Eugene Thacker on Thu, 8 Nov 2001 08:49:35 +0100 (CET) |
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<nettime> Wet Data talk |
³Wet Data: Biomedia & BioMEMS² (Talk given at the conference ³Fashioning the Future,² 4S Society for the Social Studies of Science, November 1-4, 2001, Cambridge, MA.) Eugene Thacker Georgia Institute of Technology eugene.thacker@lcc.gatech.edu ³There¹s Plenty of Room at the Bottom.² This was the title of a now-famous talk given in 1959, by the Nobel Laureate physicist Richard Feynman. In this paper Feynman outlined a vision of future technologies which would be able to control and design a range of miniature devices at the molecular and atomic levels. (His examples included writing the Encyclopedia Britannica on the head of a pin, as well as tiny mechanical manipulators and computer storage devices.) As Feynman pointed out, ³that enormous amounts of information can be carried in an exceedingly small space is, of course, well known to the biologists, and resolves the mystery which existed before we understood all this clearly, of how it could be that, in the tiniest cell, all of the information for the organization of a complex creature such as ourselves can be stored.² However, the example from molecular biology not only provides us with models for information storage, but for acting on and through that information. Feynman continues, suggesting that, ³biology is not simply writing information; it is doing something about itMany of the cells are very tiny, but they are very active.² With a hopeful, even prophetic tone, Feynman looks forward to a future where miniaturization makes possible what he calls ³surgeons you can swallow.² This vision was a major influence in contemporary fields such as nanotechnology and molecular biotechnology. It also resonates with contemporary science fiction, which imagined the promises and anxieties of a near-future technology able to design and control matter living and non-living at the molecular level. (Some examples include the ³intelligent² biochips in Greg Bear¹s novel Blood Music, and the self-organizing genetic algorithms in Greg Egan¹s novel Diaspora.) Some fifty years later, Feynman¹s vision is perhaps in the process of being realized in the space where biotechnology, engineering, and computer science intersect. These combined fields are investigating the development of micro-devices which combine biological and technological components, cells with integrated circuits, DNA with silicon. These micro-devices are known as ³bioMEMS.² MEMS is an acronym that stands for ³micro-electro-mechanical systems,² and the ³bio-³ prefix refers to MEMS technologies applied to biomedicine and biotechnology. One of the earliest MEMS-based research programs was initiated at DARPA. According to one of their textbooks on MEMS, ³Using the fabrication techniques and materials of microelectronics as a basis, MEMS processes construct both mechanical and electrical components. Mechanical components in MEMS, like transistors in microelectronics, have dimensions that are measured in micronsMEMS is not about any one single application or device, nor is it defined by a single fabrication process or limited to a few materials. More than anything else, MEMS is a fabrication approach that conveys the advantages of miniaturization, multiple components and microelectronics to the design and construction of integrated electromechanical systems.² To this we can also add a comment from MEMS Clearinghouse, an online hub for the MEMS industry, who state that ³MEMS promise to revolutionize nearly every product category by bringing together silicon-based microelectronics with micromachining technology, thereby making possible the realization of complete systems-on-a-chip.² While MEMS generally have found application in everything from airbags in cars to digital projection, one of the leading fields of MEMS research has been in biotech and biomedicine. Examples of such bioMEMS currently in development include: in vivo blood pressure sensors (with wireless telemetry), oligonucleotide microarrays (DNA chips), and microfluidics stations (labs-on-a-chip). BioMEMS not only include devices with electrical and mechanical components, but they also include devices which are produced using microelectronics fabrication technologies. Despite their highly-technical and pragmatic uses, I want to suggest that these tiny devices raise a series of philosophical questions, pertaining to the shifting relationships between the body and technology: For instance, how do these micro-devices transform the notion of the biological body in biomedicine and biotechnology? Are bioMEMS simply tools, or are they in some way viable, living systems? Do they prompt us to re-think our common definitions of media and technology? How do bioMEMS handle the different ³data types² which flow across biological and non-biological media? By way of addressing such questions we can begin with a formal analysis of bioMEMS. There are many different shapes and flavors of bioMEMS, from drug-delivery probes the size of a pill, to multi-layered chips for the analysis of biological samples. However, bioMEMS all share the commonalities of bringing together biological and non-biological materials into particular, engineered configurations, where they function in some integrated relationship to biological systems. In this sense bioMEMS point to issues pertaining to the boundary between biology and technology, the natural and artificial, and the organic and inorganic. However not all bioMEMS devices bring together the biological and technological in the same way. There are several areas of real-world applications in bioMEMS, and each provides us with a particular type of relationship between bodies and technologies: One primary area of application is in medical diagnostics. BioMEMS in this class include in vivo biosensors, for measuring blood pressure, as well as in vivo drug probes and chip-based optical prosthetics. In each case, a functioning MEMS device is implanted in the body, where it aims to function invisibly, as it were, in the biological milieu, while also gathering data about its environment (e.g., blood pressure levels), and then acting on that data (e.g., releasing a drug compound into the bloodstream). In more long-term scenarios, such bioMEMS