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Applied Microbiology and Biotechnology

, Volume 100, Issue 6, pp 2591–2602 | Cite as

Bioconcrete: next generation of self-healing concrete

  • Mostafa Seifan
  • Ali Khajeh Samani
  • Aydin BerenjianEmail author
Mini-Review

Abstract

Concrete is one of the most widely used construction materials and has a high tendency to form cracks. These cracks lead to significant reduction in concrete service life and high replacement costs. Although it is not possible to prevent crack formation, various types of techniques are in place to heal the cracks. It has been shown that some of the current concrete treatment methods such as the application of chemicals and polymers are a source of health and environmental risks, and more importantly, they are effective only in the short term. Thus, treatment methods that are environmentally friendly and long-lasting are in high demand. A microbial self-healing approach is distinguished by its potential for long-lasting, rapid and active crack repair, while also being environmentally friendly. Furthermore, the microbial self-healing approach prevails the other treatment techniques due to the efficient bonding capacity and compatibility with concrete compositions. This study provides an overview of the microbial approaches to produce calcium carbonate (CaCO3). Prospective challenges in microbial crack treatment are discussed, and recommendations are also given for areas of future research.

Keywords

Self-healing Concrete Crack Bacteria Calcium carbonate Biomineralization 

Notes

Acknowledgments

This investigation was financially supported by The University of Waikato, New Zealand.

Compliance with ethical standards

Conflict of interest

The authors declare that they have no competing interests.

Ethics

The article is original and has not been formally published in any other peer-reviewed journal and does not infringe any existing copyright and any other third party rights.

