Polymer-Based Marine Antifouling and Fouling Release Surfaces: Strategies for Synthesis and Modification

Literature Cited

1. 1.

   Abarzua S, Jakubowski S. 1995. Biotechnological investigation for the prevention of biofouling. I. Biological and biochemical principles for the prevention of biofouling. Mar. Ecol. Prog. Ser. 123:301–12
   [Google Scholar]
2. 2.

   Callow JA, Callow ME. 2011. Trends in the development of environmentally friendly fouling-resistant marine coatings. Nat. Commun. 2:244
   [Google Scholar]
3. 3.

   Callow ME, Callow JA, Pickett-Heaps JD, Wetherbee R 1997. Primary adhesion of Enteromorpha (Chlorophyta, Ulvales) propagules: quantitative settlement studies and video microscopy. J. Phycol. 33:938–47
   [Google Scholar]
4. 4.

   Osman RW, Whitlatch RB. 1995. The influence of resident adults on larval settlement: experiments with four species of ascidians. J. Exp. Mar. Biol. Ecol. 190:2199–220
   [Google Scholar]
5. 5.

   Lindholdt A, Dam-Johansen K, Olsen SM, Yebra DM, Kiil S 2015. Effects of biofouling development on drag forces of hull coatings for ocean-going ships: a review. J. Coat. Technol. Res. 12:3415–44
   [Google Scholar]
6. 6.

   Schultz MP, Bendick JA, Holm ER, Hertel WM 2011. Economic impact of biofouling on a naval surface ship. Biofouling 27:187–98
   [Google Scholar]
7. 7.

   Drake JM, Lodge DM. 2007. Hull fouling is a risk factor for intercontinental species exchange in aquatic ecosystems. Aquat. Invasions 2:2121–31
   [Google Scholar]
8. 8.

   Hewitt CL, Gollasch S, Minchin D 2009. The vessel as a vector—biofouling, ballast water and sediments. Biological Invasions in Marine Ecosystems G Rilov, JA Crooks 117–31 Berlin: Springer
   [Google Scholar]
9. 9.

   Minchin D, Gollasch S. 2003. Fouling and ships’ hulls: how changing circumstances and spawning events may result in the spread of exotic species. Biofouling 19:Suppl. 1111–22
   [Google Scholar]
10. 10.

    Godwin LS. 2003. Hull fouling of maritime vessels as a pathway for marine species invasions to the Hawaiian Islands. Biofouling 19:Suppl. 1123–31
    [Google Scholar]
11. 11.

    Lim JY, Tay TS, Lim CS, Lee SSC, Teo SLM, Tan KS 2018. Mytella strigata (Bivalvia: Mytilidae): an alien mussel recently introduced to Singapore and spreading rapidly. Molluscan Res 38:3170–86
    [Google Scholar]
12. 12.

    Woods Hole Oceanogr. Inst 1952. The history of the prevention of fouling. Marine Fouling and Its Prevention211–22 Washington, DC: Bur. Ships Navy Dep.
    [Google Scholar]
13. 13.

    Horiguchi T. 2009. Mechanism of imposex induced by organotins in gastropods. Ecotoxicology of Antifouling Biocides T Arai, H Harino, M Ohji, W Langston 111–24 Tokyo: Springer Jpn.
    [Google Scholar]
14. 14.

    Readman JW. 2006. Development, occurrence and regulation of antifouling paint biocides: historical review and future trends. Handb. Environ. Chem. 5:1–15
    [Google Scholar]
15. 15.

    Champ MA. 2003. Economic and environmental impacts on ports and harbors from the convention to ban harmful marine anti-fouling systems. Mar. Pollut. Bull. 46:8935–40
    [Google Scholar]
16. 16.

    Chambers LD, Stokes KR, Walsh FC, Wood RJK 2006. Modern approaches to marine antifouling coatings. Surf. Coat. Technol. 201:3642–52
    [Google Scholar]
17. 17.

    Detty MR, Ciriminna R, Bright FV, Pagliaro M 2013. Environmentally benign sol-gel antifouling and foul-releasing coatings. Acc. Chem. Res. 47:2678–87
    [Google Scholar]
18. 18.

