Treating glioblastoma multiforme with selective high-dose liposomal doxorubicin chemotherapy induced by repeated focused ultrasound

Feng-Yi Yang1, Ming-Che Teng1, Maggie Lu2, Hsiang-Fa Liang2, Yan-Ru Lee1, Chueh-Chuan Yen3, Muh-Lii Liang4,5, Tai-Tong Wong51Department of Biomedical Imaging and Radiological Sciences, National Yang-Ming University, Taipei, 2Drug Delivery Laboratory, Biomedical Technology and Device Research Laboratories, Industrial Technology Research Institute, Hsinchu, 3Division of Hematology and Oncology, Department of Medicine, Taipei Veterans General Hospital and National Yang-Ming University School of Medicine, Taipei, 4Institute of Clinical Medicine, National Yang-Ming University School of Medicine, Taipei, 5Department of Neurosurgery, Neurological Institute, Taipei Veterans General Hospital, Taipei, TaiwanBackground: High-dose tissue-specific delivery of therapeutic agents would be a valuable clinical strategy. We have previously shown that repeated transcranial focused ultrasound is able to increase the delivery of Evans blue significantly into brain tissue. The present study shows that repeated pulsed high-intensity focused ultrasound (HIFU) can be used to deliver high-dose atherosclerotic plaque-specific peptide-1 (AP-1)-conjugated liposomes selectively to brain tumors.Methods: Firefly luciferase (Fluc)-labeled human GBM8401 glioma cells were implanted into NOD-scid mice. AP-1-conjugated liposomal doxorubicin or liposomal doxorubicin alone was administered followed by pulsed HIFU and the doxorubicin concentration in the treated brains quantified by fluorometer. Growth of the labeled glioma cells was monitored through noninvasive bioluminescence imaging and finally the brain tissue was histologically examined after sacrifice.Results: Compared with the control group, the animals treated with 5 mg/kg injections of AP-1 liposomal doxorubicin or untargeted liposomal doxorubicin followed by repeated pulsed HIFU not only showed significantly enhanced accumulation of drug at the sonicated tumor site but also a significantly elevated tumor-to-normal brain drug ratio (P < 0.001). Combining repeated pulsed HIFU with AP-1 liposomal doxorubicin or untargeted liposomal doxorubicin has similar antitumor effects.Conclusion: This study demonstrates that targeted or untargeted liposomal doxorubicin, followed by repeated pulsed HIFU, is a promising high-dose chemotherapy method that allows the desired brain tumor region to be targeted specifically.Keywords: repeated focused ultrasound, interleukin-4 receptor, blood-brain barrier, brain tumor, target drug deliver

Roadmap on energy harvesting materials

Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere

Sintering Behaviors, Microstructure, and Microwave Dielectric Properties of CaTiO3–LaAlO3 Ceramics Using CuO/B2O3 Additions

The effect of CuO/B2O3 additions on the sintering behaviors, microstructures, and microwave dielectric properties of 0.95LaAlO3–0.05CaTiO3 ceramics is investigated. It is found that the sintering temperatures are lowered efficiently from 1600 °C to 1350 °C, as 1 wt % CuO, 1 wt % B2O3, and 0.5 wt % CuO +0.5 wt % B2O3 are used as the sintering aids due to the appearance of the liquid phase sintering. The microwave dielectric properties of 0.95LaAlO3–0.05CaTiO3 ceramics with the sintering aid additions are strongly related to the densification and the microstructure of the sintered ceramics. At the sintering temperature of 1300 °C, the 0.95LaAlO3–0.05CaTiO3 ceramic with 0.5 wt % CuO + 0.5 wt % B2O3 addition shows the best dielectric properties, including a dielectric constant (εr) of 21, approximate quality factor (Q × f) of 22,500 GHz, and a temperature coefficient of the resonant frequency (τf) of −3 ppm/°C

RAS Mediates BET Inhibitor-Endued Repression of Lymphoma Migration and Prognosticates a Novel Proteomics-Based Subgroup of DLBCL through Its Negative Regulator IQGAP3

Phenotypic heterogeneity and molecular diversity make diffuse large B-cell lymphoma (DLBCL) a challenging disease. We recently illustrated that amoeboid movement plays an indispensable role in DLBCL dissemination and inadvertently identified that the inhibitor of bromodomain and extra-terminal (BET) proteins JQ1 could repress DLBCL migration. To explore further, we dissected the impacts of BET inhibition in DLBCL. We found that JQ1 abrogated amoeboid movement of DLBCL cells through both restraining RAS signaling and suppressing MYC-mediated RhoA activity. We also demonstrated that BET inhibition resulted in the upregulation of a GTPase regulatory protein, the IQ motif containing GTPase activating protein 3 (IQGAP3). IQGAP3 similarly exhibited an inhibitory effect on RAS activity in DLBCL cells. Through barcoded mRNA/protein profiling in clinical samples, we identified a specific subgroup of DLBCL tumors with enhanced phosphatidylinositol-3-kinase (PI3K) activity, which led to an inferior survival in these patients. Strikingly, a lower IQGAP3 expression level further portended those with PI3K-activated DLBCL a very dismal outcome. The inhibition of BET and PI3K signaling activity led to effective suppression of DLBCL dissemination in vivo. Our study provides an important insight into the ongoing efforts of targeting BET proteins as a therapeutic approach for DLBCL

