Our study showed that quantitative radiomic imaging features of breast tumor extracted from digital mammograms are associated with breast cancer subtypes. Future larger studies are needed to further evaluate the findings.
As the skull induces strong aberrations in phase and amplitude during transcranial treatment of brain surgery, high-intensity focused ultrasound suffers degradation in beam shape and deposits significant heat in the skull which may cause thermal damage to the bone and surrounding tissue. The goal of this study is to optimize the transcranial pressure and thermal fields to reduce thermal damage to the skull and simultaneously concentrate more energy in the focal region and make its size controllable during transcranial brain tumor treatment by modulating the excitation signals of the transducer array (including the phase and amplitude) and superposing the signals used to reduce peak pressure in the skull. A 3D numerical model was developed based on the reconstructed images from high-resolution CT scans of a human skull and a 64-element phased array to simulate acoustic propagation and thermal behavior calculated by the finite-difference time domain method. The simulation showed that more energy was focused at the setting target with little temperature elevation in the skull after correcting phase and amplitude and reducing peak pressure in the skull; through modulating the input intensity of arrays, the volume of focal regions located off-axis could be made equal to the volume achieved with on-axis focusing.
Cancer treatments with conventional approaches often result in limited clinical outcomes due to inefficient therapeutic efficacy and cumulative toxicity against normal tissue. Recently, most research has focused on combined therapeutic studies by functional carriers. In this study, functional nanoparticles (FNPs) are assembled in a layer‐by‐layer fashion. FNPs are loaded with two drugs (10‐hydroxycamptothecin and apoptin plasmid) with dual hepatocellular carcinoma‐targeting ligands (lactobionic acid and biotin) on the surface. Cytotoxicity studies and acute toxicity experiments in BAL b/c mice show that blank FNPs demonstrate good biocompatibility. Flow cytometry analysis and cytotoxicity studies demonstrate that the dual‐targeting FNPs allow for better specificity and selectivity of the tumor mass. FNPs can escape from endosomal/lysosomal compartments effectively, as is demonstrated using the Cell Navigator lysosome staining kit. When the drugs are released into the cytosol, the nuclear localization signal can enhance the nuclear delivery of 10‐hydroxycamptothecin loaded carriers and apoptin plasmids, as is demonstrated by confocal laser scanning microscopy. In vivo experiments show the circulation time and tissue distribution of FNPs, which greatly improve the therapeutic efficacy of BAL b/c nude mice with subcutaneous tumors. Taken together, the results suggest that FNPs are a promising candidate for hepatocellular carcinoma therapy.
Transcranial focused ultrasound (tFUS) has great potential in brain imaging and therapy. However, the structural and acoustic differences of the skull will cause a large number of technical problems in the application of tFUS, such as low focus energy, focal shift, and defocusing. To have a comprehensive understanding of the skull effect on tFUS, this study investigated the effects of the structural parameters (thickness, radius of curvature, and distance from the transducer) and acoustic parameters (density, acoustic speed, and absorption coefficient) of the skull model on tFUS based on acrylic plates and two simulation methods (self-programming and COMSOL). For structural parameters, our research shows that as the three factors increase the unit distance, the attenuation caused from large to small is the thickness (0.357 dB/mm), the distance to transducer (0.048 dB/mm), and the radius of curvature (0.027 dB/mm). For acoustic parameters, the attenuation caused by density (0.024 dB/30 kg/m3) and acoustic speed (0.021 dB/30 m/s) are basically the same. Additionally, as the absorption coefficient increases, the focus acoustic pressure decays exponentially. The thickness of the structural parameters and the absorption coefficient of the acoustic parameters are the most important factors leading to the attenuation of tFUS. The experimental and simulation trends are highly consistent. This work contributes to the comprehensive and quantitative understanding of how the skull influences tFUS, which further enhances the application of tFUS in neuromodulation research and treatment.
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