would also be able to use wireless telemetry to send data outside the body to a receiving computer system (e.g., physician or home monitoring). In the context of medical diagnostics, bioMEMS highlight the relationship between a bioMEMS device and the biological milieu, ensuring the right ³fit² between them. The body¹s biological interior thus becomes a system receptive to a monitoring from the inside out. Another area of application includes biological sample preparation for biological assays or for biological sampling and screening. The micro-devices used for these purposes are known as ³microfluidics stations² (or ³labs on a chip²), because they integrate several sample preparation processes that were previously separated to different parts of the lab. Most often they are used for isolating, purifying, and amplifying desired components (such as DNA from a group of cells). Microfluidics use integrated circuit manufacturing techniques to design hand-held devices with a number of channels, reservoirs, and basins, for directing the flow of selected biomolecules. They are otherwise inert devices, until a biological sample is passed through them that is, until something ³resists² the device. In the context of biological sample preparation, bioMEMS highlight the relationship between biological and electro-mechanical components. Using either electrical conductivity or mechanical pressure, microfluidics stations create an environment in which molecules in a biological sample can essentially ³sort themselves out.² Finally, as a third area of application, current biotech research commonly makes use of bioMEMS devices for genome and proteomic sequencing and analysis. New lab technologies such as microarrays (DNA and protein chips) have not only shrunk the molecular biology lab, but have further integrated it with computer technologies. In such cases the goal is to further integrate the ³wet² data of DNA or proteins with the ³dry² data of biological sequence in computer databases. In these instances, bioMEMS highlight the space separating biological data and computer data, or biological and informatic networks. Analytical tools such as microarrays have as their main function the transmission of data types across media, and such devices act as a kind of fulcrum transmitting data from one ³platform² to another. What each of these areas of application, and their corresponding relationships demonstrate, is that bioMEMS devices further integrate biology and technology in novel ways. Despite this, bioMEMS do not represent a total fusion of biology and technology, and neither do they imply the effacement of that boundary altogether. This suggests that the hybrid quality of bioMEMS is not only to do with their material construction, but, more importantly, with their dynamical functioning within and across different systems. >From this view of dynamic systems, I want to suggest that at the core of bioMEMS technology is the transmission of data types across different media. For instance, in the example of biotech research, one possible scenario involves the following: A biological sample (e.g, blood) may be taken from a patient. Microfluidics stations may employ chip technology to isolate, purify, and amplify targeted DNA that is to be analyzed. The sample DNA, once isolated, may then be passed through a microarray (or DNA chip), where fragments of known DNA are attached to a silicon substrate. The DNA chip may then ³analyze² the sample through florescent-tagged hybridization. The resultant pattern of hybridization can then be scanned by the microarray computer, which digitizes the hybridization pattern (represented as a grid of colored dots), where it can be ported to software for microarray assays. That initial digital pattern is then ³decoded² or sequenced according to the known DNA on the DNA chip, and can then be compared to online genome databases (such as the human genome projects), to identify gene expression patterns associated with a given genetically-based disease. In this elaborate - but routine - process, there are not only several types of materialities at work, but there are also several data types being transmitted, translated, and passed through various media. Such a transmission of data types across variable media is what Lev Manovich calls ³transcoding.² In his analyses of computer-based ³new media,² Manovich suggests that transcoding involves not only the technical file conversion from one data format to another; it also involves the transmission of the metaphors, concepts, and categories of thought, from one medium to another. As he states, ³new media in general can be thought of as consisting of two distinct layers the cultural layer¹ and the computer layer¹[] Because new media is created on computers, distributed via computers, and stored and archived on computers, the logic of a computer can be expected to significantly influence the traditional cultural logic of media; that is, we may expect that the computer layer will affect the cultural layer.² In this sense, Manovich suggests, data transmitted across varying media (e.g., different database file formats; from digital video to Web animations to static digital images) not only pertain to what he calls the ³computer layer,² but they are indissociable from a ³cultural layer,² or the ways in which media ontologies affect our cultural views. In one sense, bioMEMS operate through principles of transcoding, as implied in their name the engineered combination of electrical, mechanical, and biological systems. However, unlike Manovich¹s characterizations of new media, which are based on a common logic of digitization, bioMEMS face the challenge of potentially incommensurable, resistant, or distorting transmissions across widely varying media. For instance, in the data transmissions between DNA, integrated circuits, and micro-actuators, the issues of biocompatibility, and digitization of the biological domain, must be taken into account. BioMEMS technologies thus present us with a paradox: on the one hand they ceaselessly hybridize biological and technological components and processes (e.g, the DNA chip); on the other hand they maintain the boundary between biology and technology, as implied in their design and application (e.g., as tools for genomics research). In approaching the relationship between biology and technology, bioMEMS appear to at once hold separate and yet mix together these two domains. How can bioMEMS maintain these two seemingly contradictory positions? In this sense bioMEMS must maintain a dual functionality, and they do this through a two-step process. The first is the bracketing of biological components and processes (e.g., DNA hybridization in the DNA chip), and the second is the technical re-purposing of those components/processes towards novel ends (e.g., for use in genome analysis). Biology functions as a technical means, that is nevertheless not separate from biological function. In such instances, technology is configured not so much as a tool, but as a set of conditions in which biology can act technically upon itself (i.e., the silicon in the DNA chip is passive, since DNA does all the work). This is a process that I¹ve been calling ³biomedia.