nach oben

NanoEthics

Erschienen in:

04.01.2020 | Original Research Paper

The Diversity of Engineering in Synthetic Biology

verfasst von: Massimiliano Simons

Erschienen in: NanoEthics | Ausgabe 1/2020

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

A recurrent theme in the characterization of synthetic biology is the role of engineering. This theme is widespread in the accounts of scholars studying this field and the biologists working in it, in those of the biologists themselves, as well as in policy documents. The aim of this article is to open this black-box of engineering that is supposed to influence and change contemporary life sciences. Too often, both synthetic biologists and their critics assume a very narrow understanding of what engineering is about, resulting in an unfruitful debate about whether synthetic biology possesses genuine engineering methodologies or not. By looking in more detail to the diversity of engineering conceptions in debates concerning synthetic biology, a richer perspective can be developed. In this article, I will examine five influential ways in which engineering is understood in these debates, namely engineering as applied science, as rational methodology, context-sensitive practice, cunning activity or design. The claim is first of all thus to argue that engineering must not be seen as something stable or characterized by a fixed essence. It rather has multiple meanings and interpretations. Secondly, the claim is that most of the debates on synthetic biology cannot be indifferent towards the question which conception of engineering is at play, since the specific questions and concerns that pop up depend to a great extent on the precise conception of engineering one has in account. Many of the existing debates around synthetic biology can thus be reinterpreted and readdressed once one is aware of which conception of engineering is at play.

Vorheriger Artikel Living Machines: Metaphors We Live By

Nächster Artikel Art-Science Collaboration in an EPSRC/BBSRC-Funded Synthetic Biology UK Research Centre

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Synthetic biologists also rewrite the history of biology in light of the ideal of ‘engineering life’ [11].

Rabinow P, Bennett G (2012) Designing human practices: an experiment with synthetic biology. The University of Chicago Press, Chicago

Roosth S (2017) Synthetic: how life got made. The University of Chicago Press, Chicago

Giese B, Koenigstein S, Wigger H, Schmidt J, Gleich A (2013) Rational engineering principles in synthetic biology: a framework for quantitative analysis and an initial assessment. Biol Theory 8(4):324–333

Endy D (2005) Foundations for engineering biology. Nature 438(7067):449–453

Endy D (2008) Synthetic biology: can we make biology easy to engineer? Ind Biotechnol 4(4):340–351

Andrianantoandro E, Basu S, Karig D, Weiss R (2006) Synthetic biology: new engineering rules for an emerging discipline. Mol Syst Biol 2(1):1–14

Heinemann M, Panke S (2006) Synthetic biology—putting engineering into biology. Bioinformatics 22(22):2790–2799

Church G, Regis E (2012) Regenesis. How synthetic biology will reinvent nature and ourselves. Basic Books, New York

Képès F (2011) La biologie de synthèse: plus forte que la nature? Le Pommier, Paris

10.

De Lorenzo V, Danchin A (2008) Synthetic biology: discovering new worlds and new words. EMBO Rep 9(9):822–827

11.

Bensaude-Vincent B (2013) Discipline-building in synthetic biology. Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 44(2):122–129

12.

European Commission (2005) Synthetic biology. Applying engineering to biology. Report of a NEST high‐level expert group EU 21796. Brussels.

13.

UK synthetic biology roadmap (2012). https://connect.innovateuk.org/web/syntheticbiology-special-interest-group/roadmap-for-synthetic-biology Accessed on 1 October 2018

14.

Boudry M, Pigliucci M (2013) The mismeasure of machine: synthetic biology and the trouble with engineering metaphors. Stud Hist Phil Biol Biomed Sci 44(4):660–668

15.

Pauwels E (2013) Mind the metaphor. Nature 500(7464):523–524

16.

O'Malley M (2009) Making knowledge in synthetic biology: design meets kludge. Biol Theory 4(4):378–389

17.

Lewens T (2013) From bricolage to BioBricks™: synthetic biology and rational design. Stud Hist Phil Biol Biomed Sci 44(4):641–648

18.

Frow E, Calvert J (2013) ‘Can simple biological systems be built from standardized interchangeable parts?’ Negotiating biology and engineering in a synthetic biology competition. Eng Stud 5(1):42–58

19.

Schyfter P (2013) Propellers and promoters: emerging engineering knowledge in aeronautics and synthetic biology. Eng Stud 5(1):6–25

20.

Schyfter P, Calvert J (2015) Intentions, expectations and institutions: engineering the future of synthetic biology in the USA and the UK. Sci Cult 24(4):1–25

21.

