Starch‐based nanoparticles: Stimuli responsiveness, toxicity, and interactions with food components

Yu, Mengting; Ji, Na; Wang, Yanfei; Dai, Lei; Xiong, Liu; Sun, Qingjie

doi:10.1111/1541-4337.12677

Cited by 63 publications

(28 citation statements)

References 158 publications

(224 reference statements)

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“…In assessing the gel properties, pharmacokinetics, morphology, anticancer activity and immunohistopathology after thermosensitive irinotecan-encapsulated solid lipid nanoparticles (SLN) rectal administration to tumor-bearing mice, it was easily administered to the anus, gelling rapidly and strongly after rectal administration, inducing no damage to the rat rectum and no body weight loss in tumor-bearing mice ( 135 ). Futhermore, mutiple nanocarrier, including bio-nanocapsule-liposome nanocarrier ( 136 ), poly{(benzyl-L-aspartate)-co-[N-(3-aminopropyl) imidazole-L-aspartamide]}-poly(ethylene glycol) ( 137 ), Polysaccharide-based nanocarriers ( 138 ), ( 139 ), Poly(aspartic acid-graft-imidazole)-poly(ethylene glycol) [P(Asp-g-Im)-PEG] ( 140 ), amphiphilic copolymer of poly(epsilon-caprolactone)-b-poly(ethylene glycol)-b- poly(epsilon-caprolactone) ( 141 ), were demonstrated to be safety in vivo in treatment cancer, inflammatory bowel disease. Additionally, some material was demonstrated to be safety such as starch-based nanoparticles ( 139 ).…”

Section: Safety Of Nanocarriersmentioning

confidence: 99%

A Review on Polymer and Lipid-Based Nanocarriers and Its Application to Nano-Pharmaceutical and Food-Based Systems

Zhang

Wang

et al. 2021

Front. Nutr.

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Recently, owing to well-controlled release, enhanced distribution and increased permeability, nanocarriers used for alternative drug and food-delivery strategies have received increasingly attentions. Nanocarriers have attracted a large amount of interest as potential carriers of various bioactive molecules for multiple applications. Drug and food-based delivery via polymeric-based nanocarriers and lipid-based nanocarriers has been widely investigated. Nanocarriers, especially liposomes, are more and more widely used in the area of novel nano-pharmaceutical or food-based design. Herein, we aimed to discuss the recent advancement of different surface-engineered nanocarriers type, along with cutting-edge applications for food and nanomedicine and highlight the alternative of phytochemical as nanocarrier. Additionally, safety concern of nanocarriers was also highlighted.

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Section: Safety Of Nanocarriersmentioning

confidence: 99%

A Review on Polymer and Lipid-Based Nanocarriers and Its Application to Nano-Pharmaceutical and Food-Based Systems

Zhang

Wang

et al. 2021

Front. Nutr.

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“…Antimicrobial packaging is another promising area of the food industry that has received growing attention [110]. Starchbased nanoparticles display unique properties, such as controllable release, improved water solubility, bioavailability, and improved delivery of active ingredients in foods and within the human body [111,112]. In addition to enhancing the properties of starch films, starch-based nanoparticles can be used to produce high value-added products, such as the biodegradable carriers for drug delivery [113].…”

Section: Value-added Products From Sweet Potato Starchmentioning

confidence: 99%

“…Starch-based nanoparticles with desired sizes can be produced using amylases or/and debranching enzymes to digest the α-1,4-glucosidic or α-1,6-glucosidic bonds in starch. Enzymatic hydrolysis is likely to yield homogeneous nanoparticles when the starch contains more A and B type short chains with an average DP of 14-18 [112]. Sun et al reported a method of producing starch granules of 60-120 nm in size from maize waxy starch that has 99% amylopectin [114].…”

Section: Value-added Products From Sweet Potato Starchmentioning

confidence: 99%

Engineering Properties of Sweet Potato Starch for Industrial Applications by Biotechnological Techniques including Genome Editing

Lyu

Ahmed

Fan

et al. 2021

IJMS

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Sweet potato (Ipomoea batatas) is one of the largest food crops in the world. Due to its abundance of starch, sweet potato is a valuable ingredient in food derivatives, dietary supplements, and industrial raw materials. In addition, due to its ability to adapt to a wide range of harsh climate and soil conditions, sweet potato is a crop that copes well with the environmental stresses caused by climate change. However, due to the complexity of the sweet potato genome and the long breeding cycle, our ability to modify sweet potato starch is limited. In this review, we cover the recent development in sweet potato breeding, understanding of starch properties, and the progress in sweet potato genomics. We describe the applicational values of sweet potato starch in food, industrial products, and biofuel, in addition to the effects of starch properties in different industrial applications. We also explore the possibility of manipulating starch properties through biotechnological means, such as the CRISPR/Cas-based genome editing. The ability to target the genome with precision provides new opportunities for reducing breeding time, increasing yield, and optimizing the starch properties of sweet potatoes.

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“…Bio‐responsive (bio‐decomposable) polymeric assemblies have attracted attention in, e.g., drug and gene delivery, tissue engineering, and bioimaging applications. [ 21–24 ] A possible advantage of use of polymeric (diblock or triblock) assemblies is prolonged circulation of drugs in the body. In the present paper, bio‐decomposable assemblies mean assemblies that can decompose in biological conditions because either a part of the polymer or the entire polymer is biodegradable.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Biologically Decomposable Terpolymer Nanocapsules and Higher‐Order Nanoassemblies Using RCMP‐PISA

Sarkar

Lim

Goto

2021

Macro Chemistry & Physics

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Terpolymers are used to generate bio‐decomposable self‐assemblies. PEG‐PVL‐PGMA terpolymers are synthesized via a combination of organocatalyzed living radical polymerization (RCMP) with polymerization‐induced self‐assembly (PISA), generating vesicle, multicompartment micelle (MCM), and core‐compartmentalized worm (CCW), where PEG, PVL, and PGMA are poly(ethylene glycol) monomethyl ether, poly(δ‐valerolactone), and poly(glycidyl methacrylate) and PGMA is grown during the PISA. MCM and CCW are uniquely obtainable using terpolymers. The PVL segment is biodegradable, and the obtained assemblies are bio‐decomposable. Heavy metal‐free and sulfur‐free synthesis and bio‐decomposability of the assemblies are attractive features.

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Starch‐based nanoparticles: Stimuli responsiveness, toxicity, and interactions with food components

Cited by 63 publications

References 158 publications

A Review on Polymer and Lipid-Based Nanocarriers and Its Application to Nano-Pharmaceutical and Food-Based Systems

A Review on Polymer and Lipid-Based Nanocarriers and Its Application to Nano-Pharmaceutical and Food-Based Systems

Engineering Properties of Sweet Potato Starch for Industrial Applications by Biotechnological Techniques including Genome Editing

Synthesis of Biologically Decomposable Terpolymer Nanocapsules and Higher‐Order Nanoassemblies Using RCMP‐PISA

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