Implications of increased tumor blood flow and oxygenation caused by mild temperature hyperthermia in tumor treatment.
about
Spatial and Temporal Control of Hyperthermia Using Real Time Ultrasonic Thermal Strain Imaging with Motion Compensation, Phantom Study.Magnetic resonance thermometry at 7T for real-time monitoring and correction of ultrasound induced mild hyperthermia.Tumor-triggered drug release from calcium carbonate-encapsulated gold nanostars for near-infrared photodynamic/photothermal combination antitumor therapy.Non-Invasive Radiofrequency Field Treatment to Produce Hepatic Hyperthermia: Efficacy and Safety in SwineUse of Hydroxyapatite Doping to Enhance Responsiveness of Heat-Inducible Gene Switches to Focused UltrasoundModulation of the interstitial fluid pressure by high intensity focused ultrasound as a way to alter local fluid and solute movement: insights from a mathematical model.Short-time focused ultrasound hyperthermia enhances liposomal doxorubicin delivery and antitumor efficacy for brain metastasis of breast cancer.Ultrasound and microbubble guided drug delivery: mechanistic understanding and clinical implications.MRI-Guided Focused Ultrasound as a New Method of Drug Delivery.Controllable in vivo hyperthermia effect induced by pulsed high intensity focused ultrasound with low duty cycles.Noninvasive thermometry assisted by a dual-function ultrasound transducer for mild hyperthermia.Spatial and temporal-controlled tissue heating on a modified clinical ultrasound scanner for generating mild hyperthermia in tumorsUltrasound increases nanoparticle delivery by reducing intratumoral pressure and increasing transport in epithelial and epithelial-mesenchymal transition tumors.Rationale of hyperthermia for radio(chemo)therapy and immune responses in patients with bladder cancer: Biological concepts, clinical data, interdisciplinary treatment decisions and biological tumour imaging.RF-power and temperature data analysis of 444 patients with primary cervical cancer: deep hyperthermia using the Sigma-60 applicator is reproducible.Role of HIF-1α in response of tumors to a combination of hyperthermia and radiation in vivo.Changes in tumor hypoxia induced by mild temperature hyperthermia as assessed by dual-tracer immunohistochemistryConvergence of nanotechnology with radiation therapy-insights and implications for clinical translation.Fever and the thermal regulation of immunity: the immune system feels the heat.Change in expression of apoptosis genes after hyperthermia, chemotherapy and radiotherapy in human colon cancer transplanted into nude mice.Hyperthermia-enhanced indocyanine green delivery for laser-induced thermal ablation of carcinomas.Interplay Between HGF/SF-Met-Ras Signaling, Tumor Metabolism and Blood Flow as a Potential Target for Breast Cancer TherapyAnalysis of the distribution of magnetic fluid inside tumors by a giant magnetoresistance probe.A pilot study of the effects of mild systemic heating on human head and neck tumour xenografts: Analysis of tumour perfusion, interstitial fluid pressure, hypoxia and efficacy of radiation therapy.Adverse effect of mild temperature hyperthermia combined with hexamethylenetetramine compared to its effect combined with tirapazamine in the treatment of solid tumors.Computation of ultimate SAR amplification factors for radiofrequency hyperthermia in non-uniform body models: impact of frequency and tumour location.The effect of modulated electro-hyperthermia on the pharmacokinetic properties of nefopam in healthy volunteers: A randomised, single-dose, crossover open-label studyCetuximab delivery and antitumor effects are enhanced by mild hyperthermia in a xenograft mouse model of pancreatic cancer.Dissecting the role of hyperthermia in natural killer cell mediated anti-tumor responses.Perfusion measurement using DCE-MRI: implications for hyperthermia.Current status of antivascular therapy and targeted treatment in the clinic.The role of hyperthermia in optimizing tumor response to regional therapy.Magnetic nanoparticle hyperthermia enhancement of cisplatin chemotherapy cancer treatment.Gold Nanoantenna-Mediated Photothermal Drug Delivery from Thermosensitive Liposomes in Breast Cancer.Gold nanorod-mediated hyperthermia enhances the efficacy of HPMA copolymer-90Y conjugates in treatment of prostate tumors.Mild temperature hyperthermia and radiation therapy: role of tumour vascular thermotolerance and relevant physiological factorsThe effect of mild temperature hyperthermia on tumour hypoxia and blood perfusion: relevance for radiotherapy, vascular targeting and imaging.Pathophysiological and vascular characteristics of tumours and their importance for hyperthermia: heterogeneity is the key issue.Ultrasound-induced cell permeabilisation and hyperthermia: strategies for local delivery of compounds with intracellular mode of action.In vivo applications of magnetic nanoparticle hyperthermia.
