Abstract
Toxic organic solvent residues and the active substances of thermal degradation (such as anthocyanin and polyphenols) are always a concern with the liposomes produced by traditional techniques. The present study focuses on a new approach for the microencapsulation of Clitoria ternatea petal (CTP) extracts, which contain anthocyanins, by high-pressure processing (HPP) at room temperature. Thus, a series of CTP liposomes were prepared and their physicochemical properties were analyzed by laser granulometry and by scanning electron microscopy (SEM). The results revealed that the average particle size of the liposomes after HPP treatment increased gradually from 300 MPa to 600 MPa, possibly due to the aggregation of liposomes and damage to the phospholipid bilayers. For the preparation of liposomes by the HPP method at 300 MPa, the mean particle size, polydispersity index (PDI), and encapsulation efficiency were 240.7 nm, 0.37, and 77.8%, respectively. The HPP method provided a number of advantages over conventional methods (magnet stirring and ultrasonication) as it could allow liposome preparation with higher encapsulation efficiency, smaller size, and narrower, more reproducible particle size distribution. Conclusively, microencapsulation in the liposomes was successfully achieved with the fast-adiabatic expansion of HPP.
Highlights
Recent studies have demonstrated that Clitoria ternatea can play a variety of roles: as an antioxidant [1,2], antibacterial agent [3], in scavenging free radicals [4,5], and preventing cardiovascular diseases [2,5]
The liposomes were destroyedthrough by homogenizaAfter the ethanol injection method, theinjection liposomes were destroyed by homogenization tion through stirring, ultrasonic oscillation, or to form a dispersed suspension of stirring, ultrasonic oscillation, or high-pressure processing (HPP) to form a dispersed suspension of phospholipid fragments phospholipid fragments that were reassembled to form liposomes
The microencapsulation of Clitoria ternatea petal (CTP) extracts in liposomes was successfully achieved without co-solvents at room temperature within 10 min using the eco-friendly HPP technology
Summary
Recent studies have demonstrated that Clitoria ternatea can play a variety of roles: as an antioxidant [1,2], antibacterial agent [3], in scavenging free radicals [4,5], and preventing cardiovascular diseases [2,5]. Phenolic compounds in Clitoria ternatea are a diverse group that includes anthocyanins, flavonol glycosides, and proanthocyanidins [1,2,3,4]. Anthocyanin as a potential source for antimicrobial activity in the flower petal of Clitoria ternatea is among the flavonoids that are the most susceptible to pH levels and temperature [6,7]. The active substances of thermal degradation (such as anthocyanin and polyphenol) are always a concern with the liposomes produced by traditional techniques. Numerous techniques for liposome preparation and size reduction remain popular, such as the French press, sonication, detergent dialysis, reverse-phase evaporation, ethanol injection, homogenization, membrane extrusion, and supercritical fluid process [8,10,11].
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