Vincenti W (1990) What engineers know and how they know it. The Johns Hopkins University Press, Baltimore

22.

Van de Poel I (2010) Philosophy and engineering: setting the stage. In: Van de Poel I, Goldberg DE (eds) Philosophy and engineering: an emerging agenda. Springer, Dordrecht, pp 1–11

23.

Bunge M (1966) Technology as applied science. Technol Cult 7(3):329–347

24.

Godin B (2006) The linear model of innovation: the historical construction of an analytical framework. Sci Technol Hum Values 31(6):639–667

25.

SCENHR (2014) Opinion on synthetic biology I: definition. European Commission, Luxembourg

26.

Carlson R (2011) Biology is technology. Harvard University Press, Cambridge, MA

27.

Pardee K (2018) Perspective: solidifying the impact of cell-free synthetic biology through lyophilisation. Biochem Eng J 138:91–97

28.

Smith M, Wilding K, Hunt J, Bennett A, Bundy B (2014) The emerging age of cell-free synthetic biology. FEBS Lett 588:2755–2761

29.

Harris D, Jewett M (2012) Cell-free biology: exploiting the interface between synthetic biology and synthetic chemistry. Curr Opin Biotechnol 23:672–678

30.

Hodgman C, Jewett M (2012) Cell-free synthetic biology: thinking outside of the cell. Metab Eng 14:261–269

31.

Nirenberg M, Matthaei J (1961) The dependence of cell-free protein synthesis in E. coli upon naturally occurring or synthetic polyribonucleotides. Proc Natl Acad Sci USA 47:1588–1602

32.

Katzen F, Chang G, Kudlicki W (2005) The past, present and future of cell-free protein synthesis. Trends Biotechnol 23(3):150–156

33.

Carlson E, Gan R, Hodgman C, Jewett M (2012) Cell-free protein synthesis: applications come of age. Biotechnol Adv 30:1185–1194

34.

Calvert J (2010) Synthetic biology: constructing nature? Sociol Rev 58:95–112

35.

Calvert J (2008) The commodification of emergence: systems biology, synthetic biology and intellectual property. BioSocieties 3(4):383–398

36.

Radder H (ed) (2010) The commodification of academic research: science and the modern university. University of Pittsburgh Press, Pittsburgh

37.

Doudna J, Sternberg S (2017) A crack in creation: gene editing and the unthinkable power to control evolution. Houghton Mifflin, Boston

38.

Mitcham C (1994) Thinking through technology: the path between engineering and philosophy. University of Chicago Press, Chicago

39.

Calvert J (2006) What’s special about basic research? Sci Technol Hum Values 31(2):199–220

40.

Schauz D (2014) What is basic research? Insights from historical semantics. Minerva 52(3):273–328

41.

Gieryn T (1999) Cultural boundaries of science: credibility on the line. University of Chicago Press, Chicago, Chicago

42.

Agapakis C, Silver P (2009) Synthetic biology: exploring and exploiting genetic modularity through the design of novel biological networks. Mol BioSyst 5(7):704–713

43.

Elfick A, Endy D (2014) Synthetic biology: what it is and why it matters. In: Endy D, Elfick A, Schyfter P, Calvert J, Ginsberg AD (eds) Synthetic aesthetics: investigating synthetic biology's designs on nature. MIT Press, Cambridge, pp 3–25

44.

Bud R (1991) Biotechnology in the twentieth century. Soc Stud Sci 21(3):415–457

45.

Boldt J (2013) Creating life: synthetic biology and ethics. In: Kaebnick G, Murray TH (eds) Synthetic biology and morality: artificial life and the bounds of nature. MIT press, Cambridge, pp 35–50

46.

Boldt J, Müller O (2008) Newtons of the leaves of grass. Nat Biotechnol 26(4):387–389

47.

Campos L (2009) That was the synthetic biology that was. In: Schmidt M, Kelle A, Ganguli-Mitra A, de Vriend H (eds) Synthetic biology: The technoscience and its consequences. Springer, Dordrecht, pp 5–21

48.

Morange M (2012) Synthetic biology: a challenge to mechanical explanations in biology? Perspect Biol Med 55(4):543–553

49.

Jacob F (1977) Evolution and tinkering. Science 196(4295):1161–1166

50.

Morange M (2009) Synthetic biology: a bridge between functional and evolutionary biology. Biol Theory 4(4):368–377

51.

Bensaude-Vincent B, Benoit-Browaeys D (2011) Fabriquer la vie: Où va la biologie de synthèse? Seuil, Paris

52.

Calvert J (2013) Engineering biology and society: reflections on synthetic biology. Sci Technol Soc 18(3):405–420

53.