    Matthiessen P, Reed J, Johnsonà M 1999. Sources and potential effects of copper and zinc concentrations in the estuarine waters of Essex and Suffolk, United Kingdom. Mar. Pollut. Bull. 38:10908–20
    [Google Scholar]
19. 19.

    McClay T, Zabin C, Davidson I, Young R, Elam D 2015. Vessel biofouling prevention and management options report Rep., US Dep. Homel. Secur. Washington, DC:
20. 20.

    Ytreberg E, Karlsson J, Eklund B 2010. Comparison of toxicity and release rates of Cu and Zn from anti-fouling paints leached in natural and artificial brackish seawater. Sci. Total Environ. 408:2459–66
    [Google Scholar]
21. 21.

    Thomas K. 2001. The environmental fate and behaviour of antifouling paint booster biocides: a review. Biofouling 17:173–86
    [Google Scholar]
22. 22.

    Oliveira IB, Groh KJ, Schönenberger R, Barroso C, Thomas KV, Suter MJF 2017. Toxicity of emerging antifouling biocides to non-target freshwater organisms from three trophic levels. Aquat. Toxicol. 191:164–74
    [Google Scholar]
23. 23.

    Bellas J. 2006. Comparative toxicity of alternative antifouling biocides on embryos and larvae of marine invertebrates. Sci. Total Environ. 367:573–85
    [Google Scholar]
24. 24.

    Overturf CL, Wormington AM, Blythe KN, Gohad NV, Mount AS, Roberts AP 2015. Toxicity of nor-adrenaline, a novel anti-biofouling component, to two non-target zooplankton species, Daphnia magna and Ceriodaphnia dubia. Comp. Biochem. Physiol. C Toxicol. Pharmacol. 171:49–54
    [Google Scholar]
25. 25.

    Singh RP, Reddy CRK. 2014. Seaweed-microbial interactions: key functions of seaweed-associated bacteria. FEMS Microbiol. Ecol. 88:2213–30
    [Google Scholar]
26. 26.

    Hmelo LR. 2017. Quorum sensing in marine microbial environments. Annu. Rev. Mar. Sci. 9:257–81
    [Google Scholar]
27. 27.

    Chabot R, Bourget E. 1988. Influence of substratum heterogeneity and settled barnacle density on the settlement of cypris larvae. Mar. Biol. 97:45–56
    [Google Scholar]
28. 28.

    Prime KL, Whitesides GM. 1993. Adsorption of proteins onto surfaces containing end-attached oligo(ethylene oxide): a model system using self-assembled monolayers. J. Am. Chem. Soc. 115:10714–21
    [Google Scholar]
29. 29.

    Ekblad T, Bergström G, Ederth T, Conlan SL, Mutton R et al. 2008. Poly(ethylene glycol)-containing hydrogel surfaces for antifouling applications in marine and freshwater environments. Biomacromolecules 9:102775–83
    [Google Scholar]
30. 30.

    Yang WJ, Pranantyo D, Neoh KG, Kang ET, Teo SLM, Rittschof D 2012. Layer-by-layer click deposition of functional polymer coatings for combating marine biofouling. Biomacromolecules 13:92769–80
    [Google Scholar]
31. 31.

    Youngblood JP, Andruzzi L, Ober CK, Hexemer A, Kramer EJ et al. 2003. Coatings based on side-chain ether-linked poly(ethylene glycol) and fluorocarbon polymers for the control of marine biofouling. Biofouling 19:Suppl. 191–98
    [Google Scholar]
32. 32.

    Haines JR, Alexander M. 1975. Microbial degradation of polyethylene glycols. Appl. Microbiol. 29:5621–25
    [Google Scholar]
33. 33.

    Watson GK, Jones N. 1977. The biodegradation of polyethylene glycols by sewage bacteria. Water Res 11:95–100
    [Google Scholar]
34. 34.

    Ulbricht J, Jordan R, Luxenhofer R 2014. On the biodegradability of polyethylene glycol, polypeptoids and poly(2-oxazoline)s. Biomaterials 35:174848–61
    [Google Scholar]
35. 35.