References

  1. Achal V, Mukerjee A, Sudhakara Reddy M (2013) Biogenic treatment improves the durability and remediates the cracks of concrete structures. Constr Build Mater 48:1–5CrossRefGoogle Scholar
  2. Achal V, Mukherjee A, Sudhakara Reddy M (2011) Microbial concrete: way to enhance the durability of building structures. J Mater Civil Eng 23:730–734CrossRefGoogle Scholar
  3. Achal V, Pan X (2011) Characterization of urease and carbonic anhydrase producing bacteria and their role in calcite precipitation. Curr Microbiol 62:894–902CrossRefPubMedGoogle Scholar
  4. Ahn TH, Kishi T (2009) The effect of geo-materials on the autogenous healing behavior of cracked concrete. ICCRRR II. Cape Town, South Africa pp 125–126Google Scholar
  5. Bang SS, Galinat JK, Ramakrishnan V (2001) Calcite precipitation induced by polyurethane-immobilized Bacillus pasteurii. Enzyme Microb Tech 28:404–409CrossRefGoogle Scholar
  6. Bang SS, Lippert JJ, Yerra U, Mulukutla S, Ramakrishnan V (2010) Microbial calcite, a bio-based smart nanomaterial in concrete remediation. Int J Smart Nano Mater 1:28–39CrossRefGoogle Scholar
  7. Barton LL, Northup DE (2011) Microbial ecology. Wiley- BlackwellGoogle Scholar
  8. Belie ND, Muynck W (2008) Crack repair in concrete using biodeposition. ICCRRR II. Cape Town, South Africa 291–292Google Scholar
  9. Berenjian A, Chan N, Malmiri HJ (2012) Volatile organic compounds removal methods: a review. Am J Biochem Biotechnol 8:220–229CrossRefGoogle Scholar
  10. Blaiszik BJ, Kramer SLB, Olugebefola SC, Moore JS, Sottos NR, White SR (2010) Self-healing polymers and composites. Ann Rev Mater Res 40:179–211CrossRefGoogle Scholar
  11. Burbank MB, Weaver TJ, Green TL, Williams B, Crawford RL (2011) Precipitation of calcite by indigenous microorganisms to strengthen liquefiable soils. Geomicrobiol J 28:301–312CrossRefGoogle Scholar
  12. Burne RA, Chen YYM (2000) Bacterial ureases in infectious diseases. Microbes Infect 2:533–542CrossRefPubMedGoogle Scholar
  13. Cacchio P, Ercole C, Cappuccio G, Lepidi A (2003) Calcium carbonate precipitation by bacterial strains isolated from a limestone cave and from a loamy soil. Geomicrobiol J 20:85–98CrossRefGoogle Scholar
  14. Cailleux E, Pollet V (2009) Investigations on the development of self-healing properties in protective coatings for concrete and repair mortars. 2nd International Conference on Self-Healing Materials, Chicago, USAGoogle Scholar
  15. Castainer S, Metayer-Levrel GL, Perthuisot J (2000) Bacterial roles in the precipitation of carbonate minerals. In: Riding RE, Awramik SM (eds) Microbial sediments. Springer, Berlin Heidelberg, pp. 32–39CrossRefGoogle Scholar
  16. Castainer S, Metayer-Levrel GL, Perthuisot JP (1999) Ca-carbonates precipitation and limestone genesis-the microbiogeologist point of view. Sediment Geol 126:9–23CrossRefGoogle Scholar
  17. Chahal N, Siddique R, Rajor A (2012) Influence of bacteria on the compressive strength, water absorption and rapid chloride permeability of fly ash concrete. Constr Build Mater 28:351–356CrossRefGoogle Scholar
  18. Chunxiang Q, Jianyun W, Ruixing W, Liang C (2009) Corrosion protection of cement-based building materials by surface deposition of CaCO3 by Bacillus pasteurii. Mater Sci Eng 29:1273–1280CrossRefGoogle Scholar
  19. Clear CA (1985) Effects of autogenous healing upon the leakage of water through cracks in concrete. Cement and Concrete Association, USAGoogle Scholar
  20. De Muynck W, Cox K, Belie ND, Verstraete W (2008b) Bacterial carbonate precipitation as an alternative surface treatment for concrete. Constr Build Mater 22:875–885CrossRefGoogle Scholar
  21. De Muynck W, De Belie N, Verstraete W (2010) Microbial carbonate precipitation in construction materials: a review. Ecol Eng 36:118–136CrossRefGoogle Scholar
  22. De Muynck W, Debrouwer D, De Belie N, Verstraete W (2008a) Bacterial carbonate precipitation improves the durability of cementitious materials. Cement Concrete Res 38:1005–1014CrossRefGoogle Scholar
  23. Dhami N, Mukherjee A, Reddy MS (2012) Biofilm and microbial applications in biomineralized concrete. In: Seto J (ed) Advanced Topics in Biomineralization, InTech, pp 137–164Google Scholar
