about
Membrane binding by tBid initiates an ordered series of events culminating in membrane permeabilization by BaxA porphodimethene chemical inhibitor of uroporphyrinogen decarboxylaseEmerging applications of porphyrins in photomedicineHexamodal imaging with porphyrin-phospholipid-coated upconversion nanoparticles.Porphyrin-phospholipid liposomes permeabilized by near-infrared light.Bcl-XL inhibits membrane permeabilization by competing with Bax.Non-invasive multimodal functional imaging of the intestine with frozen micellar naphthalocyaninesSize-tunable and monodisperse Tm³⁺/Gd³⁺-doped hexagonal NaYbF₄ nanoparticles with engineered efficient near infrared-to-near infrared upconversion for in vivo imaging.Nanomedical engineering: shaping future nanomedicines.Functionalization of cobalt porphyrin-phospholipid bilayers with his-tagged ligands and antigens.Porphyrin-phospholipid liposomes with tunable leakiness.Investigating the specific uptake of EGF-conjugated nanoparticles in lung cancer cells using fluorescence imaging.Surfactant-stripped naphthalocyanines for multimodal tumor theranostics with upconversion guidance cream.Ablation of hypoxic tumors with dose-equivalent photothermal, but not photodynamic, therapy using a nanostructured porphyrin assembly.Directed vaccination against pneumococcal disease.Activatable photosensitizers for imaging and therapy.Lipoprotein-inspired nanoparticles for cancer theranosticsDual-color photoacoustic lymph node imaging using nanoformulated naphthalocyanines.Porphyrin shell microbubbles with intrinsic ultrasound and photoacoustic properties.Efficient cytosolic delivery of siRNA using HDL-mimicking nanoparticles.Cytosolic delivery of LDL nanoparticle cargo using photochemical internalization.HDL-mimicking peptide-lipid nanoparticles with improved tumor targeting.Biomimetic nanocarrier for direct cytosolic drug delivery.FRET quenching of photosensitizer singlet oxygen generation.A tumor mRNA-triggered photodynamic molecular beacon based on oligonucleotide hairpin control of singlet oxygen production.Porphyrins and phthalocyanines for theranostics.Pd-porphyrin-cross-linked implantable hydrogels with oxygen-responsive phosphorescence.Optically controlled pore formation in self-sealing giant porphyrin vesicles.A quenched binuclear ruthenium(II) dimer activated by another photosensitizer.Intrabilayer 64Cu Labeling of Photoactivatable, Doxorubicin-Loaded Stealth Liposomes.Multicolor Liposome Mixtures for Selective and Selectable Cargo Release.Multifunctional Liposomes for Image-Guided Intratumoral Chemo-Phototherapy.Implantable Tin Porphyrin-PEG Hydrogels with pH-Responsive Fluorescence.Methylene blue microbubbles as a model dual-modality contrast agent for ultrasound and activatable photoacoustic imaging.Self-assembled porphyrin nanodiscs with structure-dependent activation for phototherapy and photodiagnostic applications.Assessing Photosensitizer Targeting Using Meso-Tetra(Carboxyphenyl) Porphyrin.Short Drug-Light Intervals Improve Liposomal Chemophototherapy in Mice Bearing MIA PaCa-2 Xenografts.Tumor Ablation and Therapeutic Immunity Induction by an Injectable Peptide Hydrogel.Recent Progress in Upconversion Photodynamic Therapy.Enzymatic regioselection for the synthesis and biodegradation of porphysome nanovesicles
P50
Q24323186-BA4CA67B-AFF0-4318-AA3C-ECA93535D32AQ28540127-644CC326-EBB2-402B-9550-3FDAE14C6DCEQ30355707-DC86E87C-3A55-48EB-B5DF-E3ACA644E5C9Q30388464-C2F0BA8B-E098-4DDC-9022-0F1E2B0551D0Q30576228-1C567437-8793-4FAE-AFF0-4F6A959E7D36Q33343021-11095DA2-226E-4E47-A92B-1F5852AD8637Q34034249-E8C59DF9-4E33-4B74-BDEB-5B7A217A3D7DQ34109525-5AE90B92-A5F9-46A9-8820-D30A7FC2D98BQ35019550-CDDE807C-8E3D-40FD-8EFC-27E7F18B519DQ35535265-533C2B67-86BF-4C14-9C08-F6EF76456018Q35844575-2C66EC1E-45A8-4A0D-BE3D-905A49D99051Q35979595-134C2962-9B8A-499E-87C1-D124A3BB352DQ36293522-FCA24139-1A31-46A6-A4D5-737E4CCDC61AQ36723250-CF190406-5B1C-47EA-94CA-D5CAFE217D73Q37040681-F37004FF-52D4-45E8-A359-AFAED1F406AEQ37682213-3175905A-7288-4354-BF54-AB8BA96BCC80Q37873918-05EA1256-73E5-4749-AE0D-DA77283E9DC3Q38959903-5536C581-E719-4CEA-B073-E1121D54D3D9Q39308999-0D133681-7EA4-47AA-A8C0-6404C3882294Q39582387-F98B15C6-2294-4F6D-B9DF-7CFF7A41809FQ39587660-AD3D93F4-E9BF-462B-A6B7-266875C232DFQ39767578-999A40D1-4DF3-4B90-B01D-BBC987C1452AQ39781640-4185E51C-27E7-4133-966F-51F358DA068DQ39808034-3A983506-3A36-458B-8506-DF76BB4EAC4BQ39965932-4EC3A7D8-0B2D-4CFF-8A79-827D4634DCF0Q42128018-93EA3D61-9AFF-49F4-BD5E-6315769EA4A5Q42142237-21F15187-2D81-4302-8E6E-268CD3502F1FQ43514933-497BB24B-19F6-4D8D-82AD-E9739471644EQ46932510-C01DBCDD-457A-435D-881F-264823EECD0CQ47294309-E96F7813-D50D-424E-B702-69E33A823D37Q48134517-9AECD4B8-BCFA-47E9-9E6E-10897031B3A6Q48145022-E81F56B7-F791-436F-8758-C43FA5A7E487Q48289192-D67F1DBC-8876-4865-B8D5-5BB86504E478Q50226710-813D275B-CC1C-4FAA-8D78-A3ED007C6F1FQ51754315-A0873ECD-2E79-4294-92C2-6F7203E36488Q52591899-FE97C305-4661-4712-982F-0735FEBAE573Q52613532-6CD9D64F-AF40-4F6D-9B13-5DD213395BEDQ52646866-8EBEEC23-BC6E-4126-A3E5-B31DC8FCEE1AQ55024185-A30E8179-DBFF-441A-96C5-D6524309381DQ57184399-BC982B11-9113-4935-AF11-D04693C55A73
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Jonathan F Lovell
@nl
Jonathan F Lovell
@sl
Jonathan F. Lovell
@en
Jonathan F. Lovell
@es
type
label
Jonathan F Lovell
@nl
Jonathan F Lovell
@sl
Jonathan F. Lovell
@en
Jonathan F. Lovell
@es
prefLabel
Jonathan F Lovell
@nl
Jonathan F Lovell
@sl
Jonathan F. Lovell
@en
Jonathan F. Lovell
@es
P106
P1153
35364781500
P21
P31
P496
0000-0002-9052-884X