Antibiofouling polymer interfaces: poly(ethylene glycol) and other promising candidates

Lowe, Sean E.; O'Brien-Simpson, Neil M; Connal, Luke A.

doi:10.1039/c4py01356e

Cited by 429 publications

(360 citation statements)

References 238 publications

(452 reference statements)

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“…Surfaces terminating in poly(ethylene glycol) chains or hydrophilic hydrogen bonding acceptor groups exhibit antifouling properties [40], and hence the biofilm resistance of our hydroxyl-rich, CW-primed PAA coatings was explored through incubation with E. coli ( Figure 5). Bacterial binding studies were undertaken by suspending PU samples in a fulcrum tube containing Luria Bertani (LB) media and E. Coli W3110 suspension under gentle agitation at 37 °C; the number of bacteria in suspension far exceeded that required to saturate the substrate geometric surface area.…”

Section: Resultsmentioning

confidence: 99%

Plasma-Generated Poly(allyl alcohol) Antifouling Coatings for Cellular Attachment

Watkins¹,

Lee

Moir³

et al. 2016

ACS Biomater. Sci. Eng.

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Conformal poly(allyl alcohol) (PAA) coatings were grown on a biomedical grade polyurethane scaffold using pulsed plasma polymerization of the allyl alcohol monomer. The creation of a continuous wave polymer primer layer increases the interfacial adhesion and stability of a subsequent pulsed plasma deposited PAA film. The resulting PAA coatings are strongly hydrophilic and remain unchanged following seven days incubation in biological media. Films prepared through this two-step process promote human dermal fibroblast cell culture, while resisting E. Coli biofilm formation.

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Section: Resultsmentioning

confidence: 99%

Plasma-Generated Poly(allyl alcohol) Antifouling Coatings for Cellular Attachment

Watkins¹,

Lee

Moir³

et al. 2016

ACS Biomater. Sci. Eng.

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“…Various nonfouling coatings using hydrophilic materials, such as PEG, PLA, or hydrogels, have been used to encapsulate the device, reducing inflammation and fibrosis [18,66,68]. Recently, ultra-low-fouling zwitterionic hydrogels implanted subcutaneously in mice for three months were found to resist the formation of a fibrous capsule and promote angiogenesis in the surrounding-healing tissue [63,69].…”

Section: Inflammatory and Foreign Body Responsesmentioning

confidence: 99%

Toward biomaterial-based implantable photonic devices

et al. 2017

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Optical technologies are essential for the rapid and efficient delivery of health care to patients. Efforts have begun to implement these technologies in miniature devices that are implantable in patients for continuous or chronic uses. In this review, we discuss guidelines for biomaterials suitable for use in vivo. Basic optical functions such as focusing, reflection, and diffraction have been realized with biopolymers. Biocompatible optical fibers can deliver sensing or therapeutic-inducing light into tissues and enable optical communications with implanted photonic devices. Wirelessly powered, light-emitting diodes (LEDs) and miniature lasers made of biocompatible materials may offer new approaches in optical sensing and therapy. Advances in biotechnologies, such as optogenetics, enable more sophisticated photonic devices with a high level of integration with neurological or physiological circuits. With further innovations and translational development, implantable photonic devices offer a pathway to improve health monitoring, diagnostics, and light-activated therapies.

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“…For organic matrix, called polymer-based nanocomposite, the most used polymers for preparation of nanocomposite coating can be listed as follows: epoxy [2][3][4][5][6][7], polyurethane [8,9], Chitosan [10,11], polyethylene glycol (PEG) [12][13][14][15], polyvinylidene fluoride (PVDF) [16], PANi [17][18][19], PPy [20][21][22][23], polystyrene [24], polyamic acid and polyimide [25], rubber-modified polybenzoxazine (PBZ) [26], polymers containing reactive trimethoxysilyl (TMOS) [27], pullulan [28], fluoroacrylic polymer [29,30], ethylene tetrafluoroethylene (ETFE) [31], polyacrylate [3], poly(N-vinyl carbazole) [32], polycarbonate [33], fluorinated polysiloxane [34], polyester [35], polyacrylic [36], polyvinyl alcohol (PVA) [37], polydimethylsiloxane [38], polyamide [39], and UV-curable polymers [40].…”

Section: Materials For Matrixmentioning

confidence: 99%

Nanocomposite Coatings: Preparation, Characterization, Properties, and Applications

Nguyen-Tri

Nguyen

Carriere

et al. 2018

International Journal of Corrosion

158

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Incorporation of nanofillers into the organic coatings might enhance their barrier performance, by decreasing the porosity and zigzagging the diffusion path for deleterious species. Thus, the coatings containing nanofillers are expected to have significant barrier properties for corrosion protection and reduce the trend for the coating to blister or delaminate. On the other hand, high hardness could be obtained for metallic coatings by producing the hard nanocrystalline phases within a metallic matrix. This article presents a review on recent development of nanocomposite coatings, providing an overview of nanocomposite coatings in various aspects dealing with the classification, preparative method, the nanocomposite coating properties, and characterization methods. It covers potential applications in areas such as the anticorrosion, antiwear, superhydrophobic area, self-cleaning, antifouling/antibacterial area, and electronics. Finally, conclusion and future trends will be also reported.

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Antibiofouling polymer interfaces: poly(ethylene glycol) and other promising candidates

Cited by 429 publications

References 238 publications

Plasma-Generated Poly(allyl alcohol) Antifouling Coatings for Cellular Attachment

Plasma-Generated Poly(allyl alcohol) Antifouling Coatings for Cellular Attachment

Toward biomaterial-based implantable photonic devices

Nanocomposite Coatings: Preparation, Characterization, Properties, and Applications

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