Ion-Induced Nanopatterning of Bacterial Cellulose Hydrogels for Biosensing and Anti-Biofouling Interfaces

Arias, Sandra L.; Cheng, Ming Kit; Civantos, Ana; Devorkin, Joshua; Jaramillo, Camilo; Allain, Jean Paul

doi:10.1021/acsanm.0c01151

Cited by 21 publications

(40 citation statements)

References 40 publications

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“…The macromolecules hence organize in units producing subfibrils of 10–15 glucan chains that further assemble to form microfibrils, and finally microfibril bundles with diameter of 20–100 nm forms a gelatinous membrane. The microfiber diameter determines the properties and applications of the BC film [ 19 ]. Small diameters provide BC with high surface area for the interaction with biological molecules, and their characteristic stress strain nature closely mimic the inherent complexity and hierarchical structure of native tissues [ 31 ].…”

Section: Structure and Properties Of Bcmentioning

confidence: 99%

“…For example, BC subjected to ion-irradiation leads to the formation of self-organized nanostructures by reorganization of the fibrous surface structure ( Figure 6 ). In addition to this morphological transformation, ion irradiation of BC also induces chemical changes, including alteration of the atomic composition and crystallinity [ 19 ]. The properties of these nanopatterned surfaces make ion-irradiated BC a great candidate as a biocidal surface [ 20 , 97 ].…”

Section: Functionalization Of Bc Hydrogelsmentioning

confidence: 99%

“…Moreover, BC possesses high purity with high water retaining capacity, easily modifiable biodegradability, biocompatibility with facile production, purification and mouldability. The micromorphology of BC has a distinctive network of cellulose nanofiber consisting of unique feature rendering them as oil absorbents, fuel cell, catalyst and biomedical applications such as drug delivery, tissue engineering, skin repair and wound dressing [ 17 , 18 , 19 , 20 , 21 , 22 , 23 , 24 ].…”

Section: Introductionmentioning

confidence: 99%

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Surface Modification of Bacterial Cellulose for Biomedical Applications

Allain

Jaramillo

Restrepo

2022

IJMS

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Bacterial cellulose is a naturally occurring polysaccharide with numerous biomedical applications that range from drug delivery platforms to tissue engineering strategies. BC possesses remarkable biocompatibility, microstructure, and mechanical properties that resemble native human tissues, making it suitable for the replacement of damaged or injured tissues. In this review, we will discuss the structure and mechanical properties of the BC and summarize the techniques used to characterize these properties. We will also discuss the functionalization of BC to yield nanocomposites and the surface modification of BC by plasma and irradiation-based methods to fabricate materials with improved functionalities such as bactericidal capabilities.

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Section: Structure and Properties Of Bcmentioning

confidence: 99%

Section: Functionalization Of Bc Hydrogelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Surface Modification of Bacterial Cellulose for Biomedical Applications

Allain

Jaramillo

Restrepo

2022

IJMS

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“… 23,25,29,30 Another popular way to fabricate surface topographically patterned hydrogel is photolithographic patterning technique, where the mixed solution of photoinitiator and monomer are layered onto the photoactive hydrogel substrate and exposed to UV light through the photolithographic mask with desired patterns. 31,32 Other commonly used methods, such as nanoimprinting, 23,33–35 3D printing, 36–38 electrospinning, 39–41 multiphoton patterning, 42–45 e-beam lithographic patterning, 46,47 Self-assembly wrinkle technique, 48,49 ion-induced nanopatterning, 50 and swelling-induced patterning, 51,52 also have their own specific fabrication mechanism and process. In addition, many research groups have also developed effective methods to add patterns to hydrogel substrates.…”

Section: Techniques To Fabricate Patterned Hydrogelsmentioning

confidence: 99%

The effects of surface topography modification on hydrogel properties

2021

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Hydrogel has been an attractive biomaterial for tissue engineering, drug delivery, wound healing, and contact lens materials, due to its outstanding properties, including high water content, transparency, biocompatibility, tissue mechanical matching, and low toxicity. As hydrogel commonly possesses high surface hydrophilicity, chemical modifications have been applied to achieve the optimal surface properties to improve the performance of hydrogels for specific applications. Ideally, the effects of surface modifications would be stable, and the modification would not affect the inherent hydrogel properties. In recent years, a new type of surface modification has been discovered to be able to alter hydrogel properties by physically patterning the hydrogel surfaces with topographies. Such physical patterning methods can also affect hydrogel surface chemical properties, such as protein adsorption, microbial adhesion, and cell response. This review will first summarize the works on developing hydrogel surface patterning methods. The influence of surface topography on interfacial energy and the subsequent effects on protein adsorption, microbial, and cell interactions with patterned hydrogel, with specific examples in biomedical applications, will be discussed. Finally, current problems and future challenges on topographical modification of hydrogels will also be discussed.

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“…While it is well established that topographically nanopatterned surfaces can exhibit contact-killing properties by inducing the rupture of the bacterial plasma membrane, such patterns typically require comparatively high aspect ratios [134,135]. To achieve such high aspect ratios, Arias et al irradiated dried bacterial cellulose (BC) hydrogels with 1 keV Ar + ions at normal incidence [136]. With increasing ion fluence, this resulted in a transition of the original BC morphology that is composed of interlaced ribbons to self-standing spike-like nanostructures 50-70 nm in width and about 400 nm in height.…”

Section: Bacteriamentioning

confidence: 99%

Ion Beam Nanopatterning of Biomaterial Surfaces

Yang

Keller

2021

Applied Sciences

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Ion beam irradiation of solid surfaces may result in the self-organized formation of well-defined topographic nanopatterns. Depending on the irradiation conditions and the material properties, isotropic or anisotropic patterns of differently shaped features may be obtained. Most intriguingly, the periodicities of these patterns can be adjusted in the range between less than twenty and several hundred nanometers, which covers the dimensions of many cellular and extracellular features. However, even though ion beam nanopatterning has been studied for several decades and is nowadays widely employed in the fabrication of functional surfaces, it has found its way into the biomaterials field only recently. This review provides a brief overview of the basics of ion beam nanopatterning, emphasizes aspects of particular relevance for biomaterials applications, and summarizes a number of recent studies that investigated the effects of such nanopatterned surfaces on the adsorption of biomolecules and the response of adhering cells. Finally, promising future directions and potential translational challenges are identified.

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Ion-Induced Nanopatterning of Bacterial Cellulose Hydrogels for Biosensing and Anti-Biofouling Interfaces

Cited by 21 publications

References 40 publications

Surface Modification of Bacterial Cellulose for Biomedical Applications

Surface Modification of Bacterial Cellulose for Biomedical Applications

The effects of surface topography modification on hydrogel properties

Ion Beam Nanopatterning of Biomaterial Surfaces

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