Formation-destruction conditions of an interpolymer complex between a poly(acrylic acid) gel and linear poly(ethylene glycol) in methanol

“…It should be remembered here that PEG with molecular weight of 7500 or lower does not form any complexes with linear PAA . For the complexation between cross-linked PAA an linear PEG, there is a definite range of molecular weight of PEG where the stable complexes exist, below and above which the conditions of complete complexation will be disrupted . The lower limit of molecular weight of PEG is equal to 6000, and the upper limit is equal to 100 000.…”

“…The complex formation in the poly(carboxylic acid) networks is quite different from that in linear poly(carboxylic acid)s. The conformational changes of the poly(methacrylic acid) (PMAA) or poly(acrylic acid) (PAA) networks in PEG solution were reported in refs −7. It was shown that the absorption of PEG leads to the contraction of the gel of PMAA or PAA, and the relative mass of the gel can be lowered by a factor of 1.5−3.0.…”

Shape Memory of Hydrogen-Bonded Polymer Network/Poly(ethylene glycol) Complexes

“…It should be remembered here that PEG with molecular weight of 7500 or lower does not form any complexes with linear PAA . For the complexation between cross-linked PAA an linear PEG, there is a definite range of molecular weight of PEG where the stable complexes exist, below and above which the conditions of complete complexation will be disrupted . The lower limit of molecular weight of PEG is equal to 6000, and the upper limit is equal to 100 000.…”

“…The complex formation in the poly(carboxylic acid) networks is quite different from that in linear poly(carboxylic acid)s. The conformational changes of the poly(methacrylic acid) (PMAA) or poly(acrylic acid) (PAA) networks in PEG solution were reported in refs −7. It was shown that the absorption of PEG leads to the contraction of the gel of PMAA or PAA, and the relative mass of the gel can be lowered by a factor of 1.5−3.0.…”

Shape Memory of Hydrogen-Bonded Polymer Network/Poly(ethylene glycol) Complexes

“…33,34 2.1.2 | Preparation of PEO-PAAc PEO that was dissolved in deionized water (1% v/v) was used to prepare PEO-PAAc nanogel. Different feed compositions of PEO and PAAc were used for polymerization to prepare PEO-PAAc through γ-radiation technique using γ-rays generated from 60 Co source at dose rate 1.9 kGy/h at room temperature. 33,35,36 2.2 | Conjugation of PEO-PAAc with FA Accurately, 30 mg of FA was directly added to 1 ml of the polymer nanogel followed by overnight stirring.…”

“…56,57 The bounding between PAAc and PEO transformed from physically three-dimensional networks molecule into physically three-dimensional covalently bound networks molecule. [58][59][60] 3.2 | Factors affecting and controlling the size of PEO-PAAc nanogel…”

Polyethylene oxide–polyacrylic acid–folic acid (PEO‐PAAc) nanogel as a ^99mTc targeting receptor for cancer diagnostic imaging

“…Also, the addition of 1.5 wt% PEG led to a high gel fraction at a low dose of 10 kGy. These hydrogels are assumed to have a semi-IPN structure, where PEG chains are diffused into the crosslinked network of PAA, forming a complex between PAA and PEG [24,25]. Inter-polymer complexes are known to be formed between a proton donor group like poly(carboxylic acids) and a proton acceptor group like PEG, poly(propylene oxide), poly(vinyl pyrolidone), poly(vinyl alcohol), etc.…”

Poly(acrylic acid)/polyethylene glycol hygrogel prepared by using gamma-ray irradiation for mucosa adhesion