P2860
Q27300981-497CB521-956A-473D-AE3C-38DE48F02538Q27304399-C71E8F3B-A2DE-44C4-A5E0-5B8E7C8D7EA9Q30356033-DD8E40F8-F1D7-462A-9D5A-FE5B0D5768ECQ30356280-C960BBCF-BAF5-4E37-8208-BBF9EE3306CBQ30362511-E2499362-C83E-483F-9F75-0DEEB83AE9F3Q30398463-83DDD584-27A9-4076-8440-D1BE8B842373Q30429246-A3F9BC88-6EE5-453C-8572-93C3EFDB2A72Q30429594-EA85196E-5013-4E59-A22D-9B67B0BB94C5Q30453855-5E574BF4-81B9-4F9D-9E03-F29FB71AF488Q30461135-838CB6AE-58D4-43C1-B125-80FA772CED7CQ30477607-BEB6E2D1-6D6B-4F7A-92CD-166096FD8F5AQ30477805-9586A7BE-D483-48D4-AF3E-C3D47818E712Q30514138-C7018199-14D7-40A2-9CE8-CCA4DC9F8C54Q31070048-F46A7EB0-7931-4897-AE78-7109AF00456DQ31140704-15C2E15F-88EE-4CD6-A1D2-4601AFF6F94FQ32174462-620C49A5-18FC-41FC-881C-C49BA861E2D7Q33341312-00870D00-03EF-4E61-B726-5F2B9C235A5EQ34263669-5AB83508-7636-448D-AF42-39CE9F5E995FQ34476418-19A1B742-6975-48EF-868C-F23DFD2563CBQ34606107-60622A0E-7851-4730-9313-EFD0BF50CA8FQ34883565-F55256DC-B455-45F6-9DEF-CA987D7EE310Q34971882-33093248-851D-4228-96CD-A6A1BB2C3266Q35060481-21A3C561-2346-44A0-B5C6-3DC793750F98Q36068704-057ADDFB-D1BA-406F-98B5-1286FF51B3BBQ36375347-5D8F51E4-7BF4-4FF4-952B-71CF9DA4716EQ36379737-626965DA-6376-4D80-B5DF-F3C02566BE0DQ36647178-F18DFC98-D5DE-482B-8260-490E87215F3FQ36801167-04B091DD-117B-46CD-9D0E-DA74E9E1F854Q37063492-AFF658A8-5F76-44A8-BFA4-E9E302E2EFDCQ37063506-19245F56-C409-40A3-B22C-5EE65A2D052CQ37063510-2EAAC24B-A944-4406-A53E-A144F8FA3E28Q37130250-47B56F20-C910-4B4D-AAEE-64D68DCBD574Q37200444-44ECF41E-99A9-4E6A-9F14-F9F2C4011BEBQ37262447-5CB623E4-4803-4AD3-B98D-108BE58381B8Q37635484-0992FA77-3A18-4FA0-B99E-1E2A745EE6D0Q37704374-691CB056-0FCE-4EF1-9295-364221B6B85EQ37709394-3FDD188C-F9AA-4EA5-B8A2-7A41A6B58A4CQ37719535-3B5C98EE-2A29-4C99-8DD2-984706C49F47Q38012536-B4875393-AE2C-42DA-A7CC-0EE4AF7228E2Q38161993-619CB4A3-E2A7-4DC1-A6FE-F8255A321B08
P2860
Implications of increased tumor blood flow and oxygenation caused by mild temperature hyperthermia in tumor treatment.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Implications of increased tumo ...... perthermia in tumor treatment.
@ast
Implications of increased tumo ...... perthermia in tumor treatment.
@en
type
label
Implications of increased tumo ...... perthermia in tumor treatment.
@ast
Implications of increased tumo ...... perthermia in tumor treatment.
@en
prefLabel
Implications of increased tumo ...... perthermia in tumor treatment.
@ast
Implications of increased tumo ...... perthermia in tumor treatment.
@en
P2093
P2860
P1476
Implications of increased tumo ...... perthermia in tumor treatment.
@en
P2093
P2860
P304
P356
10.1080/02656730500204487
P577
2005-12-01T00:00:00Z