    Tikhova AA, Glukhareva NA, Lebedeva OE 2014. Oxidative degradation of polyglycols by the Ruff's system in the aqueous solutions. Russ. J. Gen. Chem. 84:91570–73
    [Google Scholar]
36. 36.

    Kitano H, Tada S, Mori T, Takaha K, Gemmei-Ide M et al. 2005. Correlation between the structure of water in the vicinity of carboxybetaine polymers and their blood-compatibility. Langmuir 21:2511932–40
    [Google Scholar]
37. 37.

    Gohad NV, Aldred N, Hartshorn CM, Lee YJ, Cicerone MT et al. 2014. Synergistic roles for lipids and proteins in the permanent adhesive of barnacle larvae. Nat. Commun. 5:4414
    [Google Scholar]
38. 38.

    Brady RF. 1999. Properties which influence marine fouling resistance in polymers containing silicon and fluorine. Prog. Org. Coat. 35:1–431–35
    [Google Scholar]
39. 39.

    Ober CK. 2017. Fifty years of the Baier curve: progress in understanding antifouling coatings. Green Mater 5:11–3
    [Google Scholar]
40. 40.

    Baier RE. 2006. Surface behaviour of biomaterials: the theta surface for biocompatibility. J. Mater. Sci. Mater. Med. 17:1057–62
    [Google Scholar]
41. 41.

    Lejars M, Margaillan A, Bressy C 2012. Fouling release coatings: a nontoxic alternative to biocidal antifouling coatings. Chem. Rev. 112:84347–90
    [Google Scholar]
42. 42.

    Gudipati CS, Finlay JA, Callow JA, Callow ME, Wooley KL 2005. The antifouling and fouling-release performance of hyperbranched fluoropolymer (HBFP)-poly(ethylene glycol) (PEG) composite coatings evaluated by adsorption of biomacromolecules and the green fouling alga Ulva. Langmuir 21:73044–53
    [Google Scholar]
43. 43.

    Krishnan S, Ayothi R, Hexemer A, Finlay JA, Sohn KE et al. 2006. Anti-biofouling properties of comblike block copolymers with amphiphilic side chains. Langmuir 22:115075–86
    [Google Scholar]
44. 44.

    Finlay JA, Krishnan S, Callow ME, Callow JA, Dong R et al. 2008. Settlement of Ulva zoospores on patterned fluorinated and PEGylated monolayer surfaces. Langmuir 24:2503–10
    [Google Scholar]
45. 45.

    Galli G, Martinelli E. 2017. Amphiphilic polymer platforms: surface engineering of films for marine antibiofouling. Macromol. Rapid Commun. 38:88–12
    [Google Scholar]
46. 46.

    Brady RF, Singer IL. 2000. Mechanical factors favoring release from fouling release coatings. Biofouling 15:1–373–81
    [Google Scholar]
47. 47.

    Ahmed N, Murosaki T, Kurokawa T, Kakugo A, Yashima S et al. 2014. Prolonged morphometric study of barnacles grown on soft substrata of hydrogels and elastomers. Biofouling 30:3271–79
    [Google Scholar]
48. 48.

    Ahmed N, Murosaki T, Kakugo A, Kurokawa T, Gong JP, Nogata Y 2011. Long-term in situ observation of barnacle growth on soft substrates with different elasticity and wettability. Soft Matter 7:167281–90
    [Google Scholar]
49. 49.

    Chaudhury MK, Finlay JA, Chung JY, Callow ME, Callow JA 2005. The influence of elastic modulus and thickness on the release of the soft-fouling green alga Ulva linza (syn. Enteromorpha linza) from poly(dimethylsiloxane) (PDMS) model networks. Biofouling 21:141–48
    [Google Scholar]
50. 50.

    Wendt DE, Kowalke GL, Kim J, Singer IL 2006. Factors that influence elastomeric coating performance: the effect of coating thickness on basal plate morphology, growth and critical removal stress of the barnacle Balanus amphitrite. Biofouling 22:11–9
    [Google Scholar]
51. 51.