Nordmann A (2015) Synthetic biology at the limits of science. In: Giese B, Pade C, Wigger H, von Gleich A (eds) Synthetic biology: character and impact. Springer, Cham, pp 31–58

54.

Calcott B, Levy A, Siegal M, Soyer O, Wagner A (2015) Engineering and biology: counsel for a continued relationship. Biol Theory 10(1):50–59

55.

Galison P (1997) Image and logic: a material culture of microphysics. University of Chicago Press, Chicago

56.

Henderson K (1999) On line and on paper: visual representations, visual culture, and computer graphics in design engineering. MIT Press, Cambridge, MA

57.

Henderson K (1991) Flexible sketches and inflexible data bases: visual communication, conscription devices, and boundary objects in design engineering. Sci Technol Hum Values 16(4):448–473

58.

Cooley M (1980) Architect or bee? The human/technology relationship. South End Press, Boston

59.

Rogers C (1983) The nature of engineering: a philosophy of technology. Macmillan, London

60.

Houkes, W (2008) The nature of technological knowledge. In: Meijers, A (ed) (2008). Philosophy of technology and engineering sciences. Elsevier, Amsterdam, pp 309–350

61.

Layton E (1984) Science and engineering design. Ann N Y Acad Sci 424(1):173–181

62.

Ryle G (1971) Knowing how and knowing that. In: Collected Papers (Volume 2). Barnes and Nobles, New York, pp 212–225

63.

Polanyi M (1967) The tacit dimension. Doubleday, Garden City

64.

Ferguson E (1992) Engineering and the mind’s eye. MIT Press, Cambridge, MA

65.

Kuldell N, Bernstein R, Ingram K, Hart K (2015) BioBuilder: synthetic biology in the lab. O'Reilly, Sebastopol

66.

Law J (1987) Technology and heterogeneous engineering: the case of Portuguese expansion. In: Bijker W, Hughes T, Pinch T (eds) The social construction of technological systems: new directions in the sociology and history of technology. MIT Press, Cambridge, MA, pp 111–134

67.

Kogge W, Richter M (2013) Synthetic biology and its alternatives. Descartes, Kant and the idea of engineering biological machines. Stud Hist Phil Biol Biomed Sci 44:181–189

68.

Auyang S (2004) Engineering: endless frontier. Harvard University Press, Cambridge, MA

69.

Picon A (2004) Engineers and engineering history: problems and perspectives. Hist Technol 20(4):421–436

70.

Vérin H (1993) La gloire des ingénieurs : L'intelligence technique du XVIe au XVIIIe siècle. Albin Michel, Paris

71.

Flusser V (1999) The shape of things: a philosophy of design. Reaktion Books, London

72.

Detienne M, Vernant JP (1978) Cunning intelligence in Greek culture and society. Harvester Press, Hassocks

73.

Horkheimer M, Adorno TW (1972) Dialectic of enlightenment. Herder and Herder, New York

74.

Keller E (2002) Making sense of life: explaining biological development with models, metaphors, and machines. Harvard University Press, Cambridge, MA

75.

Gibson D et al (2010) Creation of a bacterial cell controlled by a chemically synthesized genome. Science 329(5987):52–56

76.

Pennisi E (2010) Genomics. Synthetic genome brings new life to bacterium. Science 328(5981):958–959

77.

Bedau M, Church G, Rasmussen S, Caplan A, Benner S, Fussenegger M, Collins J, Deamer D (2010) Life after the synthetic cell. Nature 465(7297):422–424

78.

Bryksin A, Brown A, Baksh M, Finn M, Barker T (2014) Learning from nature—novel synthetic biology approaches for biomaterial design. Acta Biomater 10(4):1761–1769

79.

Venter C (2013) Life at the speed of light: from the double helix to the dawn of digital life. Viking, New York

80.

Cambray G, Mutalik V, Arkin A (2011) Toward rational design of bacterial genomes. Curr Opin Microbiol 14:624–630

81.

Marrguet P, Balagadde F, Tan C, You L (2007) Biology by design: reduction and synthesis of cellular components and behavior. J R Soc Interface 4:607–623

82.

Delgado A, Porcar M (2013) Designing de novo: interdisciplinary debates in synthetic biology. Syst Synth Biol 7(1-2):41–50

83.

Drubin D, Way J, Silver P (2007) Designing biological systems. Genes Dev 21:242–254

84.

Deplazes A (2009) Piercing together a puzzle. EMBO Rep 10(5):428–432

85.

