Quantification of intracellular payload release from polymersome nanoparticles

Scarpa, Edoardo; Bailey, Joanne L.; Janeczek, Agnieszka; Stumpf, Patrick S.; Johnston, A. H.; Oreffo, Richard O.C.; Woo, Yin Ling; Cheong, Ying; Evans, Nicholas D.; Newman, Tracey A.

doi:10.1038/srep29460

Cited by 41 publications

(28 citation statements)

References 59 publications

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“…One should keep in mind that DLS is more adequate than NTA for the determination of nanostructures hydrodynamic diameter. Nonetheless, NTA allows an estimation of the concentration of PL [ 21 ] and our results clearly show that the PEG 45 -PLA 69 system after the extrusion resulted in more diluted systems in terms of number of polymersomes due to the initial loss of polymeric material in the bulk fraction after the film hydration, what was already visually observed. The PLs prepared with higher concentration of copolymer (0.1% ( m / v )) ( Figure 8 ) resulted in narrower size distribution and PDI values of 0.345, 0.144 and 0.081 for PEG 45 -PLA 69 , PEG 114 -PLA 153 and PEG 114 -PLA 180, respectively.…”

Section: Resultssupporting

confidence: 62%

Challenges for the Self-Assembly of Poly(Ethylene Glycol)–Poly(Lactic Acid) (PEG-PLA) into Polymersomes: Beyond the Theoretical Paradigms

et al. 2018

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Polymersomes (PL), vesicles formed by self-assembly of amphiphilic block copolymers, have been described as promising nanosystems for drug delivery, especially of biomolecules. The film hydration method (FH) is widely used for PL preparation, however, it often requires long hydration times and commonly results in broad size distribution. In this work, we describe the challenges of the self-assembly of poly (ethylene glycol)-poly(lactic acid) (PEG-PLA) into PL by FH exploring different hydrophilic volume fraction (f) values of this copolymer, stirring times, temperatures and post-FH steps in an attempt to reduce broad size distribution of the nanostructures. We demonstrate that, alongside f value, the methods employed for hydration and post-film steps influence the PEG-PLA self-assembly into PL. With initial FH, we found high PDI values (>0.4). However, post-hydration centrifugation significantly reduced PDI to 0.280. Moreover, extrusion at higher concentrations resulted in further improvement of the monodispersity of the samples and narrow size distribution. For PL prepared at concentration of 0.1% (m/v), extrusion resulted in the narrower size distributions corresponding to PDI values of 0.345, 0.144 and 0.081 for PEG45-PLA69, PEG114-PLA153 and PEG114-PLA180, respectively. Additionally, we demonstrated that copolymers with smaller f resulted in larger PL and, therefore, higher encapsulation efficiency (EE%) for proteins, since larger vesicles enclose larger aqueous volumes.

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Section: Resultssupporting

confidence: 62%

Challenges for the Self-Assembly of Poly(Ethylene Glycol)–Poly(Lactic Acid) (PEG-PLA) into Polymersomes: Beyond the Theoretical Paradigms

et al. 2018

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“…We believe that these larger particles resulted from the lateral fusion of NPs during the longer time allowed for self-assembly, as reported elsewhere [1,5,6,56]. According to the literature, these particles would be classified as hyperbranched polymer vesicles composed of a bilayer membrane and hydrophilic interior, which have previously shown their potential as DDSs [5,57], but more studies are required to confirm this hypothesis.…”

Section: Encapsulation and Release Study Using Peg01-npssupporting

confidence: 57%

Nanocarrier systems assembled from PEGylated hyperbranched poly(arylene oxindole)

Al‐Halifa

Lambrechts

Verheyen

et al. 2019

European Polymer Journal

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Nanoparticles (NPs) formed from hyperbranched polymers are highly attractive organized structures in nanomedicine. Herein, we utilize copper-catalyzed azide-alkyne cycloaddition of hyperbranched poly(arylene oxindole) derivatives to prepare amphiphilic conjugates with different degrees of PEGylation that form spherical NPs in water with tunable particle diameters (25 ± 5 nm for PEG0.3-NPs and 120 ± 10 nm for PEG0.1-NPs) and zeta potential (-7 ± 2 mV for PEG0.3-NPs and-23 ± 3 mV for PEG0.1-NPs). Cisplatin and BODIPY derivatives can be loaded into the PEG0.1-NPs, and their release over 5 d depends on the physicochemical properties of the payload. Moreover, changing the time and conditions for self-assembly leads to the formation of polymer vesicles that can encapsulate and release hydrophilic cargo, as shown with fluorescein. In vitro cellular uptake experiments demonstrate that at concentrations ≤10 g/mL the BODIPY-loaded NPs do not induce morphological differences or cause a reduction in metabolic activity of the cells, confirming their cytocompatibility. They are rapidly taken up by ATDC5 cells and remain stable for 7 d thus highlighting their potential as carrier systems for diagnostic or therapeutic applications.

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“… 25 In a similar study, the self-quenching dye fluorescein was encapsulated within poly(ethylene glycol)- b -poly(ε-caprolactone) (PEG- b -PCL) polymersomes above the quenching concentration. 26 Upon permeation through the polymersome membrane into the exterior solution, the dye would fluoresce, as observed by spectrophotometry, allowing quantification of the polymersome membrane permeability. This method has also been applied to the release of other types of encapsulated cargo, such as the drug doxorubicin from PS- b -PAA polymersomes.…”

Section: Measuring Polymersome Permeabilitymentioning

confidence: 99%

Probing and Tuning the Permeability of Polymersomes

et al. 2020

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Polymersomes are a class of synthetic vesicles composed of a polymer membrane surrounding an aqueous inner cavity. In addition to their overall size, the thickness and composition of polymersome membranes determine the range of potential applications in which they can be employed. While synthetic polymer chemists have made great strides in controlling polymersome membrane parameters, measurement of their permeability to various analytes including gases, ions, organic molecules, and macromolecules remains a significant challenge. In this Outlook, we compare the general methods that have been developed to quantify polymersome membrane permeability, focusing in particular on their capability to accurately measure analyte flux. In addition, we briefly highlight strategies to control membrane permeability. Based on these learnings, we propose a set of criteria for designing future methods of quantifying membrane permeability such that the passage of a variety of molecules into and out of their lumens can be better understood.

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Quantification of intracellular payload release from polymersome nanoparticles

Cited by 41 publications

References 59 publications

Challenges for the Self-Assembly of Poly(Ethylene Glycol)–Poly(Lactic Acid) (PEG-PLA) into Polymersomes: Beyond the Theoretical Paradigms

Challenges for the Self-Assembly of Poly(Ethylene Glycol)–Poly(Lactic Acid) (PEG-PLA) into Polymersomes: Beyond the Theoretical Paradigms

Nanocarrier systems assembled from PEGylated hyperbranched poly(arylene oxindole)

Probing and Tuning the Permeability of Polymersomes

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