² Put simply, biomedia is a term which describes the ways in which biology is reconfigured as a technology; in this it is one of the defining characteristics of biotechnology itself, as the technical conditioning of biological components and processes. For bioMEMS, the approach of biomedia is to combine biological with electro-mechanical principles, in order to generate certain types of data. This very logic puts forth several assumptions: First, that data inheres in ³wet² biomolecules in a way that is commensurate with ³dry² computer systems; second, that bioMEMS devices simply make explicit what was previous implicit (the ³natural² data of the organism); and third, that the body¹s data types is extensible (that beyond this natural data, there are other data types which can be technically developed, such as genomic profiling or molecular simulation). In one sense, bioMEMS are not unique, in that implantable devices, artificial organs, and prosthetics have long been the domain of biomedicine. What is unique about bioMEMS however, is their manifold intersections with new media (such as computer science and integrated circuit technologies). BioMEMS are not exactly tools (as are the X-ray, CT or MRI), in that part of what makes them function is the integration of living biological components; similarly, bioMEMS are not exactly intended to be biological replacements (as artificial organs are), in that they are engineered for the purposes of analysis and diagnostics. BioMEMS seem to hover somewhere between living and technological systems. As we¹ve suggested, a key to understanding this hovering is the approach of biomedia at once hybridizing and keeping separate the biological and technological domains. Again, these are material devices which raise a whole set of philosophical questions pertaining to the body and technology. Do these philosophical questions have any relevance in relation to bioMEMS and biotech? I want to suggest that they do, for they form the ontological basis from which principles of biomedical engineering begin, and from which a broader cultural understanding of the body in biotech and biomedicine may emerge. To this end, I would like to close with one suggestion for thinking about bioMEMS beyond the apparent paradoxes which they engender, and that is the perspective of ³design,² but design as a situated, open-ended activity that would reflect on its own processes. This reflexive thinking about design in relation to living systems is what Humberto Maturana has called ³metadesign.² Metadesign is a reflexive, bottom-up approach which places less emphasis on properties and components than on the types of transmissions, interactions, and resistances between systems. As Maturana states, ³the expansion of biotechnology has resulted in an expansion of the knowledge of living systems as structurally-determined systems and vice-versa. However it has not expanded our understanding of living systems as systems.² Instead of the traditional relationship between ethics, design, and living systems that is, make something first, then debate ethics afterwards Maturana¹s insistence on metadesign pushes for the need to consider ethics and design in an integrative fashion. This means, quite simply, that the seemingly extraneous cultural, philosophical, and political dynamics of the ³use² of living systems is indissociable from the design approach to hybrid systems such as bioMEMS. BioMEMS devices such as in vivo biosensors and DNA chips are interstitial devices, and an analysis of them suggests that, an understanding of changing views of the body in biotech & biomedicine can develop on the level of systems integration, multiple data types (wet data and dry data), and the relationships between different media (including the body). References DARPA Bioflips Program. http://www.darpa.mil/mto/bioflips. DARPA MEMS Program. http://www.darpa.mil/MTO/MEMS. Feynman, Richard. ³There¹s Plenty of Room at the Bottom.² Zyvex website. http://www.zyvex.com/nanotech/feynman.html. Manovich, Lev. The Language of New Media. Cambridge: MIT, 2000. Maturana, Humberto. ³Metadesign.² Technomorphica, ed. Joke Brower et al. Rotterdam: V2, 1997. MEMS Center. http://www.memscenter.com. MEMS Clearinghouse. http://www.memsnet.org. Michalicek, Adrian. An Introduction to Microelectromechanical Systems. Online presentation (2000): http://mems.colorado.edu/c1.res.ppt/ppt/g.tutorial/ppt.htm. National Research Council. Microelectromechanical Systems: Advanced Materials and Fabrication Methods. Washington D.C.: National Academy Press, 1997. Shuvo, Roy, et al. Microelectromechanical Systems and Neurosurgery: A New Era in a New Millennium. Neurosurgery 49:4 (October 2001): 779-91. Society for the Social Studies of Science (4S) conference: http://web.mit.edu/sts/www/4s/index.html. ¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬ Eugene Thacker, Assistant Prof School of Literature, Communication & Culture Georgia Institute of Technology eugene.thacker@lcc.gatech.edu http://www.lcc.gatech.edu/~ethacker ¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬¬ # distributed via <nettime>: no commercial use without permission # <nettime> is a moderated mailing list for net criticism, # collaborative text filtering and cultural politics of the nets # more info: majordomo@bbs.thing.net and "info nettime-l" in the msg body # archive: http://www.nettime.org contact: nettime@bbs.thing.net