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1. Fouling of mammalian hair fibres exposed to a titanium dioxide colloidal suspension

   https://doi.org/10.1098/rsif.2021.0904  

   Krsmanovic, Milos; Ali, Hessein; Biswas, Dipankar; Ghosh, Ranajay; Dickerson, Andrew K. (April 2022, Journal of The Royal Society Interface)

   Fouling of surfaces in prolonged contact with liquid often leads to detrimental alteration of material properties and performance. A wide range of factors which include mass transport, surface properties and surface interactions dictate whether foulants are able to adhere to a surface. Passive means of foulant rejection, such as the microscopic patterns, have been known to develop in nature. In this work, we investigate the anti-fouling behaviour of animal fur and its apparent passive resistance to fouling. We compare the fouling performance of several categories of natural and manufactured fibres, and present correlations between contamination susceptibility and physio-mechanical properties of the fibre and its environment. Lastly, we present a correlation between the fouling intensity of a fibre and the cumulative impact of multiple interacting factors declared in the form of a dimensionless group. Artificial and natural hair strands exhibit comparable anti-fouling behaviour in flow, however, the absence of flow improves the performance of some artificial fibres. Among the plethora of factors affecting the fouling of fur hair, the dimensionless groups we present herein provide the best demarcation between fibres of different origin. 

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2. Rational Design of Transparent Nanowire Architectures with Tunable Geometries for Preventing Marine Fouling

   https://doi.org/10.1002/admi.202000672  

   Wang, Jing; Lee, Sudarat; Bielinski, Ashley_R; Meyer, Kevin_A; Dhyani, Abhishek; Ortiz‐Ortiz, Alondra_M; Tuteja, Anish; Dasgupta, Neil_P (July 2020, Advanced Materials Interfaces)

   Abstract Marine biofouling is a sticky global problem that hinders maritime industries. Various microscale surface structures inspired by marine biological species have been explored for their anti‐fouling properties. However, systematic studies of anti‐marine‐fouling performance on surface architectures with characteristic length‐scales spanning from below 100 nm to greater than 10 µm are generally lacking. Herein, a study on the rational design and fabrication of ZnO/Al₂O₃core–shell nanowire architectures with tunable geometries (length, spacing, and branching) and surface chemistry is presented. The ability of the nanowires to significantly delay or prevent marine biofouling is demonstrated. Compared to planar surfaces, hydrophilic nanowires can reduce fouling coverage by up to ≈60% after 20 days. The fouling reduction mechanism is mainly due to two geometric effects: reduced effective settlement area and mechanical cell penetration. Additionally, superhydrophobic nanowires can completely prevent marine biofouling for up to 22 days. The nanowire surfaces are transparent across the visible spectrum, making them applicable to windows and oceanographic sensors. Through the rational control of surface nano‐architectures, the coupled relationships between wettability, transparency, and anti‐biofouling performance are identified. It is envisioned that the insights gained from the work can be used to systematically design surfaces that reduce marine biofouling in various industrial settings. 

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3. Multi-functional low-cost epoxy based nanocomposite corrosion resistant coatings

   Nawani, Pranav; Gese, Natalie (June 2017, MegaRust 2017 Organized by the American Society of Naval Engineers)

   Corrosion is a significant global issue, resulting in high maintenance and repair costs. Long term structural integrity of metal and its products is directly dependent on its anti-corrosive properties. Surfaces exposed to marine environments are prone to microbial attachment followed by biofilm formation, resulting in bio-fouling. Hence coatings are used to protect the surfaces against corrosion and biofilm formation. Currently various organic coatings are used to protect metals and the cost of these coatings is directly dependent upon the cost of the fillers used to impart specific properties. Conventionally fillers such as zinc, Titanium and Silver based compounds are used in coatings for corrosion and/or microbial protection of surfaces, which are expensive. The underlying issue with using these compounds as fillers is that they can adversely effect mechanical and barrier properties, due to which they are used as a base coat and additional fillers are used to compensate for such property losses. Most of these coatings need an enhanced anti-microbial surface and improvement in their barrier efficacy against water/moisture, oxygen, and chloride ions. Hence it is imperative to develop low-cost fillers that will enhance both active & passive corrosion resistance properties, prevent microbial attachment on the surfaces and will not degrade any polymeric properties. In this work, ASL is developing a multi-functional low cost epoxy-clay nanocomposite coating, for microbial and corrosion resistance. Multi-functional coatings are developed using a multi-component approach, where the innovation lays in deriving the benefits of various fillers through a combinatorial approach to synergistic harvesting of functionality and vigor. The primary filler is a naturally abundant clay material and, owing to their sheet like morphology and layered structures, their surface can be modified to achieve the desired property enhancements. Sheet like morphology enhances polymer filler interactions, resulting in enhanced mechanical and reduced barrier properties. The presence of clay in the coating materials will mitigate the impact of moisture and chloride ions (in marine environment) providing passive protection to the coated surface. Modification of clay with transition metal ions (TMI) enhances corrosion resistance properties of coatings. 

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4. Surfactant‐mediated mobile droplets on smooth hydrophilic surfaces

   https://doi.org/10.1002/dro2.70004  

   Alipanahrostami, Mohammad; McCoy, Tyler R; Li, Mi; Wang, Wei (April 2025, Droplet)

   Abstract Achieving mobile liquid droplets on solid surfaces is crucial for various practical applications, such as self‐cleaning and anti‐fouling coatings. The last two decades have witnessed remarkable progress in designing functional surfaces, including super‐repellent surfaces and lubricant‐infused surfaces, which allow droplets to roll/slide on the surfaces. However, it remains a challenge to enable droplet motion on hydrophilic solid surfaces. In this work, we demonstrate mobile droplets containing ionic surfactants on smooth hydrophilic surfaces that are charged similarly to surfactant molecules. The ionic surfactant‐laden droplets display ultra‐low contact angle and ultra‐low sliding angle simultaneously on the hydrophilic surfaces. The sliding of the droplet is enabled by the adsorbed surfactant ahead of three‐phase contact line, which is regulated by the electrostatic interaction between ionic surfactant and charged solid surface. The droplet can maintain its motion even when the hydrophilic surface has defects. Furthermore, we demonstrate controlled manipulation of ionic surfactant‐laden droplets on hydrophilic surfaces with different patterns. We envision that our simple technique for achieving mobile droplets on hydrophilic surfaces can pave the way to novel slippery surfaces for different applications. 

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5. A Facile Surface Modification Strategy for Antibody Immobilization on 3D-Printed Surfaces

   https://doi.org/10.3390/bios15040211  

   Binkley, Brandi; Li, Peng (April 2025, Biosensors)

   3D-printed microdevices have become increasingly important to the advancement of point-of-care (POC) immunoassays. Despite its great potential, using 3D-printed surfaces on the solid support for immunorecognition has been limited due to the non-ideal adsorption properties for many photocurable resins. In this work, we report a simple surface modification protocol that works for diverse commercial photocurable resins, improving ELISAs performed directly on 3D-printed devices. This surface modification strategy involves surface activation via air plasma followed by the one-step incubation of GLYMO-labeled streptavidin. We successfully immobilized biotinylated anti-activin A antibodies on the 3D-printed surfaces and performed the complete ELISA protocol on the 3D-printed surfaces. We demonstrated that this protocol achieved an improved performance over passive adsorption for ELISAs. The present method is also compatible with diverse commercial resins and works with both microwells and microchannels. Finally, this method demonstrated a comparable limit of detection to the ELISA performed using commercial microwells. We believe the simplicity and broad compatibility of the present surface modification strategy will facilitate the development of 3D-printed POC ELISA devices. 

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