Branched and Dendritic Polymer Architectures: Functional Nanomaterials for Therapeutic Delivery

Cook, Alexander; Perrier, Sébastien

doi:10.1002/adfm.201901001

Cited by 117 publications

(96 citation statements)

References 197 publications

(170 reference statements)

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“…[6][7][8] However, the discoveries of anionic 9 and cationic 10 polymerisation as well as controlled radical polymerisation methodologies including atom transfer radical polymerisation (ATRP), 11,12 reversible addition-fragmentation chain-transfer (RAFT) polymerisation 13 and nitroxide mediated polymerisation (NMP) 14 have enabled the synthesis of well-dened macromolecules with controlled molecular weight, architecture, end-group delity and dispersity. [15][16][17][18][19][20][21][22][23] In fact, the high end-group delity and the controlled nature of the polymerisation is typically conrmed by low dispersity values and as such dispersities in the range of Đ z 1.01-1.20 are routinely targeted. [24][25][26][27][28][29][30][31][32] Conversely, broader molecular weight distributions (Đ > 1.4) are oen considered to be a sign of uncontrolled or "failed" polymerisation and necessitate additional optimisation to reduce the dispersity.…”

Section: Introductionmentioning

confidence: 99%

Tailoring polymer dispersity and shape of molecular weight distributions: methods and applications

et al. 2019

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Section: Introductionmentioning

confidence: 99%

Tailoring polymer dispersity and shape of molecular weight distributions: methods and applications

et al. 2019

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“…Hyperbranched polymers were chosen as the initial architecture of materials to investigate based on their known potential for tumor targeting and uptake in vivo. [61,62] Further to this, larger architectures were proposed, namely star, high molecular weight linear and core-crosslinked micellar polymers. A combination of nondegradable hyperbranched and redoxresponsive architectures were synthesized through parallel synthetic routes in order to access a wide size range of materials from 5 to 60 nm with multiple stimuli-responsive mechanisms of degradation, depicted in Scheme 1.…”

Section: Introductionmentioning

confidence: 99%

Effects of Polymer 3D Architecture, Size, and Chemistry on Biological Transport and Drug Delivery In Vitro and in Orthotopic Triple Negative Breast Cancer Models

Pearce

Anane-Adjei

Cavanagh

et al. 2020

Adv Healthcare Materials

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The size, shape, and underlying chemistries of drug delivery particles are key parameters which govern their ultimate performance in vivo. Responsive particles are desirable for triggered drug delivery, achievable through architecture change and biodegradation to control in vivo fate. Here, polymeric materials are synthesized with linear, hyperbranched, star, and micellar-like architectures based on 2-hydroxypropyl methacrylamide (HPMA), and the effects of 3D architecture and redox-responsive biodegradation on biological transport are investigated. Variations in "stealth" behavior between the materials are quantified in vitro and in vivo, whereby reduction-responsive hyperbranched polymers most successfully avoid accumulation within the liver, and none of the materials target the spleen or lungs. Functionalization of selected architectures with doxorubicin (DOX) demonstrates enhanced efficacy over the free drug in 2D and 3D in vitro models, and enhanced efficacy in vivo in a highly aggressive orthotopic breast cancer model when dosed over schedules accounting for the biodistribution of the carriers. These data show it is possible to direct materials of the same chemistries into different cellular and physiological regions via modulation of their 3D architectures, and thus the work overall provides valuable new insight into how nanoparticle architecture and programmed degradation can be tailored to elicit specific biological responses for drug delivery.

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“…Compared with linear ones, branched polymers have a high branched topological structure, a high density of functional groups, a nanoscale size and internal cavities 29 . Especially, functional branched polymers can be prepared via one-pot synthesis of RAFT polymerization, and their structures and functions can be optimized via selecting and manipulating cross-linking agents and monomers, so they have great application potential as multifunctional polymer delivery systems 30 . Additionally, depending on the choice of tumor microenvironment-responsive cross-linking agents and functionalized side chain groups, the stimuli-responsive branched polymers-based nanoscale drug delivery systems can be achieved with strong EPR effect for negatively-targeting tumors and good biocompatibility.…”

Section: Introductionmentioning

confidence: 99%

Cathepsin B-responsive and gadolinium-labeled branched glycopolymer-PTX conjugate-derived nanotheranostics for cancer treatment

Cai

Xiang

Zeng

et al. 2021

Acta Pharmaceutica Sinica B

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Multi-modal therapeutics are emerging for simultaneous diagnosis and treatment of cancer. Polymeric carriers are often employed for loading multiple drugs due to their versatility and controlled release of these drugs in response to a tumor specific microenvironment. A theranostic nanomedicine was designed and prepared by complexing a small gadolinium chelate, conjugating a chemotherapeutic drug PTX through a cathepsin B-responsive linker and covalently bonding a fluorescent probe pheophorbide a (Ppa) with a branched glycopolymer. The branched prodrug-based nanosystem was degradable in the tumor microenvironment with overexpressed cathepsin B, and PTX was simultaneously released to exert its therapeutic effect. The theranostic nanomedicine, branched glycopolymer-PTX-DOTA-Gd, had an extended circulation time, enhanced accumulation in tumors, and excellent biocompatibility with significantly reduced gadolinium ion (Gd 3+ ) retention after 96 h post-injection. Enhanced imaging contrast up to 24 h post-injection and excellent antitumor efficacy with a tumor inhibition rate more than 90% were achieved from glycopolymer-PTX-DOTA-Gd without obvious systematic toxicity. This branched polymeric prodrug-based nanomedicine is very promising for safe and effective diagnosis and treatment of cancer.

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Branched and Dendritic Polymer Architectures: Functional Nanomaterials for Therapeutic Delivery

Cited by 117 publications

References 197 publications

Tailoring polymer dispersity and shape of molecular weight distributions: methods and applications

Tailoring polymer dispersity and shape of molecular weight distributions: methods and applications

Effects of Polymer 3D Architecture, Size, and Chemistry on Biological Transport and Drug Delivery In Vitro and in Orthotopic Triple Negative Breast Cancer Models

Cathepsin B-responsive and gadolinium-labeled branched glycopolymer-PTX conjugate-derived nanotheranostics for cancer treatment

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