  24. Dick J, De Windt W, De Graef B, Saveyn H, Van Der Meeren P, De Belie N, Verstraete W (2006) Bio-deposition of a calcium carbonate layer on degraded limestone by Bacillus species. Biodegradation 17:357–367CrossRefPubMedGoogle Scholar
  25. Dry C (1994) Matrix cracking repair and filling using active and passive modes for smart timed release of chemicals from fibers into cement matrices. Smart Mater Struct 3:118–123CrossRefGoogle Scholar
  26. Ebrahiminezhad A, Najafipour S, Kouhpayeh A, Berenjian A, Rasoul-Amini S, Ghasemi Y (2014) Facile fabrication of uniform hollow silica microspheres using a novel biological template. Colloid Surface B 118:249–253CrossRefGoogle Scholar
  27. Edvardsen C (1999) Water permeability and autogenous healing of cracks in concrete. ACI Mater J 96:448–454Google Scholar
  28. Ehrlich HL (1995) Geomicrobiology. Marcel Dekker Inc, New YorkGoogle Scholar
  29. Erşan YÇ, Belie ND, Boon N (2015b) Microbially induced CaCO3 precipitation through denitrification: an optimization study in minimal nutrient environment. Biochem Eng J 101:108–118CrossRefGoogle Scholar
  30. Erşan YÇ, Da Silva FB, Boon N, Verstraete W, De Belie N (2015a) Screening of bacteria and concrete compatible protection materials. Constr Build Mater 88:196–203CrossRefGoogle Scholar
  31. Federal Highway Administration (FHWA) (2001) Corrosion cost and preventive strategies in the United States. NACE International http://www.nace.org/uploadedFiles/Publications/ccsupp.pdf
  32. Fortin D, Ferris FG, Beveridge TJ (1997) Surface-mediated mineral development by bacteria. Rev Mineral 35:161–180Google Scholar
  33. Ghaz-Jahanian MA, Khodaparastan F, Berenjian A, Jafarizadeh-Malmiri H (2013) Influence of small RNAs on biofilm formation process in bacteria. Mol Biotechnol 55:288–297CrossRefPubMedGoogle Scholar
  34. Groth I, Schumann P, Laiz L, Sanchez-Moral S, Cañveras JC, Saiz-Jimenez C (2001) Geomicrobiological study of the Grotta dei Cervi, Porto Badisco, Italy. Geomicrobiol J 18:241–258CrossRefGoogle Scholar
  35. Hammes F, Verstraete W (2002) Key roles of pH and calcium metabolism in microbial carbonate precipitation. Rev Environ Sci Biotechnol 1:3–7CrossRefGoogle Scholar
  36. Hearn N (1998) Self-sealing, autogenous healing and continued hydration: what is the difference? Mater Struct 31:563–567CrossRefGoogle Scholar
  37. Jonkers HM (2011) Bacteria-based self-healing concrete. Heron 56:5–16Google Scholar
  38. Jonkers HM, Schlangen E (2009) A two component bacteria-based self-healing concrete. Concrete Repair, Rehabilitation and Retrofitting II, ICCRRR Cape Town South AfricaGoogle Scholar
  39. Jonkers HM, Thijssen A, Muyzer G, Copuroglu O, Schlangen E (2010) Application of bacteria as self-healing agent for the development of sustainable concrete. Ecol Eng 36:230–235CrossRefGoogle Scholar
  40. Kar SZ, Berenjian A (2013) Soil formation by ecological factors: critical review. Am J Agric Biol Sci 8:114–116CrossRefGoogle Scholar
  41. Karatas I (2008) Microbiological improvement of the physical properties of soils. Dissertation Arizona State UniversityGoogle Scholar
  42. Kim HK, Park SJ, Han JI, Lee HK (2013) Microbially mediated calcium carbonate precipitation on normal and lightweight concrete. Constr Build Mater 38:1073–1082CrossRefGoogle Scholar
  43. Knorre H, Krumbein KE (2000) Bacterial calcification, in Microbial sediments, Riding RE, Awramik SM. Springer, Berlin, pp. 25–31Google Scholar
  44. Le Métayer-Levrel G, Castanier S, Orial G, Loubière JF, Perthuisot JP (1999) Applications of bacterial carbonatogenesis to the protection and regeneration of limestones in buildings and historic patrimony. Sediment Geol 126:25–34CrossRefGoogle Scholar
  45. Lee YN (2003) Calcite production by Bacillus amyloliquefaciens CMB01. J Microbiol 41:345–348Google Scholar
  46. Li VC, Herbert E (2012) Robust self-healing concrete for sustainable infrastructure. J Adv Concr Technol 10:207–218CrossRefGoogle Scholar
  47. Maheswaran S, Dasuru SS, Rama Chandra Murthy A, Bhuvaneshwari B, Ramesh Kumar V, Palani GS, Iyer NR, Krishnamoorthy S, Sandhya S (2014) Strength improvement studies using new type wild strain Bacillus cereus on cement mortar. Curr Sci India 106:50–57Google Scholar
  48. Malmiri HJ, Jahanian MAG, Berenjian A (2012) Potential applications of chitosan nanoparticles as novel support in enzyme immobilization. Am J Biochem Biotechnol 8:203–219CrossRefGoogle Scholar
