Open-Cell Aliphatic Polyurethane Foams with High Content of Polysaccharides: Structure, Degradation, and Ecotoxicity

Skleničková, Kateřina; Vlčková, Věra; Abbrent, Sabina; Bujok, Sonia; Paruzel, Aleksandra; Kanizsová, Lívia; Trhlíková, Olga; Ambrožová, Jana Říhová; Halecky, Martin; Beneš, Hynek

doi:10.1021/acssuschemeng.1c01173

Cited by 15 publications

(5 citation statements)

References 49 publications

(82 reference statements)

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“…17 A broad and strong peak at 1100 cm −1 is attributed to ether bond C−O−C stretching. 18 These bands verified the typical polyurethane structure in PPU. In the spectrum of PHMG, there is a characteristic absorption peak at 1640 cm −1 , which can be attributed to the C�N stretching vibration.…”

Section: Structure Analysis and Cr Release Assaysupporting

confidence: 53%

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Development of Leather Fiber/Polyurethane Composite with Antibacterial, Wet Management, and Temperature-Adaptive Flexibility for Foot Care

Gong

Han

Zhang

et al. 2022

ACS Biomater. Sci. Eng.

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With the increase in the incidence of diabetes, the health care of the feet of diabetic patients becomes particularly important. Herein, leather fiber (LF) was utilized with waterborne polyhexamethylene guanidine-embedded polyurethane (PPU) to prepare network-interpenetrating LF/PPU composites as potential foot care material via a facile “paper-making” pathway. Due to the coating of PPU on LF, the release of chromium in sweat is significantly reduced. The fibrous structure endows LF/PPU with temporary hydrophobicity, air permeability, and moisture absorption and retention. Such wet management capacity can help to maintain a dry environment inside a shoe model. Moreover, the presence of PPU improves the durability of LF/PPU, and the synergistic effect of LF and PPU leads to temperature adaptive flexibility of LF/PPU, thus providing the proper strength to protect feet at low temperatures while offering flexibility in hot environments to facilitate movement. Furthermore, LF/PPU possesses antibacterial and antimildew properties, which are still effective after repeated friction. This study offers a facile and eco-friendly route to develop multifunctional composites for health wear products, especially for foot care.

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Section: Structure Analysis and Cr Release Assaysupporting

confidence: 53%

“…The peak at 1535 cm –1 is associated with the bending vibration of N–H (from −CONH−) . A broad and strong peak at 1100 cm –1 is attributed to ether bond C–O–C stretching . These bands verified the typical polyurethane structure in PPU.…”

Section: Resultsmentioning

confidence: 58%

Development of Leather Fiber/Polyurethane Composite with Antibacterial, Wet Management, and Temperature-Adaptive Flexibility for Foot Care

Gong

Han

Zhang

et al. 2022

ACS Biomater. Sci. Eng.

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“…[24] The presence of these characteristic peaks indicated the formation of urethane. [25,26] Additionally, the intensive peaks located at 765 cm À1 , 910 cm À1 , and 968 cm À1 were assigned to the traces of cis-1,4 isomers, 1,2-vinyl and trans-1,4 isomers, respectively. [27] In the FT-IR spectra of FPU, the peak at 1264 cm À1 was ascribed to the Si-CH 3 group.…”

Section: Ft-ir Analysismentioning

confidence: 99%

Fabrication and characterization of novel polyurethane Encapsulant with excellent underwater acoustic transparency and hydrophobicity

Zhang

Yan

et al. 2022

Polymer Engineering & Sci

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“…Tailor-made polyester polyols bearing hydrolyzable ester groups are key for the fabrication of PUR foams with enhanced degradability . Additionally, introducing hydrophilic entities such as glycol chains into the PUR structure can further accelerate the degradation rate. − …”

Section: Introductionmentioning

confidence: 99%

Biobased Ultralow-Density Polyurethane Foams with Enhanced Recyclability

Gotkiewicz,

Kirpluks,

Walterová

et al. 2024

ACS Sustainable Chem. Eng.

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Polyurethane (PUR) foams are widely used in many engineering applications, but their efficient recycling has remained a major challenge for many years. This study presents a novel strategy of incorporating hydrolyzable ester units into the PUR structure to enhance PUR foam recyclability. The present ecodesign concept of PUR materials enables fully the replacement of petrochemical polyols with biobased alternatives and production of ultralow-density (16 kg•m −3 ) PUR foams. To reach this target, a series of low-function polyols based on succinic acid (SA) were first synthesized. Their subsequent use in combination with a highfunctional biobased tall oil-derived polyol led to the production of highly homogenous semirigid, partly open-cell PUR foams with outstanding structural, thermal, and mechanical properties. Additionally, the study shows that the incorporation of SA-polyols with hydrolyzable ester linkages into the PUR foams significantly enhances their recyclability via glycolysis, proving their potential in contributing to a circular economy and addressing plastic waste concerns.

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Open-Cell Aliphatic Polyurethane Foams with High Content of Polysaccharides: Structure, Degradation, and Ecotoxicity

Cited by 15 publications

References 49 publications

Development of Leather Fiber/Polyurethane Composite with Antibacterial, Wet Management, and Temperature-Adaptive Flexibility for Foot Care

Development of Leather Fiber/Polyurethane Composite with Antibacterial, Wet Management, and Temperature-Adaptive Flexibility for Foot Care

Fabrication and characterization of novel polyurethane Encapsulant with excellent underwater acoustic transparency and hydrophobicity

Biobased Ultralow-Density Polyurethane Foams with Enhanced Recyclability

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