Abstract
Biological materials are chemically modified natural materials derived from proteins, carbohydrates, lipids and nucleic acids, whose properties can be tailored to suit the needs of specific applications in mind. There is an urgent need for such bio-derived materials which would demonstrate to have very high value in terms of function, durability, stability and price. One driving factor for our research efforts in this area has been the concern regarding the extensive accumulation of nonbiodegradable materials in our environment at an alarming rate, which is causing extensive damage to life on this planet, directly or indirectly. This problem needs urgent attention from scientists, engineers as well as the general public to find acceptable solutions. One approach is to extensively utilize natural materials such that they are rapidly degraded in a preprogrammed manner into harmless components when released into the environment after their useful lifetime as required for the particular goods. But, naturally occurring materials may not have the necessary characteristics and properties for the intended purpose, and hence chemical modification of the natural materials is required to tailor their properties. In this chapter, an introduction to such materials is provided with one specific example to demonstrate the strategy, scope and versatility of the approach and philosophy of making bio-derived materials for the long term sustainability of our standard of living on this planet. One major advantage of biological materials is that they can be rationally programmed to degrade when exposed to the environmental conditions over predetermined time scales and hence, they would not accumulate in the environment or generate toxic waste. Another advantage of biological materials is that these can be rationally designed based on fundamental principles of chemistry. A clear understanding of the properties of the biological materials with respect to their composition, surface chemistry, morphology, assembly, stability as well as interactions with other kinds of matter is essential to tailor their properties for specific applications. Examples of chemical modification of ordinary proteins to make protein fluorescent nanoparticles of controlled size are described in this chapter. A comparison is made between these bio-derived materials and the current state-of-the-art quantum dot equivalents. The examples illustrated here show the possibility of making biodegradable materials, which are functional, programmable, inexpensive, novel and also generate new and exciting chemistry. Progress in this area is intricately connected with recent advances made in understanding the interactions between the above natural materials and reagents used for the chemical modification of nature’s materials.
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For fun facts, go to https://faculty.washington.edu/chudler/bvc.html.
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Millions of times faster than the IBM Watson and thousand times faster than the fastest supercomputer, K of Fujitsu. T. Pearson, IBM Watson—How to build your own “Watson Jr.” in your basement, Inside System Storage.
References
Dautel SL (2009) Transoceanic trash: international and United States strategies for the great Pacific Garbage Patch. Golden Gate U. Environ L J 3:181
Young LC, Vanderlip C, Duffy DC, Afanasyev V, Shaffer SA (2009) In: Ropert-Coudert Y (ed) Bringing home the trash: do colony-based differences in foraging distribution lead to increased plastic ingestion in Laysan Albatrosses? PLoS ONE 4(10):e7623
Ryan PG, Moore CJ, Van Franeker JA, Moloney CL (2009) Monitoring the abundance of plastic debris in the marine environment. Philos Tran R Soc B Biol Sci 364(1526):1999–2012. doi:10.1098/rstb.2008.0207
Rios LM, Moore C, Jones PR (2007) Persistent organic pollutants carried by synthetic polymers in the ocean environment. Mar Pollut Bull 54:1230–1237. doi:10.1016/j.marpolbul.2007.03.022
Joshi S (2000) Product environmental life-cycle assessment using input-output techniques. J Ind Ecol 3:95
Mahasenan N, Smith S, Humphreys K, Kaya Y (2003) The cement industry and global climate change: current and potential future cement industry CO2 emissions. In: 6th international conference on greenhouse gas control technologies. Pergamon, Oxford, pp 995–1000. doi:10.1016/B978-008044276-1/50157-4
