Development of Freeze‐resistant Aluminum Surfaces by Tannic Acid Coating and Subsequent Immobilization of Antifreeze Proteins

Jeong, Yeonwoo; Jeong, Seokyung; Nam, Yoon Kwon; Kang, Sung Min

doi:10.1002/bkcs.11406

Cited by 5 publications

(5 citation statements)

References 32 publications

(42 reference statements)

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“…Tannic acid (TA) and its derivatives are proven to be effective for biocoating applications. The complex formation of TA's galloyl groups and protein's amino groups resulted in a promising biocompatible adhesive material (Sileika et al, 2013;Jeong et al, 2018). Moreover, the bioconjugation technique via biomaterials such as polydopamine (PDA) (3-glycidoxypropyl) methyldimethoxysilane (GOPTS), and biopoly amino acids such as poly l lysine (Niazi et al, 2021) or metal bonding repeating polypeptides (Brown, 1997) are also known to be efficacious methods.…”

Section: Applications Afps Coatingmentioning

confidence: 99%

“…Bioconjugation of Aluminum-binding peptide (ABP) with antifreeze proteins from Antarctic marine diatom for metal coating purpose Liu et al (2016) Incorpration of a hyperactive insect AFP from the beetle Microdera punctipennis dzungarica (MpdAFP) into polydopamine (PDA) and (3-glycidoxypropyl)methyldimethoxysilane (GOPTS) to prepare an ice-binding face (IBF) and non-icebinding face (NIBF) for an anti-icing coating on silicon surface Esser- Kahn et al (2010) Conjugated AFP-polymer were immobilized via commercially glass slides with coated aldehyde groups Ejima et al (2013) Novel organic polymer of polyphenol Tannic acid meld with Fe III followed by pH change from acid to alkali results in TA-Fe3+ octahedral complex that can adhere to many diverse solid substrates Jeong et al (2018) TA coating on solid substrates and later AFP immobilization on aluminum surface. The Al surface was treated with a musselinspired polymer, polydopamine (pDA) Zuo et al (2005) Novel peptides capable of binding to aluminum and mild steel to protect them from deterioration.…”

Section: Gwak Et Al (2015)mentioning

confidence: 99%

See 1 more Smart Citation

Antifreeze Proteins: A Tale of Evolution From Origin to Energy Applications

Gharıb

Saeidiharzand

Sadaghiani

et al. 2022

Front. Bioeng. Biotechnol.

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Icing and formation of ice crystals is a major obstacle against applications ranging from energy systems to transportation and aviation. Icing not only introduces excess thermal resistance, but it also reduces the safety in operating systems. Many organisms living under harsh climate and subzero temperature conditions have developed extraordinary survival strategies to avoid or delay ice crystal formation. There are several types of antifreeze glycoproteins with ice-binding ability to hamper ice growth, ice nucleation, and recrystallization. Scientists adopted similar approaches to utilize a new generation of engineered antifreeze and ice-binding proteins as bio cryoprotective agents for preservation and industrial applications. There are numerous types of antifreeze proteins (AFPs) categorized according to their structures and functions. The main challenge in employing such biomolecules on industrial surfaces is the stabilization/coating with high efficiency. In this review, we discuss various classes of antifreeze proteins. Our particular focus is on the elaboration of potential industrial applications of anti-freeze polypeptides.

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Section: Applications Afps Coatingmentioning

confidence: 99%

Section: Gwak Et Al (2015)mentioning

confidence: 99%

Antifreeze Proteins: A Tale of Evolution From Origin to Energy Applications

Gharıb

Saeidiharzand

Sadaghiani

et al. 2022

Front. Bioeng. Biotechnol.