    Decker JT, Kirschner CM, Long CJ, Finlay JA, Callow ME et al. 2013. Engineered antifouling microtopographies: an energetic model that predicts cell attachment. Langmuir 29:4213023–30
    [Google Scholar]
52. 52.

    Kirschner CM, Brennan AB. 2012. Bio-inspired antifouling strategies. Annu. Rev. Mater. Res. 42:211–29
    [Google Scholar]
53. 53.

    Sullivan T, Regan F. 2017. Marine diatom settlement on microtextured materials in static field trials. J. Mater. Sci. 52:105846–56
    [Google Scholar]
54. 54.

    Brzozowska AM, Maassen S, Goh Zhi Rong R, Benke PI, Lim C-S et al. 2017. Effect of variations in micropatterns and surface modulus on marine fouling of engineering polymers. ACS Appl. Mater. Interfaces 9:2017508–16
    [Google Scholar]
55. 55.

    Yandi W, Mieszkin S, Martin-Tanchereau P, Callow ME, Callow JA et al. 2014. Hydration and chain entanglement determines the optimum thickness of poly(HEMA-co-PEG 10 MA) brushes for effective resistance to settlement and adhesion of marine fouling organisms. ACS Appl. Mater. Interfaces 6:11448–58
    [Google Scholar]
56. 56.

    Wiegemann M. 2005. Adhesion in blue mussels (Mytilus edulis) and barnacles (genus Balanus): mechanisms and technical applications. Aquat. Sci. 67:2166–76
    [Google Scholar]
57. 57.

    Scardino AJ, Guenther J, de Nys R 2008. Attachment point theory revisited: the fouling response to a microtextured matrix. Biofouling 24:145–53
    [Google Scholar]
58. 58.

    Lynn DC, Bohlander GS. 1999. Performing ship hull inspections using a remotely operated vehicle. IEEE/MTS Ocean. Conf. Exhib. 2:555–62
    [Google Scholar]
59. 59.

    Selim MS, Shenashen MA, El-Safty SA, Higazy SA, Selim MM et al. 2017. Recent progress in marine foul-release polymeric nanocomposite coatings. Prog. Mater. Sci. 87:1–32
    [Google Scholar]
60. 60.

    Kim S, Gim T, Kang SM 2015. Versatile, tannic acid-mediated surface PEGylation for marine antifouling applications. ACS Appl. Mater. Interfaces 7:126412–16
    [Google Scholar]
61. 61.

    Chen WL, Cordero R, Tran H, Ober CK 2017. 50th anniversary perspective: polymer brushes: novel surfaces for future materials. Macromolecules 50:114089–113
    [Google Scholar]
62. 62.

    Kuliasha CA, Finlay JA, Franco SC, Clare AS, Stafslien SJ, Brennan AB 2017. Marine anti-biofouling efficacy of amphiphilic poly(coacrylate) grafted PDMSe: effect of graft molecular weight. Biofouling 33:3252–67
    [Google Scholar]
63. 63.

    Quintana R, Jańczewski D, Vasantha VA, Jana S, Lee SSC et al. 2014. Sulfobetaine-based polymer brushes in marine environment: Is there an effect of the polymerizable group on the antifouling performance. Colloids Surf. B Biointerfaces 120:118–24
    [Google Scholar]
64. 64.

    Tugulu S, Klok H-A. 2008. Stability and nonfouling properties of poly(poly(ethylene glycol) methacrylate) brushes under cell culture conditions. Biomacromolecules 9:3906–12
    [Google Scholar]
65. 65.

    Paripovic D, Klok HA. 2011. Improving the stability in aqueous media of polymer brushes grafted from silicon oxide substrates by surface-initiated atom transfer radical polymerization. Macromol. Chem. Phys. 212:9950–58
    [Google Scholar]
66. 66.

    Quintana R, Gosa M, Jańczewski D, Kutnyanszky E, Vancso GJ 2013. Enhanced stability of low fouling zwitterionic polymer brushes in seawater with diblock architecture. Langmuir 29:3410859–67
    [Google Scholar]
67. 67.

