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Beilstein J. Nanotechnol. 2020, 11, 180–212, doi:10.3762/bjnano.11.15
Figure 1: Schematic description of in vitro PDT processes using photosensitizer (PS) encapsulated in a block ...
Figure 2: Chemical structures of four molecular photosensitizers commonly used: a) pheophorbide a; b) chlorin...
Figure 3: Schematic representation of the strategies used for delivery of photosensitizers using block copoly...
Figure 4: Chemical structures of the main blocks commonly described in recent literature.
Figure 5: a) Light-responsive self-immolative polymers. Adapted with permission from [70], copyright 2018 America...
Figure 6: Block copolymers used as nanocarriers for overcoming hypoxia; a) adapted with permission from [104], cop...
Figure 7: Schematic representation of the interplay between polymer structure, physicochemical characteristic...
Figure 8: Representative snapshots describing the endocytosis pathway for spherocylindrical nanoparticles. Re...
Figure 9: Field flow fractograms of PEO(2400)-b-PDLLA(2000) and PEO(3100)-b-PS(2300) micelles. The multi-angl...
Figure 10: Idealized docking of 5,10,15,20-tetrakis(3-hydroxyphenyl)chlorin (m-THPC, shown as van der Waals su...
Figure 11: Modulation of PDT efficiency through introduction of bulky substituents on the PS, which inhibit ag...
Figure 12: Use of Hansen solubility parameters to optimize polymeric nanovectors.
Figure 13: Types of pathways of block copolymer micelle–cell membrane interactions. Reprinted with permission ...
Figure 14: Schematic view of photodynamic therapy (PDT) strategies with polymeric nanovectors targeting subcel...
Figure 15: Illustration of the PTX@PAsp-g-(PEG-ICG) ER-targeting process and mechanism of cell death. PTX@PAsp-...