) is a leading cause of cancer-related deaths globally. Early detection and treatment response monitoring of HCC are vital for improved outcomes. Traditional diagnostic methods rely on imaging, serum tumor markers, and invasive liver tissue biopsy. The advent of liquid biopsy has revolutionized cancer diagnostics and management. Liquid biopsy involves the detection and analysis of tumor-derived components, such as circulating tumor DNA, circulating tumor cells, and extracellular vesicles, in various body fluids. These components reflect tumor characteristics, genetic alterations, and functional changes, providing valuable information for HCC diagnosis and treatment response monitoring. Liquid biopsy offers several advantages, including its non-invasive nature, potential for repetitive sampling, and real-time monitoring of disease progression and treatment response. However, challenges remain, including the sensitivity of detection methods, and standardization. In this review, we discuss the methods, current status, and prospects of liquid biopsy for HCC, highlighting its potential as a valuable tool in HCC management.
RÉSUMÉ
BACKGROUND@#Bone growth factors, particularly bone morphogenic protein-2 (BMP-2), are required for effective treatment of significant bone loss. Despite the extensive development of bone substitutes, much remains to be desired for wider application in clinical settings. The currently available bone substitutes cannot sustain prolonged BMP-2 release and are inconvenient to use. In this study, we developed a ready-to-use bone substitute by sequential conjugation of BMP to a three-dimensional (3D) poly(L-lactide) (PLLA) scaffold using novel molecular adhesive materials that reduced the operation time and sustained prolonged BMP release. @*METHODS@#A 3D PLLA scaffold was printed and BMP-2 was conjugated with alginate-catechol and collagen. PLLA scaffolds were conjugated with different concentrations of BMP-2 and evaluated for bone regeneration in vitro and in vivo using a mouse calvarial model. The BMP-2 release kinetics were analyzed using ELISA. Histological analysis and microCT image analysis were performed to evaluate new bone formation. @*RESULTS@#The 3D structure of the PLLA scaffold had a pore size of 400 lm and grid thickness of 187–230 lm. BMP-2 was released in an initial burst, followed by a sustained release for 14 days. Released BMP-2 maintained osteoinductivity in vitro and in vivo. Micro-computed tomography and histological findings demonstrate that the PLLA scaffold conjugated with 2 lg/ml of BMP-2 induced optimal bone regeneration. @*CONCLUSION@#The 3D-printed PLLA scaffold conjugated with BMP-2 enhanced bone regeneration, demonstrating its potential as a novel bone substitute.