Roadmap on energy harvesting materials

Funder: Fundação para a Ciência e TecnologiaFunder: BIDEKO ProjectFunder: MCIN/AEIFunder: Spanish State Research Agency (AEI)Funder: Basic Science Research ProgramFunder: Ministry of Education; doi: http://dx.doi.org/10.13039/501100002701Funder: Swedish Knowledge FoundationFunder: University of Calgary; doi: http://dx.doi.org/10.13039/100008459Funder: National Renewable Energy Laboratory; doi: http://dx.doi.org/10.13039/100006233Funder: Fonds de recherche du Québec – Nature et technologies; doi: http://dx.doi.org/10.13039/501100003151Funder: Canada Research Chairs programFunder: EUFunder: National Research Foundation of Korea; doi: http://dx.doi.org/10.13039/501100003725Funder: NRFFunder: Priority Research Centers ProgramFunder: European regional development fund (ERDF)Funder: European Research Council (ERC)Funder: ERCFunder: Alliance for Sustainable Energy, LLCFunder: MIURFunder: Italian MinistryFunder: the Cardiff University, Engineering and Physical Sciences Research CouncilFunder: JST Mirai ProgramFunder: Agence Nationale de la Recherche (ANR)Funder: A*STARFunder: JSTFunder: PRESTOFunder: Aerospace ProgrammeFunder: EBFunder: U.S. Department of Commerce, National Institute of Standards and TechnologyFunder: Laboratory-Directed Research and Development (LDRD)Funder: Sandia, LLCFunder: the Office of Science, Office of Basic Energy SciencesFunder: United States GovernmentFunder: Honeywell International Inc.Funder: The Leverhulme TrustFunder: Royal Academy of Engineering; doi: http://dx.doi.org/10.13039/501100000287Funder: Office of the Chief Science Adviser for National SecurityFunder: Henry Samueli School of Engineering & Applied ScienceFunder: Department of Bioengineering at the University of California, Los AngelesFunder: CRESTFunder: Beijing Forestry University; doi: http://dx.doi.org/10.13039/501100012138Funder: Japan Science and Technology Agency (JST)Funder: the Australian Research Council, QUTFunder: Center for Hierarchical Materials DesignFunder: Austrian Christian Doppler Laboratory for ThermoelectricityFunder: HBIS-UQ Innovation Centre for Sustainable SteelAbstract Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere.</jats:p

Roadmap on energy harvesting materials

Funder: Fundação para a Ciência e TecnologiaFunder: BIDEKO ProjectFunder: MCIN/AEIFunder: Spanish State Research Agency (AEI)Funder: Basic Science Research ProgramFunder: Ministry of Education; doi: http://dx.doi.org/10.13039/501100002701Funder: Swedish Knowledge FoundationFunder: University of Calgary; doi: http://dx.doi.org/10.13039/100008459Funder: National Renewable Energy Laboratory; doi: http://dx.doi.org/10.13039/100006233Funder: Fonds de recherche du Québec – Nature et technologies; doi: http://dx.doi.org/10.13039/501100003151Funder: Canada Research Chairs programFunder: EUFunder: National Research Foundation of Korea; doi: http://dx.doi.org/10.13039/501100003725Funder: NRFFunder: Priority Research Centers ProgramFunder: European regional development fund (ERDF)Funder: European Research Council (ERC)Funder: ERCFunder: Alliance for Sustainable Energy, LLCFunder: MIURFunder: Italian MinistryFunder: the Cardiff University, Engineering and Physical Sciences Research CouncilFunder: JST Mirai ProgramFunder: Agence Nationale de la Recherche (ANR)Funder: A*STARFunder: JSTFunder: PRESTOFunder: Aerospace ProgrammeFunder: EBFunder: U.S. Department of Commerce, National Institute of Standards and TechnologyFunder: Laboratory-Directed Research and Development (LDRD)Funder: Sandia, LLCFunder: the Office of Science, Office of Basic Energy SciencesFunder: United States GovernmentFunder: Honeywell International Inc.Funder: The Leverhulme TrustFunder: Royal Academy of Engineering; doi: http://dx.doi.org/10.13039/501100000287Funder: Office of the Chief Science Adviser for National SecurityFunder: Henry Samueli School of Engineering & Applied ScienceFunder: Department of Bioengineering at the University of California, Los AngelesFunder: CRESTFunder: Beijing Forestry University; doi: http://dx.doi.org/10.13039/501100012138Funder: Japan Science and Technology Agency (JST)Funder: the Australian Research Council, QUTFunder: Center for Hierarchical Materials DesignFunder: Austrian Christian Doppler Laboratory for ThermoelectricityFunder: HBIS-UQ Innovation Centre for Sustainable SteelAmbient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere