Research Advances of Lactoferrin in Electrostatic Spinning, Nano Self-Assembly, and Immune and Gut Microbiota Regulation

Li, Ying; Dong, Lezhen; Mu, Zhishen; Liu, Lingyi; Yang, Junsi; Wu, Zufang; Pan, Daodong; Liu, Lianliang

doi:10.1021/acs.jafc.2c04241

Cited by 22 publications

(20 citation statements)

References 116 publications

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“…The presence of oppositely charged polyelectrolytes undergoes strong electrostatic interactions to yield a self-assembled polyelectrolyte complex (PEC). , Hence, the participating polymers must be ionized and possess opposite charges. In the case of natural polysaccharides, chitosan most commonly forms PEC via electrostatic interaction between its positive amino group and opposite negative groups of numerous polyelectrolytes such as alginate, gellan, and κ-carrageenan .…”

Section: Hydrogel Cross-linking Methodsmentioning

confidence: 99%

“…The presence of oppositely charged polyelectrolytes undergoes strong electrostatic interactions to yield a self-assembled polyelectrolyte complex (PEC). 9,61 Hence, the participating polymers must be These are nonionic. As a result of extensive hydrogen bonding between the molecules, agarose exhibits mild gelation, forming double helical structure bundles that adhere together.…”

Section: Hydrogel Cross-linking Methodsmentioning

confidence: 99%

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Stimuli-Responsive Polysaccharide-Based Smart Hydrogels and Their Emerging Applications

Srivastava

Choudhury

2022

Ind. Eng. Chem. Res.

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Hydrogels are a soft material that undergoes cross-linking between polymers to form a hydrophilic three-dimensional network. In fact, similarity to body tissue, soft consistency, biocompatibility, and elasticity, impart a protagonic role of hydrogel to be applied as a biomaterial. In response to external cues, stimuli-responsive hydrogels are particularly impactful, enabling remarkable levels of control over material properties. They can endure changes in swelling behavior, permeability, network structure, and mechanical strength. Nevertheless, such changes induce single-cycle or reversible transitions, so hydrogels can regain their initial state once the trigger is removed. Recently, polysaccharide-based hydrogels with stimuli-responsive properties resulted in developing biomimetic structures for a widespread biotechnological application owing to their excellent biodegradability, biocompatibility, nonimmunogenicity, functional properties, ease of gelation, and derivatization. This review will initially highlight recent advances in cross-linking methods and chemistry for preparing stimuli-responsive hydrogels. Subsequently, state-of-the-art techniques to understand the structural, chemical, and rheological behavior of polysaccharide-based stimuli-responsive hydrogel will be discussed. Additionally, the responsiveness of polysaccharide hydrogel toward diverse stimuli such as redox, temperature, light, pH, magnetism, electricity, etc., with a broad spectrum of applications will be described in detail. This review also attempts to address the lacunae of existing stimuli-responsive hydrogel and their future perspectives.

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Section: Hydrogel Cross-linking Methodsmentioning

confidence: 99%

Section: Hydrogel Cross-linking Methodsmentioning

confidence: 99%

Stimuli-Responsive Polysaccharide-Based Smart Hydrogels and Their Emerging Applications

Srivastava

Choudhury

2022

Ind. Eng. Chem. Res.

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“…With the rapid advancement of proteomic techniques, more than 3000 BEV-associated proteins have been identified, which can be functionally classified as structural proteins, porins, ion channels, transporters, enzymes, and proteins related to stress responses [80][81][82][83]. Global proteomics highlights the unique protein profiles of BEVs, which endow them with distinct functional capabilities, such as signal transduction, pathogenicity, biofilm formation, metabolism, antibiotic resistance, and bacterial survival [38,[84][85][86][87]. The distinct features of dynamic changes in protein composition and BEV yield efficiency when bacteria are grown under different environmental conditions, suggests that cargos in BEVs may be selectively enriched compared to their parent bacteria, although few studies have determined the specific sorting mechanisms.…”

Section: Cargo Packaging Into Bevsmentioning

confidence: 99%

Interactions between extracellular vesicles and microbiome in human diseases: New therapeutic opportunities

