Oral delivery of probiotics using single‐cell encapsulation

Han, Jiaqi; McClements, David Julian; Liu, Xuebo; Liu, Fuguo

doi:10.1111/1541-4337.13322

Cited by 4 publications

(3 citation statements)

References 159 publications

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“…Natural food-grade polymers like alginate and chitosan are GRAS, whereas synthetic polymers may require a more thorough safety evaluation. Meanwhile, both the encapsulation material and the PROs dosage need to meet the human daily intake limits [ 67 ].…”

Section: Monolayer Versus Double/multilayer Coatingsmentioning

confidence: 99%

Encapsulation of Probiotics within Double/Multiple Layer Beads/Carriers: A Concise Review

Agriopoulou,

Smaoui,

Chaari

et al. 2024

Molecules

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An increased demand for natural products nowadays most specifically probiotics (PROs) is evident since it comes in conjunction with beneficial health effects for consumers. In this regard, it is well known that encapsulation could positively affect the PROs’ viability throughout food manufacturing and long-term storage. This paper aims to analyze and review various double/multilayer strategies for encapsulation of PROs. Double-layer encapsulation of PROs by electrohydrodynamic atomization or electrospraying technology has been reported along with layer-by-layer assembly and water-in-oil-in-water (W1/O/W2) double emulsions to produce multilayer PROs-loaded carriers. Finally, their applications in food products are presented. The resistance and viability of loaded PROs to mechanical damage, during gastrointestinal transit and shelf life of these trapping systems, are also described. The PROs encapsulation in double- and multiple-layer coatings combined with other technologies can be examined to increase the opportunities for new functional products with amended functionalities opening a novel horizon in food technology.

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Section: Monolayer Versus Double/multilayer Coatingsmentioning

confidence: 99%

Encapsulation of Probiotics within Double/Multiple Layer Beads/Carriers: A Concise Review

Agriopoulou,

Smaoui,

Chaari

et al. 2024

Molecules

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“…5 On the basis of these living contributions, living materials have been extensively applied in a wide range of fields, including medical engineering, drug delivery, agriculture, biofuels, and environment monitoring and remediation. 1,6,7 It is worth noting that due to fast reproduction, sophisticated genetic modifiability, strong adaptability, simple cultivation, and convenient transportation, microorganisms, especially bacteria that constitute ∼15% of the global biomass in earth, have significant advantages over plant cells and mammalian cells for living material fabrication. 8 Besides, bacteria own a serial of unique features, including the preference of targeting and colonizing specific in vivo sites, immunoactivation effect, and antipathogen ability, which provide such bacteria-based living materials with great potential for use as therapeutic agents for microbial therapy.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, these living materials have been recognized as a kind of green biomaterials, as they match the green concept and principle . On the basis of these living contributions, living materials have been extensively applied in a wide range of fields, including medical engineering, drug delivery, agriculture, biofuels, and environment monitoring and remediation. ,, …”

Section: Introductionmentioning

confidence: 99%

Coated Bacteria: Advanced Living Materials for Microbial Therapy

Cao,

Liu

2024

Acc. Mater. Res.

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Metrics & MoreArticle Recommendations CONSPECTUS: Living materials represent an emerging and innovative concept at the forefronts of materials science due to the distinctive living characteristics. Living organisms, such as microorganisms, plant cells, and mammalian cells, have been used as the major elements for the fabrication of living materials. Given the favorable features including reproductivity, genetic modifiability, adaptability, and cultivability, bacteria have received increasing attention for the development of engineered living materials. Particularly, owing to the inherent abilities to target and colonize specific in vivo sites, activate immune responses, and inhibit pathogens, bacteria play key roles in maintaining human health and have currently widely exploited as living materials for the preparation of therapeutic agents. However, caused by the innate immunogenicity, metabolic activity, and movability, the use of bacteria-based living materials for therapeutic applications often suffers from poor biosafety and insufficient bioavailability, inevitably resulting in low treatment efficacy. In order to address these challenges, extensive efforts have been invested in designing and engineering various advanced bacteria-based living materials to generate superior therapeutic agents by using genetic modification and surface decoration.In this Account, we summarize the recent advances from our group with a focus on surface coating of bacteria-based living material for advanced microbial therapy. First, we present a brief introduction of the existing living materials in nature that possess the living characteristics of reproduction, biosynthesis, self-healing, self-organization, self-adaption, and environment responsiveness, with a particular emphasis on the advantages of living materials composed by bacteria for microbial therapy. Second, we elaborate the current challenges of using bacteria-based living materials for therapeutic applications and then showcase the strategies to prepare superior living bacterial therapeutics by surface coating of individual bacteria. Three types of coating strategies are included in this Account: (1) the physical strategy to coat bacteria with eukaryotic cell membranes from red blood cells and yeast cells by mechanical extrusion;(2) the chemical strategy to wrap bacteria with synthetic coatings by interfacial self-assembly and interfacial mineralization;(3) the biological strategy to encapsulate bacteria by self-secreted biofilms and apoptosis bodies through external stimulations. We highlight that coated bacteria can be endowed with a wide range of coating-derived exogenous functions and enumerate their appealing characteristics of reduced immune clearance, increased bioavailability, improved safety, and preferential colonization in vivo. Third, we shift to the potential of these coated bacteria as living therapeutic agents for treating various diseases, especially different types of cancer and intestinal inflammations. Lastly, we discuss the remaining challenges that ...

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Single-cell encapsulation systems for probiotic delivery: Armor probiotics

Zhao,

Yu,

et al. 2024

Advances in Colloid and Interface Science

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Oral delivery of probiotics using single‐cell encapsulation

Cited by 4 publications

References 159 publications

Encapsulation of Probiotics within Double/Multiple Layer Beads/Carriers: A Concise Review

Encapsulation of Probiotics within Double/Multiple Layer Beads/Carriers: A Concise Review

Coated Bacteria: Advanced Living Materials for Microbial Therapy

Single-cell encapsulation systems for probiotic delivery: Armor probiotics

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