Quantitative turbidimetric characterization of stabilized complex coacervate dispersions

Quantitative turbidimetric characterization of stabilized complex coacervate dispersions

Stabilizing complex coacervate microdroplets is desirable due to their various applications, such as bioreactors, drug delivery vehicles, and encapsulants. Here, we present quantitative characterization of complex coacervate dispersion stability inferred by turbidimetry measurements. The stability o...

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Veröffentlicht in:Soft matter 2024-07, Vol.2 (26), p.56-57
Hauptverfasser: Holkar, Advait, Gao, Shang, Villaseñor, Kathleen, Lake, Michael, Srivastava, Samanvaya
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Sprache:eng
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Bioreactors
Coalescence
Dispersions
Drug delivery
Effectiveness
Polyelectrolytes
Salts
Stability
Turbidimetry
Turbidity
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container_end_page 57
container_issue 26
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container_title Soft matter
container_volume 2
creator Holkar, Advait
Gao, Shang
Villaseñor, Kathleen
Lake, Michael
Srivastava, Samanvaya
description Stabilizing complex coacervate microdroplets is desirable due to their various applications, such as bioreactors, drug delivery vehicles, and encapsulants. Here, we present quantitative characterization of complex coacervate dispersion stability inferred by turbidimetry measurements. The stability of the dispersions is shown to be modulated by the concentrations of comb polyelectrolyte (cPE) stabilizers and salt. We demonstrate cPEs as effective stabilizers for complex coacervate dispersions independent of the chemistry or length of the constituent polyelectrolytes, salts, or preparation routes. By monitoring the temporal evolution of dispersion turbidity, we show that cPEs suppress microdroplet coalescence with minimal change in microdroplet sizes over 48 hours, even at salt concentrations up to 300 mM. The number density and average microdroplet size are shown to be controlled by varying the cPE and salt concentrations. Lastly, turbidity maps, akin to binodal phase maps, depict an expansion of the turbid two-phase region and an increase in the salt resistance of the coacervates upon the introduction of cPEs. The coacervate salt resistance is shown to increase by >3×, and this increase is maintained for up to 15 days, demonstrating that cPEs impart higher salt resistance over extended durations. The stabilization of complex coacervate microdroplets can be modulated by the concentrations of cPE stabilizer and salt, enabling their various applications, such as bioreactors, drug delivery vehicles, and encapsulants.
doi_str_mv 10.1039/d3sm01761c
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source Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects Bioreactors
Coalescence
Dispersions
Drug delivery
Effectiveness
Polyelectrolytes
Salts
Stability
Turbidimetry
Turbidity
title Quantitative turbidimetric characterization of stabilized complex coacervate dispersions
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