  49. Mann S (2001) Biomineralization: principles and concepts in bioinorganic materials chemistry. Oxford University Press, New YorkGoogle Scholar
  50. Munn CB (2004) Marine microbiology: ecology and applications. Bios Scientific Publisher, LondonGoogle Scholar
  51. Muynck W, Belie N, Verstraete W (2007) Improvement of concrete durability with the aid of bacteria. Proceedings of the first international conference on self healing materials. Noordwijk aan zee, The NetherlandsGoogle Scholar
  52. Neville AM, Brooks JJ (2010) Concrete technology. Pearson, United KingdomGoogle Scholar
  53. Okafor N (2011) Environmental microbiology of aquatic and waste systems. Springer, NetherlandsCrossRefGoogle Scholar
  54. Pacheco-Torgal F, Labrincha JA (2013) Biotech cementitious materials: some aspects of an innovative approach for concrete with enhanced durability. Constr Build Mater 40:1136–1141CrossRefGoogle Scholar
  55. Park SJ, Park YM, Chun WY, Kim WJ, Ghim SY (2010) Calcite-forming bacteria for compressive strength improvement in mortar. J Microbiol Biotechn 20:782–788Google Scholar
  56. Perito B, Mastromei G (2011) Molecular basis of bacterial calcium carbonate precipitation, in molecular biomineralization. W.E.G, Müller, EditorGoogle Scholar
  57. Qian C, Wang R, Cheng L, Wang J (2010a) Theory of microbial carbonate precipitation and its application in restoration of cement-based materials defects. Chinese J Chem 28:847–857CrossRefGoogle Scholar
  58. Qian SZ, Zhou J, Schlangen E (2010b) Influence of curing condition and precracking time on the self-healing behavior of engineered cementitious composites. Cement Concrete Composites 32:686–693CrossRefGoogle Scholar
  59. Ramachandran SK, Ramakrishnan V, Bang SS (2001) Remediation of concrete using micro-organisms. ACI Mater J 98:3–9Google Scholar
  60. Ramm W, Biscoping M (1998) Autogenous healing and reinforcement corrosion of water-penetrated separation cracks in reinforced concrete. Nucl Eng Des 179:191–200CrossRefGoogle Scholar
  61. Reinhardt HW, Jooss M (2003) Permeability and self-healing of cracked concrete as a function of temperature and crack width. Cement Concrete Res 33:981–985CrossRefGoogle Scholar
  62. Rivadeneyra MA, Delgado R, Del Moral A, Ferrer MR, Ramos-Cormenzana A (1994) Precipitation of calcium carbonate by Vibrio spp. from an inland saltern. FEMS Microbiol Ecol 13: 197–204Google Scholar
  63. Ronholm J, Schumann D, Sapers HM, Izawa M, Applin D, Berg B, Mann P, Vali H, Flemming RL, Cloutis EA, Whyte LG (2014) A mineralogical characterization of biogenic calcium carbonates precipitated by heterotrophic bacteria isolated from cryophilic polar regions. Geobiology 12:542–556CrossRefPubMedGoogle Scholar
  64. Rusznyák A, Akob DM, Nietzsche S, Eusterhues K, Totsche KU, Neu TR, Frosch T, Popp J, Keiner R, Geletneky J, Katzschmann L, Schulze E, Küsel K (2012) Calcite biomineralization by bacterial isolates from the recently discovered pristine karstic herrenberg cave. Appl Environ Microb 78:1157–1167CrossRefGoogle Scholar
  65. Şahmaran M, Keskin SB, Ozerkan G, Yaman IO (2008) Self-healing of mechanically-loaded self consolidating concretes with high volumes of fly ash. Cement Concrete. Composites 30:872–879CrossRefGoogle Scholar
  66. Samani AK, Attard MM (2012) A stress-strain model for uniaxial and confined concrete under compression. Eng Struct 41:335–349CrossRefGoogle Scholar
  67. Samani AK, Attard MM (2014) Lateral strain model for concrete under compression. ACI Struct J 111:441–451Google Scholar
  68. Sangadji S, Schlangen E (2013) Mimicking bone healing process to self repair concrete structure novel approach using porous network concrete. Procedia Engineering 54:315–326CrossRefGoogle Scholar
  69. Schlegel H (1993) General microbiology. University Press, CambridgeGoogle Scholar
  70. Sierra-Beltran MG, Jonkers HM, Schlangen E (2014) Characterization of sustainable bio-based mortar for concrete repair. Constr Build Mater 67:344–352CrossRefGoogle Scholar
  71. Silva FB, Boon N, De Belie N, Verstraete W (2015) Industrial application of biological self-healing concrete: challenges and economical feasibility. J Commerc Biotechnol 21:31–38CrossRefGoogle Scholar
  72. Soltmann U, Böttcher H (2008) Utilization of sol-gel ceramics for the immobilization of living microorganisms. J Sol-Gel Sci Techn 48:66–72CrossRefGoogle Scholar
