Nanoemulsion stability: Experimental evaluation of the flocculation rate from turbidity measurements

Rahn-Chique, Kareem; Puertas, Antonio M.; Romero-Cano, Manuel S.; Rojas, Clara; Urbina-Villalba, Germán

doi:10.1016/j.cis.2012.05.001

Cited by 73 publications

(44 citation statements)

References 140 publications

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“…Such behavior leading to thermodynamic instability was observed to be least with NEs stored at 22 ± 1 C, which indicated that coalescence could be controlled by storage of formulation at this temperature. The NEs stored at 4 ± 1 C exhibited higher increase in droplet size (coalescence) which might be attributed to the fact that at low temperature, NE droplets tend to aggregate/coalesce (Rahn-Chique et al, 2012). Jiang et al, have reported an increase in particle size up to 100 nm at room temperature in a three months stability study of nanoemulsion but they did not find any variation in the entrapment efficiency (Jiang et al, 2013).…”

Section: Stability Of Nesmentioning

confidence: 97%

Perspectives of nanoemulsion assisted oral delivery of docetaxel for improved chemotherapy of cancer

et al. 2014

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Context: Nanoemulsions (NE) are one of the robust delivery tools for drugs due to their higher stability and efficacy. Objectives: The purpose of present investigation is to develop stable, effective and safe NE of docetaxel (DTX). Methods: Soybean oil, lecithin, Pluronic F68, PEG 4000 and ethanol were employed as excipients and NEs were prepared by hot homogenization followed by ultra-sonication. NEs were optimized and investigated for different in vitro and in vivo parameters viz. droplet size, poly dispersity index, charge; zeta potential, drug content and in vitro drug release, in vitro cytotoxicity, in vitro cell uptake and acute toxicity. Transmission electron microscopy was performed to study morphology and structure of NEs. Stability studies of the optimized formulation were performed. Results: Droplet size, poly dispersity index, zeta potential, drug content and in vitro drug release were found to be 233.23 ± 4.3 nm, 0.24 ± 0.010, À43.66 ± 1.9 mV, 96.76 ± 1.5%, 96.25 ± 2.1%, respectively. NE F11 exhibited higher cell uptake (2.83 times than control) and strong cytotoxic activity against MCF-7 cancer cells (IC 50 ; 13.55 ± 0.21 mg/mL at 72 h) whereas no toxicity or necrosis was observed with liver and kidney tissues of mice at a dose of 20 mg/kg. Transmission electron microscopy ensured formation of poly-dispersed and spherical droplets in nanometer range. NE F11 (values indicated above) was selected as the optimized formulation based on the aforesaid parameters. Conclusion: Conclusively, stable, effective and safe NE was developed which might be used as an alternative DTX therapy.

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Section: Stability Of Nesmentioning

confidence: 97%

Perspectives of nanoemulsion assisted oral delivery of docetaxel for improved chemotherapy of cancer

et al. 2014

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“…Nano-emulsions can be prepared either through low-energy emulsification or high-energy emulsification methods or a combination of both (Koroleva and Yurtov, 2012). Due to their small droplet size, nano-emulsions are stable against sedimentation or creaming but prone to flocculation, coalescence and Ostwald ripening (Rahn-Chique et al, 2012). However, high kinetic stability of nano-emulsions can be obtained with proper choice of system components, composition and preparation method (Solans and Sole, 2012).…”

Section: Introductionmentioning

confidence: 99%

Comparison of Box–Behnken and central composite designs in optimization of fullerene loaded palm-based nano-emulsions for cosmeceutical application

Ngan

Basri

Lye

et al. 2014

Industrial Crops and Products

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Response surface methodology (RSM) Central composite rotatable design (CCRD) Box-Behnken design (BBD) a b s t r a c t Box-Behnken (BBD) and central composite rotatable designs (CCRD) were used as statistical multivariate methods in the formulation optimization of fullerene loaded nano-emulsions. Effect of palm kernel oil ester (10-20%, w/w), emulsifier (5-10%, w/w) and xanthan gum (0.6-1.0%, w/w) as formulation variables on the particle size, -potential and viscosity of the nano-emulsions were investigated. Under the optimum conditions, CCRD model predicted the response values for particle size, -potential and viscosity were 153.6 nm, −53.4 mV and 42.1 Pa s, respectively. Nonetheless, BBD model suggested that the optimum conditions for a fullerene loaded nano-emulsion would gave particle size, -potential and viscosity of 151.6 nm, −53.8 mV and 43.1 Pa s, respectively. The actual response according to suggested compositions for both models showed excellent agreement with the predicted value with residual standard error (RSE) of less than 4%. Optimum nano-emulsions were stable during storage at 25 and 45 • C for 90 days and freeze-thaw cycle.

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“…56 The most widely used model for flocculation is the classical expression of Smoluchowski's equation 4,57,58 for hetero-aggregation. This expression is governed by two aspects, perikinetic (due to Brownian motion and diffusive adsorption, leading to attachment) and orthokinetic flocculation (transport of flocculants due to shear).…”

Section: Discussionmentioning

confidence: 99%

Flocculation on a chip: a novel screening approach to determine floc growth rates and select flocculating agents

et al. 2018

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Flocculation is a key purification step in cell-based processes for the food and pharmaceutical industry where the removal of cells and cellular debris is aided by adding flocculating agents. However, finding the best suited flocculating agent and optimal conditions to achieve rapid and effective flocculation is a nontrivial task. In conventional analytical systems, turbulent mixing creates a dynamic equilibrium between floc growth and breakage, constraining the determination of floc formation rates. Furthermore, these systems typically rely on end-point measurements only. We have successfully developed for the first time a microfluidic system for the study of flocculation under well controlled conditions. In our microfluidic device (μFLOC), floc sizes and growth rates were monitored in real time using high-speed imaging and computational image analysis. The on-line and in situ detection allowed quantification of floc sizes and their growth kinetics. This eliminated the issues of sample handling, sample dispersion, and end-point measurements.We demonstrated the power of this approach by quantifying the growth rates of floc formation under forty different growth conditions by varying industrially relevant flocculating agents (pDADMAC, PEI, PEG), their concentration and dosage. Growth rates between 12.2 μm s −1 for a strongly cationic flocculant (pDADMAC) and 0.6 μm s −1 for a non-ionic flocculant (PEG) were observed, demonstrating the potential to rank flocculating conditions in a quantitative way. We have therefore created a screening tool to efficiently compare flocculating agents and rapidly find the best flocculating condition, which will significantly accelerate early bioprocess development.

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Nanoemulsion stability: Experimental evaluation of the flocculation rate from turbidity measurements

Cited by 73 publications

References 140 publications

Perspectives of nanoemulsion assisted oral delivery of docetaxel for improved chemotherapy of cancer

Perspectives of nanoemulsion assisted oral delivery of docetaxel for improved chemotherapy of cancer

Comparison of Box–Behnken and central composite designs in optimization of fullerene loaded palm-based nano-emulsions for cosmeceutical application

Flocculation on a chip: a novel screening approach to determine floc growth rates and select flocculating agents

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