    Pranantyo D, Xu LQ, Neoh KG, Kang ET, Ng YX, Teo SLM 2015. Tea stains-inspired initiator primer for surface grafting of antifouling and antimicrobial polymer brush coatings. Biomacromolecules 16:3723–32
    [Google Scholar]
68. 68.

    Xu G, Liu P, Pranantyo D, Xu L, Neoh KG, Kang ET 2017. Antifouling and antimicrobial coatings from zwitterionic and cationic binary polymer brushes assembled via “click” reactions. Ind. Eng. Chem. Res. 56:4914479–88
    [Google Scholar]
69. 69.

    Yandi W, Mieszkin S, di Fino A, Martin-Tanchereau P, Callow ME et al. 2016. Charged hydrophilic polymer brushes and their relevance for understanding marine biofouling. Biofouling 32:6609–25
    [Google Scholar]
70. 70.

    Higaki Y, Nishida J, Takenaka A, Yoshimatsu R, Kobayashi M, Takahara A 2015. Versatile inhibition of marine organism settlement by zwitterionic polymer brushes. Polym. J. 47:12811–18
    [Google Scholar]
71. 71.

    Yandi W, Mieszkin S, Callow ME, Callow JA, Finlay JA et al. 2017. Antialgal activity of poly(2-(dimethylamino)ethyl methacrylate) (PDMAEMA) brushes against the marine alga Ulva. Biofouling 33:2169–83
    [Google Scholar]
72. 72.

    Zhang Y, Hu H, Pei X, Liu Y, Ye Q, Zhou F 2017. Polymer brushes on structural surfaces: a novel synergistic strategy for perfectly resisting algae settlement. Biomater. Sci. 5:2493–500
    [Google Scholar]
73. 73.

    Calabrese DR, Wenning B, Finlay JA, Callow ME, Callow JA et al. 2015. Amphiphilic oligopeptides grafted to PDMS-based diblock copolymers for use in antifouling and fouling release coatings. Polym. Adv. Technol. 26:7829–36
    [Google Scholar]
74. 74.

    Calabrese DR, Wenning BM, Buss H, Finlay JA, Fischer D et al. 2017. Oligopeptide-modified hydrophobic and hydrophilic polymers as antifouling coatings. Green Mater 5:131–43
    [Google Scholar]
75. 75.

    Van Zoelen W, Zuckermann RN, Segalman RA 2012. Tunable surface properties from sequence-specific polypeptoid-polystyrene block copolymer thin films. Macromolecules 45:177072–82
    [Google Scholar]
76. 76.

    Miller SM, Simon RJ, Ng S, Zuckermann RN, Kerr JM, Moos WH 1995. Comparison of the proteolytic susceptibilities of homologous L-amino acid, D-amino acid and N-substituted glycine peptide and peptoid oligomers. Drug Dev. Res. 32:20–32
    [Google Scholar]
77. 77.

    Van Zoelen W, Buss HG, Ellebracht NC, Lynd NA, Fischer DA et al. 2014. Sequence of hydrophobic and hydrophilic residues in amphiphilic polymer coatings affects surface structure and marine antifouling/fouling release properties. ACS Macro Lett 3:364–68
    [Google Scholar]
78. 78.

    Leng C, Buss HG, Segalman RA, Chen Z 2015. Surface structure and hydration of sequence-specific amphiphilic polypeptoids for antifouling/fouling release applications. Langmuir 31:9306–11
    [Google Scholar]
79. 79.

    Patterson AL, Wenning B, Rizis G, Calabrese DR, Finlay JA et al. 2017. Role of backbone chemistry and monomer sequence in amphiphilic oligopeptide- and oligopeptoid-functionalized PDMS- and PEO-based block copolymers for marine antifouling and fouling release coatings. Macromolecules 50:72656–67
    [Google Scholar]
80. 80.

    Kavanagh CJ, Swain GW, Kovach BS, Stein J, Darkangelo-Wood C et al. 2003. The effects of silicone fluid additives and silicone elastomer matrices on barnacle adhesion strength. Biofouling 19:6381–90
    [Google Scholar]
81. 81.

