Particle Size Evaluation of Ultra-micro-pigment in Breaking-up and Stabilization Processes by Ultrasonic Attenuation Spectroscopy

Abstract In order to examine the effect of briquettes with different crack structures on ultrasonic characteristics under different wetting conditions, a series of ultrasonic testing are carried out on briquettes at different wetting heights and the ultrasonic characteristics in these coal samples are explored. The results show that ultrasonic amplitude is positively correlated with the emission voltage, whereas ultrasonic frequency is negatively correlated with the emission voltage. Changes in both are closely related to the particle size and density. The ultrasonic velocity is positively correlated with the wetting degree. Sample mass has the greatest effect on the ultrasonic velocity, followed by particle size, and pressure has the smallest effect. At dry stage, ultrasonic velocity in gas coal is less than that in bituminous coal. The opposite is true in the fully wet state. The influence of crack thickness on ultrasonic velocity gradually increases with the wetting degree increasing. At dry stage, the velocity gradually increases with the crack dip increasing, while as the wetting height increasing, magnitude of velocity increase gradually decreases with the dip increasing. The ultrasonic attenuation in the briquettes reduces with the emission voltage enhancing. The attenuation decreases with sample particle size, crack thickness and crack size decreasing and with sample mass, pressure and crack dip increasing. The ultrasonic attenuation shows a trend of increase before decrease with the wetting height increasing. The attenuation of ultrasonic wave increases with wave velocity increasing for intact samples and shows a trend of increase before decrease for cracked samples.

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EFFECTS OF SONICATION ON SIZE DISTRIBUTION AND ENTRAPMENT OF LYNESTRENOL TRANSFEROSOME

International Journal of Applied Pharmaceutics ◽

10.22159/ijap.2020.v12s1.ff053 ◽

2020 ◽

pp. 245-247

Author(s):

ISKANDARSYAH ISKANDARSYAH ◽

CAMELIA DWI PUTRI MASRIJAL ◽

HARMITA HARMITA

Keyword(s):

Drug Delivery ◽

Particle Size ◽

Size Distribution ◽

Time Variation ◽

Transdermal Drug Delivery ◽

Entrapment Efficiency ◽

Tween 80 ◽

Sonication Time ◽

Size Evaluation ◽

Edge Activator

Objective: The aim of this study was to develop transferosome vesicles for the transdermal drug delivery of lynestrenol.Methods: The lynestrenol transferosome vesicle was made by encapsulating the drug in a variation of phosphatidylcholine and Tween 80 by the thinlayerhydration method. The resulting transferosome vesicles were modified with a time variation of 30, 60, 90, and 120 min, and sonication variationswere paused and not paused. Particle size evaluation, polydispersity (PDI), and entrapment efficiency (%EE) were carried out on the variation ofsonication time.Results: The evaluation results showed that sonication without pauses showed better %EE and particle size than sonication with pauses andincreasing concentration of Tween 80 (edge activator). The %EE increased, and particle size decreased with increasing sonication time; PDI of vesicleswas heterogeneous with increasing sonication time. The %EE in formulas F1 and F2 after 120 min was 73.06% and 76.06% (paused) and 80.40% and82.97% (without paused). The particle size of formula F1 and F2 after 120 min 575.4 nm and 471.6 nm (paused) and 524.1 nm and 434.7 nm (withoutpaused). The PDI formulas of F1 and F2 after 120 min were 0.69 and 0.763 (paused) and 0.84 and 0.59 (without paused).Conclusion: Based on the results of the transferosome vesicle characteristics, it was shown that the optimal vesicle composition for packaginglynestrenol was vesicles that were composed of phosphatidylcholine and Tween 80 without pauses and could potentially be used as a transdermaldrug delivery system.

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