Hydrophobic modification of sodium alginate and its application in drug controlled release

Yao, Baoquan; Ni, Caihua; Xiong, Cheng Dong; Zhu, Caichao; Huang, Bo

doi:10.1007/s00449-009-0349-2

Cited by 62 publications

(36 citation statements)

References 18 publications

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“…The successive weight loss about 8.2 wt% (219~318 ºC) for MS0 and about 8.1 wt% (215~337 ºC) for MS10 can be attributed to the lactonization or transglucosidation of NaAlg. 33 The successive weight loss about 14.4 wt% (3184 29 ºC) for MS0 and about 13.5 wt% (337~435 ºC) for MS10 can be attributed to the breaking of C-O-C bonds in NaAlg chains and the formation of anhydride with the elimination of water molecule derived from the two neighboring carboxylic groups of the grafted PNaA chains. 34 The weight losses about 24.5 wt% between 429 and 485 ºC for MS0 and about 21.1 wt% between 435 and 489 ºC for MS10 are due to the breakage of main-chain scission and the destruction of crosslinked network structure.…”

Section: Methodsmentioning

confidence: 98%

A pH-sensitive composite hydrogel based on sodium alginate and medical stone: Synthesis, swelling, and heavy metal ions adsorption properties

Gao

Wang

2011

Macromol. Res.

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New pH-sensitive composite hydrogels were synthesized by free-radical graft copolymerization among sodium alginate (NaAlg), sodium acrylate (NaA), and medical stone (MS). Fourier transform infrared spectroscopy (FTIR), field emission scanning electron microscopy (FESEM), tronsmission electron microscopy (TEM), and thermogravimetric analysis (TGA) analyses confirmed that NaA was grafted onto the NaAlg chains and MS participate in polymerization by its active silanol groups, and the surface morphologies and thermal stability was clearly improved after incorporating MS. The swelling capacity and rate of the hydrogel were clearly enhanced by introducing MS, and the intriguing deswelling in gelatin solution and "overflowing" behaviors in dimethyl sulfoxide (DMSO) and glycerin solutions were observed. In addition, the composite hydrogels exhibited excellent adsorption capacity on heavy metal ions, which enhanced the adsorption of Ni 2+ , Cu 2+ , Zn 2+ and Cd 2+ ions by 10.4, 8.0, 23.0, and 14.3 fold compared to active carbon (AC), and by 17.3, 16.0, 38.3 and 23.8 fold compared to MS, respectively. The biopolymer-based composite hydrogel can be used as a potential water-saving material and candidate of AC for heavy metal removal.

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Section: Methodsmentioning

confidence: 98%

A pH-sensitive composite hydrogel based on sodium alginate and medical stone: Synthesis, swelling, and heavy metal ions adsorption properties

Gao

Wang

2011

Macromol. Res.

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“…[1,11,[13][14][15] It induces several biological effects such as anti-cholesterolaemic, [2,[16][17][18][19][20][21][22] antihypertensive, [23][24][25] antidiabetic, [2,17,19,26] anti-obesity, [17] antimicrobial, [25,27] anti-cancer, [2,28] anti-hepatotoxicity, [2] wound healing, [29,30] anticoagulation and coagulation [2] activity. The biological effects of alginate are related to its structural assembly and physicochemical attributes.…”

Section: Physicochemical and Biological Propertiesmentioning

confidence: 99%

“…The hydrogel made of graft copolymer expresses a lower swelling capacity due to collapse of N-isopropylacrylamide at specific temperature range thereby sustaining drug release. Alginate-g-poly(butyl methacrylate), a-methyl methacrylate-gsodium alginate [15,121] The microspheres formed from alginate conjugate can prolong drug release when compared to microspheres made of unmodified alginate. The alginate conjugate is more hydrophobic than the parent polymer.…”

Section: Graft Copolymer Physicochemical and Drug Release Propertiesmentioning

confidence: 99%

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Alginate graft copolymers and alginate–co-excipient physical mixture in oral drug delivery

Wong

2011

Journal of Pharmacy and Pharmacology

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Objectives Use of alginate graft copolymers in oral drug delivery reduces dosage form manufacture complexity with reference to mixing or coating processes. It is deemed to give constant or approximately steady weight ratio of alginate to covalently attached co-excipient in copolymers, thereby leading to controllable matrix processing and drug release. This review describes various grafting approaches and their outcome on oral drug release behaviour of alginate graft copolymeric matrices. It examines drug release modulation mechanism of alginate graft copolymers against that of co-excipients in non-grafted formulations. Key findings Drug release from alginate matrices can be modulated through using either co-excipients or graft copolymers via changing their swelling, erosion, hydrophobicity/ hydrophilicity, porosity and/or drug adsorption capacity. However, it is not known if the drug delivery performance of formulations prepared using alginate graft copolymers is superior to those incorporating graft-equivalent co-excipient physically in a dosage form without grafting but at the corresponding graft weight, owing to limited studies being available. Conclusions The value of alginate graft copolymers as the potential alternative to alginate-co-excipient physical mixture in oral drug delivery cannot be entirely defined by past and present research. Such an issue is complicated by the lack of green chemistry graft copolymer synthesis approach, high grafting process cost, complications and hazards, and the formed graft copolymers having unknown toxicity. Future research will need to address these matters to achieve a widespread commercialization and industrial application of alginate graft copolymers in oral drug delivery

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“…However, Alg has some weak points, including strong hydrophilicity, poor mechanical strength, low level of drug loading, and burst release, resulting in poor utilization of the drug. Therefore, the hydrophobic modification of Alg is an interesting and challenging work [6][7][8][9]. For example, Dellacherie et al [10] synthesized amphiphilic derivatives with tetrabutylammonium alginate and alkyl halide in homogeneous medium (dimethylsulfoxide, DMSO).…”

Section: Introductionmentioning

confidence: 99%

Synthesis of polyglycolic acid grafting from sodium alginate through direct polycondensation and its application as drug carrier

et al. 2015

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The hydrophobic modification of sodium alginate was realized by direct grafting with glycolic acid. The products, polyglycolic acid grafting from sodium alginate (Alg-g-PGA), self-assembled into nanoparticles of 200-250 nm in diameter through the interaction of hydrophobic PGA segments in the aqueous solution. Alg-g-PGA nanoparticles were cross-linked into hydrogel microspheres by calcium chloride, which was used as drug delivery vehicles for controlled release. The results of drug (ibuprofen) release model exhibited high drug loading rate and prolonged drug release speed of the Alg-g-PGA gel microspheres. The one-step method of synthesizing hydrophobically modified sodium alginate processes simple operation, mild condition, and low-cost raw material, resulting in its wide application of biological medicine in the future.

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Hydrophobic modification of sodium alginate and its application in drug controlled release

Cited by 62 publications

References 18 publications

A pH-sensitive composite hydrogel based on sodium alginate and medical stone: Synthesis, swelling, and heavy metal ions adsorption properties

A pH-sensitive composite hydrogel based on sodium alginate and medical stone: Synthesis, swelling, and heavy metal ions adsorption properties

Alginate graft copolymers and alginate–co-excipient physical mixture in oral drug delivery

Synthesis of polyglycolic acid grafting from sodium alginate through direct polycondensation and its application as drug carrier

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