    Stein J, Truby K, Wood CD, Stein J, Gardner M et al. 2003. Silicone foul release coatings: effect of the interaction of oil and coating functionalities on the magnitude of macrofouling attachment strengths. Biofouling 19:Suppl. 171–82
    [Google Scholar]
82. 82.

    Martinelli E, Hill SD, Finlay JA, Callow ME, Callow JA et al. 2016. Amphiphilic modified-styrene copolymer films: antifouling/fouling release properties against the green alga Ulva linza. Prog. Org. Coat. 90:235–42
    [Google Scholar]
83. 83.

    Galli G, Barsi D, Martinelli E, Glisenti A, Finlay JA et al. 2016. Copolymer films containing amphiphilic side chains of well-defined fluoroalkyl-segment length with biofouling-release potential. RSC Adv 6:67127–35
    [Google Scholar]
84. 84.

    Martinelli E, Gunes D, Wenning BM, Ober CK, Finlay JA et al. 2016. Effects of surface-active block copolymers with oxyethylene and fluoroalkyl side chains on the antifouling performance of silicone-based films. Biofouling 32:181–93
    [Google Scholar]
85. 85.

    Wenning BM, Martinelli E, Mieszkin S, Finlay JA, Fischer D et al. 2017. Model amphiphilic block copolymers with tailored molecular weight and composition in PDMS-based films to limit soft biofouling. ACS Appl. Mater. Interfaces 9:1916505–16
    [Google Scholar]
86. 86.

    Oliva M, Martinelli E, Galli G, Pretti C 2017. PDMS-based films containing surface-active amphiphilic block copolymers to combat fouling from barnacles B. amphitrite and B. improvisus. Polymer 108:476–82
    [Google Scholar]
87. 87.

    Martinelli E, Guazzelli E, Bartoli C, Gazzarri M, Chiellini F et al. 2015. Amphiphilic pentablock copolymers and their blends with PDMS for antibiofouling coatings. J. Polym. Sci. A Polym. Chem. 53:101213–25
    [Google Scholar]
88. 88.

    Hawkins ML, Schott SS, Grigoryan B, Rufin MA, Khai B et al. 2017. Anti-protein and anti-bacterial behavior of amphiphilic silicones. Polym. Chem. 8:5239–51
    [Google Scholar]
89. 89.

    Hawkins ML, Faÿ F, Réhel K, Linossier I, Grunlan MA 2014. Bacteria and diatom resistance of silicones modified with PEO-silane amphiphiles. Biofouling 30:2247–58
    [Google Scholar]
90. 90.

    Rufin MA, Barry ME, Adair PA, Hawkins ML, Raymond JE, Grunlan MA 2016. Protein resistance efficacy of PEO-silane amphiphiles: dependence on PEO-segment length and concentration. Acta Biomater 41:247–52
    [Google Scholar]
91. 91.

    Rufin MA, Gruetzner JA, Hurley MJ, Hawkins ML, Raymond ES et al. 2015. Enhancing the protein resistance of silicone via surface-restructuring PEO-silane amphiphiles with variable PEO length. J. Mater. Chem. B 3:142816–25
    [Google Scholar]
92. 92.

    Fay F, Hawkins ML, Rehel K, Linossier I, Grunlan MA 2016. Non-toxic, antifouling silicones with variable PEO-silane amphiphile content. Green Mater 4:253–62
    [Google Scholar]
93. 93.

    Katsuyama Y, Kurokawa T, Kaneko T, Gong JP, Osada Y et al. 2002. Inhibitory effects of hydrogels on the adhesion, germination, and development of zoospores originating from Laminaria angustata. Macromol. Biosci 2:4163–69
    [Google Scholar]
94. 94.

    Jiang D, Liu Z, He X, Han J, Wu X 2016. Polyacrylamide strengthened mixed-charge hydrogels and their applications in resistance to protein adsorption and algae attachment. RSC Adv 6:5347349–56
    [Google Scholar]
95. 95.