Schmidt M, Ganguli-Mitra A, Torgersen H, Kelle A, Deplazes A, Biller-Andorno N (2009) A priority paper for the societal and ethical aspects of synthetic biology. Syst Synth Biol 3:3–7

86.

Rabinow P (2009) Prosperity, amelioration, flourishing: from a logic of practical judgment to reconstruction. Law and Literature 21(3):301–320

87.

Synthetic Biology Leadership Council (2016) Biodesign for the Bioeconomy. UK Synthetic Biology Strategic Plan 2016 https://static1squarespacecom/static/54a6bdb7e4b08424e69c93a1/t/589619873e00be743c62a76e/1486231951837/BioDesign+for+the+Bioeconomy+2016+-+DIGITALpdf. Accessed 1 October 2018

88.

Galle P, Kroes P (2014) Science and design: identical twins? Des Stud 35(3):201–231

89.

Ammon S (2017) Why designing is not experimenting: design methods, epistemic praxis and strategies of knowledge acquisition in architecture. Philosophy & Technology 30(4):495–520

90.

Seely B (1993) Research, engineering, and science in American engineering colleges: 1900-1960. Technol Cult 34(2):344–386

91.

Seely B (1999) The other re-engineering of engineering education, 1900–1965. J Eng Educ 88(3):285–294

92.

Sheppard SD, Macatangay K, Colby A, Sullivan WM, Shulman LS (2009) Educating engineers: designing for the future of the field. Jossey-Bass, San Francisco

93.

Lewin D (1979) On the place of design in engineering. Des Stud 1(2):113–117

94.

Creed M (1990) On an educational philosophy towards civil engineering design. In: McCabe V (ed) Design in engineering education. SEFI, Brussels, pp 75–78

95.

Cross N (2001) Designerly ways of knowing: design discipline versus design science. Des Issues 17(3):49–55

96.

Simon H (1984) The sciences of the artificial. MIT Press, Cambridge, MA

97.

Schön D (1983) The reflective practitioner. Temple-Smith, London

98.

Petroski H (1995) Design paradigms: case histories of error and judgment in engineering. Cambridge University Press, Cambridge

99.

Akera A, Seely B (2015) A historical survey of the structural changes in the American system of engineering education. In: Christensen S, Didier C, Jamison A, Meganck M, Mitcham C, Newberry B (eds) International perspectives on engineering education. Springer, Cham, pp 7–32

100.

Williams R (2003) Retooling: a historian confronts technological change. MIT Press, Cambridge, MA

101.

Ijäs T (2018) Design under randomness: how variation affects the engineering of biological systems. Biol Theory 13(3):153–163

102.

Wang H, Church G (2011) Multiplexed genome engineering and genotyping methods: applications for synthetic biology and metabolic engineering. Methods Enzymol 498:409–426

103.

Raman S, Rogers JK, Taylor ND, Church G (2014) Evolution-guided optimization of biosynthetic pathways. Proc Natl Acad Sci 111(50):17803–17808

104.

Rogers J, Church G (2016) Multiplexed engineering in biology. Trends Biotechnol 34(3):198–206

105.

Carr P, Church G (2009) Genome engineering. Nat Biotechnol 27(12):1151–1162

106.

Wang H, Isaacs FJ, Carr P, Sun Z, Xu G, Forest C, Church G (2009) Programming cells by multiplex genome engineering and accelerated evolution. Nature 460(7257):894–898

107.

Fujimura J (2005) Postgenomic futures: translations across the machine-nature border in systems biology. New Genetics and Society 24(2):195–226

108.

Green S (2017) Introduction to philosophy of systems biology. In: Green S (ed) Philosophy of systems biology: perspectives from scientists and philosophers. Springer, Dordrecht, pp 1–23

Titel: The Diversity of Engineering in Synthetic Biology
verfasst von: Massimiliano Simons
Publikationsdatum: 04.01.2020
Verlag: Springer Netherlands
Erschienen in: NanoEthics / Ausgabe 1/2020
Print ISSN: 1871-4757
Elektronische ISSN: 1871-4765
DOI: https://doi.org/10.1007/s11569-019-00348-1

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Wirtschaft"

Weitere Artikel der Ausgabe 1/2020

Art-Science Collaboration in an EPSRC/BBSRC-Funded Synthetic Biology UK Research Centre

Generative Critique in Interdisciplinary Collaborations: From Critique in and of the Neurosciences to Socio-Technical Integration Research as a Practice of Critique in R(R)I

Living Machines: Metaphors We Live By

BrisSynBio Art-Science Dossier

Noise and Synthetic Biology: How to Deal with Stochasticity?

Philosophy and Synthetic Biology: the BrisSynBio Experiment