Use of gelatin and gum arabic for microencapsulation of probiotic cells from Lactobacillus plantarum by a dual process combining double emulsification followed by complex coacervation

Paula, Daniele de Almeida; Martins, Eliane Maurício Furtado; Costa, Nataly de Almeida; Oliveira, Patrícia Martins de; Oliveira, Eduardo Basílio de; Ramos, Afonso Mota

doi:10.1016/j.ijbiomac.2019.04.110

Cited by 95 publications

(33 citation statements)

References 70 publications

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“…The fact that gelatine is one of the oldest and multiple-purposes ingredients in the food industry makes it also one of the most studied proteins as coating agent in the preparation of microcapsules [152]. Moreover, the properties of gelatine and its ability to interact with a wide variety of polysaccharides allows its use as a coating material in a several microencapsulation methods, such as extrusion, complex coacervation, spray chilling, spray drying, and lyophilisation [23,42,67,100,153,154]. Another particular advantage of using gelatine as a coating material is its linear structure, which provides a better oxygen barrier than globular proteins.…”

Section: Proteinsmentioning

confidence: 99%

“…On the other hand, the protein moiety of GA provides the surface activity, foaming abilities, and emulsifying characteristics of this polysaccharide [178,195]. In this regard, combinations of gelatine-GA [67], whey protein isolate (WPI)-GA [58], and the individual mixture of seed, leaf, or pulp extracts of the miracle fruit (Synsepalum dulcificum) with GA [21], were used as coating materials for the microencapsulation of probiotics and these coatings successfully improved the survival of probiotic cells during processing, simulated gastrointestinal in vitro conditions, and upon storage, when compared to free cells.…”

Section: Anionic Polysaccharidesmentioning

confidence: 99%

“…The melting point of fats is the main property used for microencapsulation, since thermal solidification is induced at temperatures below their melting point [213,214]. Vegetable fats have been extensively used as co-encapsulating materials in the microencapsulation of probiotics by emulsification [34,39,[59][60][61][62][63][64][65][66][67][69][70][71]104,183] or by spry drying [24,103,104]. On the other hand, in a recent study, Silva et al reported the microencapsulation of probiotics using vegetable oil as a sole coating material or covered with gelatine-gum Arabic.…”

Section: Lipidsmentioning

confidence: 99%

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A Brief Review of Edible Coating Materials for the Microencapsulation of Probiotics

et al. 2020

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The consumption of probiotics has been associated with a wide range of health benefits for consumers. Products containing probiotics need to have effective delivery of the microorganisms for their consumption to translate into benefits to the consumer. In the last few years, the microencapsulation of probiotic microorganisms has gained interest as a method to improve the delivery of probiotics in the host as well as extending the shelf life of probiotic-containing products. The microencapsulation of probiotics presents several aspects to be considered, such as the type of probiotic microorganisms, the methods of encapsulation, and the coating materials. The aim of this review is to present an updated overview of the most recent and common coating materials used for the microencapsulation of probiotics, as well as the involved techniques and the results of research studies, providing a useful knowledge basis to identify challenges, opportunities, and future trends around coating materials involved in the probiotic microencapsulation.

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Section: Proteinsmentioning

confidence: 99%

Section: Anionic Polysaccharidesmentioning

confidence: 99%

Section: Lipidsmentioning

confidence: 99%

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A Brief Review of Edible Coating Materials for the Microencapsulation of Probiotics

et al. 2020

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“…Proteins are another important group of polymers that are used for encapsulation of probiotics thanks to their amphiphilic nature [77]. The most common proteins used for encapsulation of probiotics include gelatin [78], whey protein [79], and casein [80]. From synthetic polymers, Polyesters (such as poly (D, L-lactic-co-glycolic acid) (PLGA)), polyacrylamides, and polyvinyl alcohol (PVA) are some other examples applied for delivery of probiotics [77].…”

Section: -3-ph-sensitive Polymersmentioning

confidence: 99%

Polymeric carriers for enhanced delivery of probiotics

Asgari

Pourjavadi

Licht

et al. 2020

Advanced Drug Delivery Reviews

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“…An effective microencapsulation system should maintain the stability of the probiotics during storage, protect them from the harsh conditions in the upper GIT, release them in the colon, and then promote their ability to colonize the mucosal surfaces (Anselmo, McHugh, Webster, Langer, & Jaklenec, 2016;Fakhrullin & Lvov, 2012;Tripathi et al, 2013). A number of recent reviews have focused on the various kinds of oral delivery systems that have been developed to encapsulate probiotics (Chen, Wang, Liu, & Gong, 2017;De Prisco & Mauriello, 2016;Heidebach, Forst, & Kulozik, 2012;Iravani, Korbekandi, & Mirmohammadi, 2015;Mandal & Hati, 2017;Paula et al, 2019;Pavli, Tassou, Nychas, & Chorianopoulos, 2018;Ramos, Cerqueira, Teixeira, & Vicente, 2018;Sarao & Arora, 2017). However, many of these systems are unable to adequately protect probiotics from degradation within the human gut because of inherent limitations, such as their permeability to acids, enzymes, or bile salts.…”

Section: Introductionmentioning

confidence: 99%

Progress in microencapsulation of probiotics: A review

Yao

Xie

et al. 2020

Comp Rev Food Sci Food Safe

259

146

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The potential health benefits of probiotics may not be realized because of the substantial reduction in their viability during food storage and gastrointestinal transit. Microencapsulation can be used to enhance the resistance of probiotics to unfavorable conditions. A range of oral delivery systems has been developed to increase the level of probiotics reaching the colon including embedding and coating systems. This review introduces emerging strategies for the microencapsulation of probiotics and highlights the key mechanisms of their stress–tolerance properties. Recent in vitro and in vivo models for evaluation of the efficiency of probiotic delivery systems are also reviewed. Encapsulation technologies are required to maintain the viability of probiotics during storage and within the human gut so as to increase their ability to colonize the colon. These technologies work by protecting the probiotics from harsh environmental conditions, as well as increasing their mucoadhesive properties. Typically, the probiotics are either embedded inside or coated with food‐grade materials such as biopolymers or lipids. In some cases, additional components may be coencapsulated to enhance their viability such as nutrients or protective agents. The importance of having suitable in vitro and in vivo models to evaluate the efficiency of probiotic delivery systems is also emphasized.

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Use of gelatin and gum arabic for microencapsulation of probiotic cells from Lactobacillus plantarum by a dual process combining double emulsification followed by complex coacervation

Cited by 95 publications

References 70 publications

A Brief Review of Edible Coating Materials for the Microencapsulation of Probiotics

A Brief Review of Edible Coating Materials for the Microencapsulation of Probiotics

Polymeric carriers for enhanced delivery of probiotics

Progress in microencapsulation of probiotics: A review

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