  73. Soltmann U, Raff J, Selenska-Pobell S, Matys S, Pompe W, Böttcher H (2003) Biosorption of heavy metals by sol-gel immobilized Bacillus sphaericus cells, spores and S-layers. J Sol-Gel Sci Techn 26:1209–1212CrossRefGoogle Scholar
  74. Stocks-Fischer S, Galinat JK, Bang SS (1999) Microbiological precipitation of CaCO3. Soil Biol Biochem 31:1563–1571CrossRefGoogle Scholar
  75. Stuckrath C, Serpell R, Valenzuela LM, Lopez M (2014) Quantification of chemical and biological calcium carbonate precipitation: performance of self-healing in reinforced mortar containing chemical admixtures. Cement Concrete Composites 50:10–15CrossRefGoogle Scholar
  76. Tebo BM, Johnson HA, McCarthy JK, Templeton AS (2005) Geomicrobiology of manganese(II) oxidation. Trends Microbiol 13:421–428CrossRefPubMedGoogle Scholar
  77. Vaghari H, Eskandari M, Sobhani V, Berenjian A, Song Y, Jafarizadeh-Malmiri H (2015) Process intensification for production and recovery of biological products. Am J Biochem Biotechnol 11:37–43CrossRefGoogle Scholar
  78. Van Breugel K (2007) Is there a market for self-healing cement based materials? The first international conference on self-healing materials. Noordwijk aan zee, The NetherlandsGoogle Scholar
  79. van Paassen LA, Daza CM, Staal M, Sorokin DY, van der Zon W, van Loosdrecht MCM (2010) Potential soil reinforcement by biological denitrification. Ecol Eng 36:168–175CrossRefGoogle Scholar
  80. Van Tittelboom K, De Belie N (2013) Self-healing in cementitious materials-a review. Materials 6:2182–2217CrossRefGoogle Scholar
  81. Van Tittelboom K, De Belie N, De Muynck W, Verstraete W (2010) Use of bacteria to repair cracks in concrete. Cement Concrete Res 40:157–166CrossRefGoogle Scholar
  82. Van Tittelboom K, De Belie N, Van Loo D, Jacobs P (2011) Self-healing efficiency of cementitious materials containing tubular capsules filled with healing agent. Cement Concrete Composites 33:497–505CrossRefGoogle Scholar
  83. Wang J, Dewanckele J, Cnudde V, Van Vlierberghe S, Verstraete W, De Belie N (2014a) X-ray computed tomography proof of bacterial-based self-healing in concrete. Cement Concrete Composites 53:289–304CrossRefGoogle Scholar
  84. Wang J, Van Tittelboom K, De Belie N, Verstraete W (2012a) Use of silica gel or polyurethane immobilized bacteria for self-healing concrete. Constr Build Mater 26:532–540CrossRefGoogle Scholar
  85. Wang JY, De Belie N, Verstraete W (2012b) Diatomaceous earth as a protective vehicle for bacteria applied for self-healing concrete. J Ind Microbiol Biot 39:567–577CrossRefGoogle Scholar
  86. Wang JY, Snoeck D, Van Vlierberghe S, Verstraete W, De Belie N (2014b) Application of hydrogel encapsulated carbonate precipitating bacteria for approaching a realistic self-healing in concrete. Constr Build Mater 68:110–119CrossRefGoogle Scholar
  87. Wang JY, Soens H, Verstraete W, De Belie N (2014c) Self-healing concrete by use of microencapsulated bacterial spores. Cement Concrete Res 56:139–152CrossRefGoogle Scholar
  88. Wang JY, Van Tittelboom K, De Belie N, Verstraete W (2010) Potential of applying bacteria to heal cracks in concrete. 2nd International Conference on Sustainable Construction Materials and TechnologiesGoogle Scholar
  89. Wang X, Xing F, Zhang M, Han N, Qian Z (2013) Experimental study on cementitious composites embedded with organic microcapsules. Materials 6:4064–4081CrossRefGoogle Scholar
  90. Warscheid T, Braams J (2000) Biodeterioration of stone: a review. Int Biodeter Biodegr 46:343–368CrossRefGoogle Scholar
  91. Wiktor V, Jonkers HM (2011) Quantification of crack-healing in novel bacteria-based self-healing concrete. Cement Concrete Composites 33:763–770CrossRefGoogle Scholar
  92. Wu M, Johannesson B, Geiker M (2012) A review: self-healing in cementitious materials and engineered cementitious composite as a self-healing material. Constr Build Mater 28:571–583CrossRefGoogle Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2016

Authors and Affiliations

  • Mostafa Seifan
    • 1
  • Ali Khajeh Samani
    • 1
  • Aydin Berenjian
    • 1
    Email author
  1. 1.School of Engineering, Faculty of Science and EngineeringThe University of WaikatoHamiltonNew Zealand

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