Luo

Chang

Liang

et al. 2023

iMeta

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In recent decades, accumulating research on the interactions between microbiome homeostasis and host health has broadened new frontiers in delineating the molecular mechanisms of disease pathogenesis and developing novel therapeutic strategies. By transporting proteins, nucleic acids, lipids, and metabolites in their versatile bioactive molecules, extracellular vesicles (EVs), natural bioactive cell‐secreted nanoparticles, may be key mediators of microbiota–host communications. In addition to their positive and negative roles in diverse physiological and pathological processes, there is considerable evidence to implicate EVs secreted by bacteria (bacterial EVs [BEVs]) in the onset and progression of various diseases, including gastrointestinal, respiratory, dermatological, neurological, and musculoskeletal diseases, as well as in cancer. Moreover, an increasing number of studies have explored BEV‐based platforms to design novel biomedical diagnostic and therapeutic strategies. Hence, in this review, we highlight the recent advances in BEV biogenesis, composition, biofunctions, and their potential involvement in disease pathologies. Furthermore, we introduce the current and emerging clinical applications of BEVs in diagnostic analytics, vaccine design, and novel therapeutic development.

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“…Moreover, apoferritin can be utilized to encapsulate various bioactive ingredients due to the ideal space provided by the cavity of the protein . Currently, a variety of delivery systems have been designed and fabricated, including liposomes, nanoparticles, hydrogels, and emulsions. − Notably, ferritin nanocage particles stand out as particularly suitable for enhancing the bioavailability and functionality of a wide range of biologically active compounds and nutrients through the development of ferritin-based delivery systems. , Apoferritin can successfully encapsulate polyphenols, flavonoids, enzymes, and drugs through reversible disassembly/reassembly property by using pH conditions transition or urea induction. , These encapsulation techniques effectively enhance the functionality of bioactive compounds or nutrients in food, improve ingredient stability during processing and storage, and confer specific targeting capabilities to enhance their bioavailability. Ferritin nanocage particles are highly conducive to enhancing the bioavailability and functionality of these bioactive compounds and nutrients through the development of a wide variety of ferritin-based delivery systems. , Furthermore, ferritin–polymer conjugates can also be developed as assembled nanoparticles for encapsulation and delivery applications, and the sensitivity and size flexibility of ferritin channels allow metal ions, such as calcium and small organic molecules, to diffuse into the cavity through channels .…”

Section: Introductionmentioning

confidence: 99%

Multifaceted Applications of Ferritin Nanocages in Delivering Metal Ions, Bioactive Compounds, and Enzymes: A Comprehensive Review

Hu,

Sha,

et al. 2023

J. Agric. Food Chem.

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Ferritin, a distinctive iron-storage protein, possesses a unique cage-like nanoscale structure that enables it to encapsulate and deliver a wide range of biomolecules. Recent advances prove that ferritin can serve as an efficient 8 nm diameter carrier for various bioinorganic nutrients, such as minerals, bioactive polyphenols, and enzymes. This review offers a comprehensive summary of ferritin’s structural features from different sources and emphasizes its functions in iron supplementation, calcium delivery, single- and coencapsulation of polyphenols, and enzyme package. Additionally, the influence of innovative food processing technologies, including manothermosonication, pulsed electric field, and atmospheric cold plasma, on the structure and function of ferritin are examined. Furthermore, the limitations and prospects of ferritin in food and nutritional applications are discussed. The exploration of ferritin as a multifunctional protein with the capacity to load various biomolecules is crucial to fully harnessing its potential in food applications.

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Research Advances of Lactoferrin in Electrostatic Spinning, Nano Self-Assembly, and Immune and Gut Microbiota Regulation

Cited by 22 publications

References 116 publications

Stimuli-Responsive Polysaccharide-Based Smart Hydrogels and Their Emerging Applications

Stimuli-Responsive Polysaccharide-Based Smart Hydrogels and Their Emerging Applications

Interactions between extracellular vesicles and microbiome in human diseases: New therapeutic opportunities

Multifaceted Applications of Ferritin Nanocages in Delivering Metal Ions, Bioactive Compounds, and Enzymes: A Comprehensive Review

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