Stimuli Responsive Hydrogels: NIPAM/AAm/Carboxylic Acid Polymers

Işıkver, Yasemin; Saraydın, Dursun

doi:10.2478/achi-2019-0012

Cited by 5 publications

(7 citation statements)

References 41 publications

(60 reference statements)

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“…In general, acrylamide-based compounds are well known for their absorptive and medicinal properties. In line with our research interest in AAm based materials, [17][18][19][20][21][22] in this article we report the copolymerization of NIPAAm with AAm. The present study aims to develop N-isopropyl acrylamide/acrylamide; (NI-PAAm/AAm) based hydrogels with pH and temperature sensitivities and higher swelling properties.…”

Section: Introductionsupporting

confidence: 68%

“…In the FTIR spectra of the SHs (Figure 2), the typical absorption bands for NIPAAm, AAm, and A or M units can be seen about 3600-3100 cm −1 as broad bands for secondary NH amide, between 2980 and 2878 cm −1 for CH stretching frequencies for isopropyl groups, and at 1670 cm −1 a strong C=O amide I band, and at 1550 cm −1 for another strong amide II band. The peak around 1400-1300 cm −1 belongs to −CH(CH3)2 group in isopropylgroups [18,20,24]. From this spectral analysis, it can be concluded that a polymeric network is formed, because of the functional groups of each component of the hydrogel units: NIPAAm, AAm, and A or M monomers with NBis.…”

Section: Ftir Analysismentioning

confidence: 81%

“…In addition, the values found as a result of applying the Jerez correction method to the values found by the Freeman Carrol method are more realistic [18,20].…”

mentioning

confidence: 94%

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Smart Hydrogels: Preparation, Characterization, and Determination of Transition Points of Crosslinked N-Isopropyl Acrylamide/Acrylamide/Carboxylic Acids Polymers

Işıkver

Saraydın

2021

Gels

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Smart hydrogels (SH) were prepared by thermal free radical polymerization of N-isopropyl acrylamide (NIPAAm), acrylamide (AAm) with acrylic acid (A) or maleic acid (M), and N, N′-methylene bisacrylamide. Spectroscopic and thermal characterizations of SHs were performed using FTIR, TGA, and DSC. To determine the effects of SHs on swelling characteristics, swelling studies were performed in different solvents, solutions, temperatures, pHs, and ionic strengths. In addition, cycle equilibrium swelling studies were carried out at different temperatures and pHs. The temperature and pH transition points of SHs are calculated using a sigmoidal equation. The pH transition points were calculated as 5.2 and 4.2 for SH-M and SH-A, respectively. The NIPAAm/AAm hydrogel exhibits a critical solution temperature (LCST) of 28.35 °C, while the SH-A and SH-M hydrogels exhibit the LCST of 34.215 °C and 28.798 °C, respectively, and the LCST of SH-A is close to the body. temperature. Commercial (CHSA) and blood human serum albumin (BHSA) were used to find the adsorption properties of biopolymers on SHs. SH-M was the most efficient SH, adsorbing 49% of CHSA while absorbing 16% of BHSA. In conclusion, the sigmoidal equation or Gaussian approach can be a useful tool for chemists, chemical engineers, polymer and plastics scientists to find the transition points of smart hydrogels.

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Section: Introductionsupporting

confidence: 68%

Section: Ftir Analysismentioning

confidence: 81%

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Smart Hydrogels: Preparation, Characterization, and Determination of Transition Points of Crosslinked N-Isopropyl Acrylamide/Acrylamide/Carboxylic Acids Polymers

Işıkver

Saraydın

2021

Gels

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“…Temperature, light Mesogen-driven network deformation Oseen, 1933;Frank, 1958;Ericksen, 1961;Stephen and Straley, 1974;De Gennes and Prost, 1993;Terentjev, 1996, 2007;Finkelmann et al, 2001;Ikeda et al, 2007;Ohm et al, 2012;Jiang et al, 2013;White and Broer, 2015;Yakacki et al, 2015;Guin et al, 2018;McBride et al, 2018;Ula et al, 2018;Shang et al, 2019 Gels Hydrogels Humidity, other fluids Swelling-driven response Flory, 1950;Tanaka and Fillmore, 1979;Hong et al, 2008;Zhu et al, 2018;Agarwal et al, 2019 PNIPAm Humidity, other fluids, temperature change Temperaturedependent swelling-driven response Afroze et al, 2000;Yan and Tsujii, 2005;Deshmukh et al, 2013;Li et al, 2015;Vernerey and Shen, 2017;Işikver and Saraydin, 2019;Shen et al, 2019;Wang et al, 2020 PNIPAm, poly(N-isopropylacrylamide).…”

Section: Polymers With Conformational Instabilitiesmentioning

confidence: 99%

“…Among the family of gels, poly(N-isopropylacrylamide) (also indicated as PNIPAA or PNIPAm) forms a three-dimensional hydrogel when cross-linked with N, N ′ -methylene-bisacrylamide (MBAm) or N, N ′ -cystamine-bis-acrylamide (CBAm) (Işikver and Saraydin, 2019). It is a gel whose fluid absorption capability is heavily influenced by the temperature; in fact, it is a temperature-responsive polymer showing a reversible lower critical solution temperature (LCST) phase transition from a swollen state to a shrunken dehydrated one (Yan and Tsujii, 2005).…”

Section: Temperature-sensitive Hydrogelsmentioning

confidence: 99%

Smart Polymers for Advanced Applications: A Mechanical Perspective Review

2020

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Responsive materials, as well as active structural systems, are today widely used to develop unprecedented smart devices, sensors, or actuators; their functionalities come from the ability to respond to environmental stimuli with a detectable reaction. Depending on the responsive material under study, the triggering stimuli can have a different nature, ranging from physical (temperature, light, electric or magnetic field, mechanical stress, etc.), chemical (pH, ligands, etc.), or biological (enzymes, etc.) type. Such a responsiveness can be obtained by properly designing the meso-or macroscopic arrangement of the constitutive elements, as occurs in metamaterials, or can be obtained by using responsive materials per se, whose responsiveness comes from the chemistry underlying their microstructure. In fact, when the responsiveness at the molecular level is properly organized, the nanoscale response can be collectively detected at the macroscale, leading to a responsive material. In the present article, we review the enormous world of responsive polymers, by outlining the main features, characteristics, and responsive mechanisms of smart polymers and by providing a mechanical modeling perspective, both at the molecular as well as at the continuum scale level. We aim at providing a comprehensive overview of the main features and modeling aspects of the most diffused smart polymers. The quantitative mechanical description of active materials plays a key role in their development and use, enabling the design of advanced devices as well as to engineer the materials' microstructure according to the desired functionality.

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Facile fabrication and characterization of high-performance Borax-PVA hydrogel

Wang

Shen

et al. 2021

J Sol-Gel Sci Technol

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Stimuli Responsive Hydrogels: NIPAM/AAm/Carboxylic Acid Polymers

Cited by 5 publications

References 41 publications

Smart Hydrogels: Preparation, Characterization, and Determination of Transition Points of Crosslinked N-Isopropyl Acrylamide/Acrylamide/Carboxylic Acids Polymers

Smart Hydrogels: Preparation, Characterization, and Determination of Transition Points of Crosslinked N-Isopropyl Acrylamide/Acrylamide/Carboxylic Acids Polymers

Smart Polymers for Advanced Applications: A Mechanical Perspective Review

Facile fabrication and characterization of high-performance Borax-PVA hydrogel

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