bjectiveTo evaluate the efficacy and limits of high intensity focused ultrasound (HIFU) in tumor treatment. MethodsThe references about the application of HIFU in tumor treatment in recent years were reviewed.ResultsHIFU caused localized hyperthermia at predictable depth in a few seconds to make the tumor tissue coagulative necrosis without injuring surrounding tissue. HIFU treatment had the advantages of low morbidity, noninvasiveness, avoidance of systemic side effects, and repeatitiveness. However, the utilization of HIFU sometimes could be limited by some factors such as imaging technique, organ movement, incomplete tissue destruction, etc.ConclusionHIFU is a promising noninvasive therapy for tumor treatment, though there are lots of problems to be further studied.
Objective To analyze the reason of tumor treatment-related premature ovarian failure, and to review the progress of ovarian functional reconstruction. Methods The l iterature about the effects of radiotherapy and chemotherapy on ovarian function and reconstruct ovarian function was reviewed, analysed and summarized. Results Radiotherapy and chemotherapy can both affect ovarian function. The ovarian function reconstruction included fresh ovarian transplantation and ovarian cryopreservation and transplantation. Frequent ovarian cryopreservation was procedure slow-freezing protocols and vitrification protocols. Some laboratory and animal models of ovarian function reconstruction have come to gratifying results. Conclusion Ovarian function reconstruction has a potential cl inical value and provides a promising future.
Tumor treatment fields (TTFields) can effectively inhibit the proliferation of tumor cells, but its mechanism remains exclusive. The destruction of cellular microtubule structure caused by TTFields through electric field force is considered to be the main reason for inhibiting tumor cell proliferation. However, the validity of this hypothesis still lacks exploration at the mesoscopic level. Therefore, in this study, we built force models for tubulins subjected to TTFields, based on the physical and electrical properties of tubulin molecules. We theoretically analyzed and simulated the dynamic effects of electric field force and torque on tubulin monomer polymerization, as well as the alignment and orientation of α/β tubulin heterodimer, respectively. Research results indicate that the interference of electric field force induced by TTFields on tubulin monomer is notably weaker than the inherent electrostatic binding force among tubulin monomers. Additionally, the electric field torque generated by the TTFileds on α/β tubulin dimers is also difficult to affect their random alignment. Therefore, at the mesoscale, our study affirms that TTFields are improbable to destabilize cellular microtubule structures via electric field dynamics effects. These results challenge the traditional view that TTFields destroy the microtubule structure of cells through TTFields electric field force, and proposes a new approach that should pay more attention to the "non-mechanical" effects of TTFields in the study of TTFields mechanism. This study can provide reliable theoretical basis and inspire new research directions for revealing the mesoscopic bioelectrical mechanism of TTFields.