Novak MJ, Pattammattel A, Koshmerl B, Puglia M, Williams C, Kumar CV (2015) ‘Stable-on-the-table’ enzymes: engineering enzyme-graphene oxide interface for unprecedented stability of the biocatalysts. ACS Catal 6:339–447
Riccardi CM, Mistri D, Hart O, Anuganti M, Lin Y, Kasi RM, Kumar CV (2016) Covalent interlocking of glucose oxidase and peroxidase in the voids of paper: enzyme-polymer ‘spider-webs”. Chem Comm. doi:10.1039/c6cc00037a (5 Jan 16)
Deshapriya I, Stromer BS, Kim CS, Patel V, Gutkind JS, Kumar CV (2015) Novel, protein-based nanoparticles: improved half-lives, retention of protein structure and activities. Bioconj Chem 26:396–404
Pattammattel A, Kumar CV (2015) Kitchen chemistry 101: efficient exfoliation of high quality graphene with a blender and edible proteins. Adv Funct Mater, Oct 15/15 (in press)
Vranova V, Rejsek K, Formanek P (2013) Proteolytic activity in soil: a review. Appl Soil Ecol 70:23–32
Emery AEH (1984) An introduction to recombinant DNA. Taylor and Francis, Routledge
Thilakarathne VK, Briand VA, Ghimere A, Zore OV, Lenehan PJ, Kasi RM, Kumar CV (2015) Ultra-stable, hemoglobin-poly(acrylic) acid “Nanogels”. Chem Sci J Sept 29/15; Kumar CV, Benson KB, Baveghems C, Stromer BS, Thilakarathne VK, Novac MJ, Rossi (2015) Toward the design of bio-solar cells: high efficiency cascade energy transfer among four donor-acceptor dyes self assembled in highly ordered protein-DNA matrix. RSC Adv 5:72416–72422; Zore O, Pattamattel A, Gnanaguru S, Kumar CV, Kasi R (2015) Bienzyme-polymer-graphene oxide quaternary hybrid biocatalysts: efficient substrate channeling at chemically and thermally denaturing conditions. ACS Catal 5:4979–4988; Pattammattel A, Williams CL, Pande P, Tsui WG, Basu AK, Kumar CV (2015) Biological relevance of oxidative debris present in as-prepared graphene oxide. RSC Adv 5:59364–59372; Deshapriya I, Stromer BS, Kim CS, Patel V, Gutkind JS, Kumar CV (2015) Novel, protein-based nanoparticles: improved half-lives, retention of protein structure and activities. Bioconj Chem 26:396–404; Sun X, Ma X, Kumar CV, Lei Y (2014) Protein-based sensitive, selective and rapid fluorescence detection of picric acid. Anal Methods 6:8464–8468; Riccardi CM, Cole KS, Benson KR, Ward J, Bassett K, Zhang Y, Zore O, Stromer B, Kasi RM, Kumar CV (2014) Toward ‘stable-on-the-table’ enzymes: improving key properties of catalase by simple covalent conjugation with poly(acrylic acid). Bioconj Chem 25:1501–1510; Zore OV, Lenehan PJ, Kumar CV, Kasi RM (2014) Efficient biocatalysis in organic media with hemoglobin and poly(acrylic acid) nanogels. Langmuir 30:5176–5184
Duff MR Jr, Kumar, CV (2009) The metallomics approach: use of Fe(II) and Cu(II) footprinting to examine metal binding sites on serum albumins. Metallomics 1:518–523
Kumar CV, Buranaprapuk A (1999) Tuning the selectivity of protein photocleavage: spectroscopic and photochemical studies. J Am Chem Soc 121:4202–4210
Kumar CV, Buranaprapuk A (1997) Site specific photocleavage of proteins. Angew Chem Int Ed Engl 36:2085
Schmid A, Dordick JS, Hauer B, Kiener A, Wubbolts M, Witholt B (2001) Industrial biocatalysis today and tomorrow. Nature 409:258–268
Baldwin AD, Kiick KL (2010) Polysaccharide-modified synthetic polymeric biomaterials. Pept Sci Biopolymers 94:128–140
Ostwald W (1889) Lehrbuch der Allgemeinen Chemie. Part 1. Leipzig, Germany
Resch-Genger U, Grabolle M, Cavaliere-Jaricot S, Nitschke R, Nann T (2008) Quantum dots versus organic dyes as fluorescent labels. Nat Methods 5:763–775
Medintz IL, Uyeda T, Goldman ER, Mattoussi H (2005) Quantum dot bioconjugates for imaging, labeling and sensing. Nat Mater 4:435–446
Acknowledgements
Author thanks the Fulbright Foundation for a fellowship, and the National Science Foundation for partial financial support of this work (DMR-1401879).
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Kumar, C.V. (2017). Biological Materials. In: Nakato, T., Kawamata, J., Takagi, S. (eds) Inorganic Nanosheets and Nanosheet-Based Materials. Nanostructure Science and Technology. Springer, Tokyo. https://doi.org/10.1007/978-4-431-56496-6_22
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DOI: https://doi.org/10.1007/978-4-431-56496-6_22
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