Cytoplasmic molecular delivery with shock waves: importance of impulse
about
Can ultrasound enable efficient intracellular uptake of molecules? A retrospective literature review and analysis.A non-invasive tissue-specific molecular delivery method of cancer gene therapy.Shockwaves increase T-cell proliferation and IL-2 expression through ATP release, P2X7 receptors, and FAK activation.Extracorporeal Acoustic Wave Therapy and Multiple Symmetric Lipomatosis.Characterization of a setup to test the impact of high-amplitude pressure waves on living cells.Photomechanical wave-driven delivery of siRNAs targeting intermediate filament proteins promotes functional recovery after spinal cord injury in ratsSelective gene transfection of individual cells in vitro with plasmonic nanobubbles.Biophysical response to pulsed laser microbeam-induced cell lysis and molecular delivery.Sonoporation from jetting cavitation bubblesAn experimental and theoretical analysis of ultrasound-induced permeabilization of cell membranes.Mechanisms of shock wave induced endothelial cell injury.Structural change in lipid bilayers and water penetration induced by shock waves: molecular dynamics simulationsDirect comparison of the spread area, contractility, and migration of balb/c 3T3 fibroblasts adhered to fibronectin- and RGD-modified substrataRapid release of tissue enzymes into blood after blast exposure: potential use as biological dosimeters.In vitro perforation of human epithelial carcinoma cell with antibody-conjugated biodegradable microspheres illuminated by a single 80 femtosecond near-infrared laser pulse.Computational Studies of the Effect of Shock Waves on the Binding of Model ComplexesDestruction of cancer cells by laser-induced shock waves: recent developments in experimental treatments and multiscale computer simulations.Role of cytoskeletal mechanics and cell membrane fluidity in the intracellular delivery of molecules mediated by laser-activated carbon nanoparticles.Delivery of ribosome-inactivating protein toxin into cancer cells with shock waves.Shock Wave-Induced Damage and Poration in Eukaryotic Cell Membranes.Potential applications of low-energy shock waves in functional urology.Mechanism of transformation in Mycobacteria using a novel shockwave assisted technique driven by in-situ generated oxyhydrogen.Ultrasound well below the intensity threshold of cavitation can promote efficient uptake of small drug model molecules in fibroblast cells.Periodontal gene transfer by ultrasound and nano/microbubbles.Effects of mild blast traumatic brain injury on cerebral vascular, histopathological and behavioral outcomes in rats.Increasing vaccine production using pulsed ultrasound waves.Differential effects on membrane permeability and viability of human keratinocyte cells undergoing very low intensity megasonic fields.Photoporation Using Carbon Nanotubes for Intracellular Delivery of Molecules and Its Relationship to Photoacoustic Pressure.Nanobubbles, cavitation, shock waves and traumatic brain injury.Damage in spherical cellular membrane generated by the shock waves: coarse-grained molecular dynamics simulation of lipid vesicle.
P2860
Q27006059-C6A38D5B-99A2-40A2-96E9-1E30876FE700Q30356798-4B7042FF-4D9E-443E-9EC8-673B939AD3C7Q30397791-450F3336-C0E0-4F3A-B522-5F1B8E6520E3Q30406833-49EAC312-7E99-4021-A83C-7768675DA423Q30444140-761FA8A3-3E7F-42ED-B479-349FDB9293FBQ30459711-25B8758D-3AB7-4571-840C-447BB7024A49Q30466731-2312093C-7A22-4833-AE50-BB3D7B42F3E4Q30474534-F97C1A37-3EF9-474E-9133-646B595F6773Q30499618-8E7CD61B-C51F-4619-A940-F3D28340BAA1Q30503526-4CA5E33D-C822-4655-8F4D-DCFACF0DCF09Q30858020-F28B0197-DE87-4ED8-977D-2B5EA7C585D2Q33247897-2DA8C7BC-53BA-4B2B-A292-66A7920F660AQ34187439-FCDA2473-7B29-43B5-ACE2-C18BD76454ADQ34228292-D0D333CA-633E-4225-BC8D-B29C581521CCQ34296994-1212957C-A17D-4A55-9D89-7D44D6F2C423Q34503093-033E9140-8201-4A8F-83FF-564E1230933DQ35166987-D9EFEE45-132B-4357-843A-AEAA99D703B9Q36408938-AFAFE97B-FDE9-4BFD-BBCA-28E949B67EA4Q36600242-87A54E1E-4FE9-423D-9ED6-D829F2BB4535Q38750699-DD9BF3B0-60CF-4822-AF6F-2F005208B3BEQ39428940-D73F2655-EF04-4E2F-98E9-B3793D7C4C95Q41448549-7D696F53-CCC8-4E55-B55A-7A48276EBE97Q42813260-07FA379A-BB84-4260-8CEA-D4F011F74D4FQ44376635-DD04A493-408E-44D6-BC23-44BED21E89E0Q46257288-B20CFA4B-65F0-4B9D-B118-720D55AAEB3DQ47134184-1C7CA448-760B-497B-9155-3B210A9E1204Q47139913-04FB24ED-B8C6-4C50-B62B-80CD29223B6CQ47283193-F29CF8CD-0D1A-4D0F-A46F-F3E29919AB96Q48418291-E3DA85DB-F6A3-49EE-BA9C-5083E9874691Q48455696-00FAAC3E-33AB-4B20-A026-0C5A55865A3B
P2860
Cytoplasmic molecular delivery with shock waves: importance of impulse
description
2000 nî lūn-bûn
@nan
2000 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年学术文章
@wuu
2000年学术文章
@zh-cn
2000年学术文章
@zh-hans
2000年学术文章
@zh-my
2000年学术文章
@zh-sg
2000年學術文章
@yue
name
Cytoplasmic molecular delivery with shock waves: importance of impulse
@ast
Cytoplasmic molecular delivery with shock waves: importance of impulse
@en
type
label
Cytoplasmic molecular delivery with shock waves: importance of impulse
@ast
Cytoplasmic molecular delivery with shock waves: importance of impulse
@en
prefLabel
Cytoplasmic molecular delivery with shock waves: importance of impulse
@ast
Cytoplasmic molecular delivery with shock waves: importance of impulse
@en
P2093
P2860
P1433
P1476
Cytoplasmic molecular delivery with shock waves: importance of impulse
@en
P2093
P2860
P304
P356
10.1016/S0006-3495(00)76432-0
P407
P577
2000-10-01T00:00:00Z