    Yang W, Lin P, Cheng D, Zhang L, Wu Y et al. 2017. Contribution of charges in polyvinyl alcohol networks to marine antifouling. ACS Appl. Mater. Interfaces 9:2118295–304
    [Google Scholar]
96. 96.

    Zhu X, Jańczewski D, Lee SSC, Teo SLM, Vancso GJ 2013. Cross-linked polyelectrolyte multilayers for marine antifouling applications. ACS Appl. Mater. Interfaces 5:135961–68
    [Google Scholar]
97. 97.

    Zhu X, Guo S, Janzewski D, Parra Velandia FJ, Lay S et al. 2014. Multilayers of fluorinated amphiphilic polyions for marine fouling prevention. Langmuir 30:288–96
    [Google Scholar]
98. 98.

    Zhu X, Jańczewski D, Guo S, Lee SSC, Parra Velandia FJ et al. 2015. Polyion multilayers with precise surface charge control for antifouling. ACS Appl. Mater. Interfaces 7:1852–61
    [Google Scholar]
99. 99.

    Laschewsky A. 2014. Structures and synthesis of zwitterionic polymers. Polymers 6:51544–601
    [Google Scholar]
100. 100.

     Ventura C, Guerin AJ, El-Zubir O, Ruiz-Sanchez AJ, Dixon LI et al. 2017. Marine antifouling performance of polymer coatings incorporating zwitterions. Biofouling 33:10892–903
     [Google Scholar]
101. 101.

     Bauer S, Finlay JA, Thomé I, Nolte K, Franco SC et al. 2016. Attachment of algal cells to zwitterionic self-assembled monolayers comprised of different anionic compounds. Langmuir 32:5663–71
     [Google Scholar]
102. 102.

     Wang H, Zhang C, Wang J, Feng X, He C 2016. Dual-mode antifouling ability of thiol-ene amphiphilic conetworks: minimally adhesive coatings via the surface zwitterionization. ACS Sustain. Chem. Eng. 4:73803–11
     [Google Scholar]
103. 103.

     Xie Q, Xie Q, Pan J, Ma C, Zhang G 2018. Biodegradable polymer with hydrolysis-induced zwitterions for antibiofouling. ACS Appl. Mater. Interfaces 10:1311213–20
     [Google Scholar]
104. 104.

     Ekin A, Webster DC, Daniels JW, Stafslien SJ, Cassé F et al. 2007. Synthesis, formulation, and characterization of siloxane-polyurethane coatings for underwater marine applications using combinatorial high-throughput experimentation. J. Coat. Technol. Res. 4:4435–51
     [Google Scholar]
105. 105.

     Majumdar P, Webster DC. 2005. Preparation of siloxane-urethane coatings having spontaneously formed stable biphasic microtopograpical surfaces. Macromolecules 38:145857–59
     [Google Scholar]
106. 106.

     Webster DC, Bodkhe RB. 2013. Functionalized silicones with polyalkylene oxide side chains Patent No. WO 2013/052181 A2
107. 107.

     Bodkhe RB, Stafslien SJ, Cilz N, Daniels J, Thompson SEM et al. 2012. Polyurethanes with amphiphilic surfaces made using telechelic functional PDMS having orthogonal acid functional groups. Prog. Org. Coat. 75:38–48
     [Google Scholar]
108. 108.

     Galhenage TP, Webster DC, Moreira AMS, Burgett RJ, Stafslien SJ et al. 2017. Poly(ethylene) glycol-modified, amphiphilic, siloxane-polyurethane coatings and their performance as fouling-release surfaces. J. Coat. Technol. Res. 14:2307–22
     [Google Scholar]
109. 109.

     Bodkhe RB, Stafslien SJ, Daniels J, Cilz N, Muelhberg AJ et al. 2015. Zwitterionic siloxane-polyurethane fouling-release coatings. Prog. Org. Coat. 78:369–80
     [Google Scholar]
110. 110.

     Liu C, Xie Q, Ma C, Zhang G 2016. Fouling release property of polydimethylsiloxane-based polyurea with improved adhesion to substrate. Ind. Eng. Chem. Res. 55:236671–76
     [Google Scholar]
111. 111.