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show abstract

“…[40] Moreover, Jeonn et al prepared anti-icing surfaces by employing AFPs on PDA-treated aluminum with the use of Tannic acid (TA) coating. [41] Aluminum is the third most abundant element on the Earth and a highly produced metal after steel. [42,43] It has low density, is nontoxic, has high thermal conductivity, and can be easily cast, machined, and formed.…”

Section: Introductionmentioning

confidence: 99%

“…prepared anti‐icing surfaces by employing AFPs on PDA‐treated aluminum with the use of Tannic acid (TA) coating. [ 41 ]…”

Section: Introductionmentioning

confidence: 99%

Development and Implementation of Microbial Antifreeze Protein Based Coating for Anti‐Icing

Muganlı

Saeidiharzand

Rekuvienė

et al. 2023

Adv Materials Inter

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Ice formation on a solid surface is a major challenge in industrial applications, it causes higher energy consumption and performance deterioration and may lead to catastrophic results. The preparation of anti‐icing surfaces to prohibit ice accumulation on a surface is crucial to reduce operational costs and to extend the surface's lifetime. The utilization of cryoprotectants to obtain anti‐icing surfaces is an effective method and is applicable in multiple fields. Antifreeze proteins (AFPs) are natural cryoprotectants to obtain anti‐icing surfaces, which have the ability to decrease the freezing point and to prevent ice‐crystal growth via thermal hysteresis (TH) and ice recrystallization inhibition (IRI). This study reports the molecular cloning, expression, and production of AFP protein from Escherichia coli (E. Coli). This wok also demonstrates the activity of coated AFP on aluminum surfaces. The expressed AFP is immobilized on aluminum surfaces treated by oxygen plasma. The coated AFP exhibits promising antifreeze activity with a high anti‐icing ability on aluminum surfaces in the size of evaporator fins (40 × 40 cm). The outcome of this study provides new insights into the biotechnological implementation of AFPs to various industrial applications for energy‐saving and higher performance.

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“…Inspired by the mechanism, synthetic polyphenols developed from phenolic building blocks have been introduced. Polydopamine [9][10][11][12][13], poly(L-DOPA) [14], poly(norepinephrine) [15][16][17], poly(gallic acid) [18], and poly(tannic acid) [19][20][21] are typical examples; the materials showing similar physicochemical properties to the natural polyphenols have been successfully used as adhesives, optical materials, sensors, and other bioinspired applications [12][13][14]. Especially due to their excellent biocompatibility [22,23], biodegradability [24], and wet-adhesion abilities [25,26], the self-assembled phenolic building blocks have been successfully utilized as biomaterials, such as nanomedicine, antimicrobial coating, and tissue scaffold (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Crosslinking Mechanisms of Phenol, Catechol, and Gallol for Synthetic Polyphenols: A Comparative Review

Choi

Lee

2022

Applied Sciences

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Since the first introduction of a synthetic polyphenol called polydopamine, both it and its derivatives have received significant attention from material scientists owing to their unique functionality. In particular, synthetic polyphenols have been utilized as interfacial engineering tools; many important review papers have been published regarding this topic. However, despite those that have focused on the applicability of synthetic polyphenols, fundamental aspects of crosslinking mechanisms and resultant characteristics have still been overlooked in the community. This review covers the mechanisms for building synthetic polyphenols, which are dependent on the number of hydroxyl groups of each phenolic building block. The inherent physicochemical properties of the developed polyphenolic materials are discussed in depth herein. This review can provide guidelines for selecting appropriate phenolic building blocks when designing relevant polyphenolic biomaterials.

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Development of Freeze‐resistant Aluminum Surfaces by Tannic Acid Coating and Subsequent Immobilization of Antifreeze Proteins

Cited by 5 publications

References 32 publications

Antifreeze Proteins: A Tale of Evolution From Origin to Energy Applications

Antifreeze Proteins: A Tale of Evolution From Origin to Energy Applications

Development and Implementation of Microbial Antifreeze Protein Based Coating for Anti‐Icing

Crosslinking Mechanisms of Phenol, Catechol, and Gallol for Synthetic Polyphenols: A Comparative Review

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