     Liu C, Ma C, Xie Q, Zhang G 2017. Self-repairing silicone coatings for marine anti-biofouling. J. Mater. Chem. A 5:3015855–61
     [Google Scholar]
112. 112.

     Galhenage TP, Hoffman D, Silbert SD, Stafslien SJ, Daniels J et al. 2016. Fouling-release performance of silicone oil-modified siloxane-polyurethane coatings. ACS Appl. Mater. Interfaces 8:4229025–36
     [Google Scholar]
113. 113.

     Epstein AK, Wong T-S, Belisle RA, Boggs EM, Aizenberg J 2012. Liquid-infused structured surfaces with exceptional anti-biofouling performance. PNAS 109:3313182–87
     [Google Scholar]
114. 114.

     Xiao L, Li J, Mieszkin S, di Fino A, Clare AS et al. 2013. Slippery liquid-infused porous surfaces showing marine antibiofouling properties. ACS Appl. Mater. Interfaces 5:10074–80
     [Google Scholar]
115. 115.

     Howell C, Vu TL, Johnson CP, Hou X, Ahanotu O et al. 2015. Stability of surface-immobilized lubricant interfaces under flow. Chem. Mater. 27:51792–800
     [Google Scholar]
116. 116.

     Howell C, Vu TL, Lin JJ, Kolle S, Juthani N et al. 2014. Self-replenishing vascularized fouling-release surfaces. ACS Appl. Mater. Interfaces 6:1513299–307
     [Google Scholar]
117. 117.

     Amini S, Kolle S, Petrone L, Ahanotu O, Sunny S et al. 2017. Preventing mussel adhesion using lubricant-infused materials. Science 357:668–73
     [Google Scholar]
118. 118.

     Wang P, Zhang D, Lu Z 2015. Slippery liquid-infused porous surface bio-inspired by pitcher plant for marine anti-biofouling application. Colloids Surf. B Biointerfaces 136:240–47
     [Google Scholar]
119. 119.

     Wang P, Lu Z, Zhang D 2015. Slippery liquid-infused porous surfaces fabricated on aluminum as a barrier to corrosion induced by sulfate reducing bacteria. Corros. Sci. 93:159–66
     [Google Scholar]
120. 120.

     Wang P, Zhang D, Lu Z, Sun S 2016. Fabrication of slippery lubricant-infused porous surface for inhibition of microbially influenced corrosion. ACS Appl. Mater. Interfaces 8:21120–27
     [Google Scholar]
121. 121.

     Wang P, Zhang D, Sun S, Li T, Sun Y 2017. Fabrication of slippery lubricant-infused porous surface with high underwater transparency for the control of marine biofouling. ACS Appl. Mater. Interfaces 9:1972–82
     [Google Scholar]
122. 122.

     Chen L, Qian PY. 2017. Review on molecular mechanisms of antifouling compounds: an update since 2012. Mar. Drugs 15:91–20
     [Google Scholar]
123. 123.

     Chung KT, Lu Z, Chou MW 1998. Mechanism of inhibition of tannic acid and related compounds on the growth of intestinal bacteria. Food Chem. Toxicol. 36:1053–60
     [Google Scholar]
124. 124.

     Peres RS, Armelin E, Alemán C, Ferreira CA 2015. Modified tannin extracted from black wattle tree as an environmentally friendly antifouling pigment. Ind. Crops Prod. 65:506–14
     [Google Scholar]
125. 125.

     Del Grosso CA, McCarthy TW, Clark CL, Cloud JL, Wilker JJ 2016. Managing redox chemistry to deter marine biological adhesion. Chem. Mater. 28:186791–96
     [Google Scholar]
126. 126.

     Lim CS, Lee SSC, Leong W, Ng YX, Teo SLM 2014. A short review of laboratory and field testing of environmentally benign antifouling coatings. Indian J. Geo-Mar. Sci. 43:112067–74
     [Google Scholar]
127. 127.

     Briand J-F. 2009. Marine antifouling laboratory bioassays: an overview of their diversity. Biofouling 25:4297–311
     [Google Scholar]