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Potenziale für POCT im Internet of Things (IoT)

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POCT - Patientennahe Labordiagnostik

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Zusammenfassung

Dieses Kapitel beschäftigt sich mit aktuellen innovativen Ansätzen zur Weiterentwicklung des POCT und knüpft an Themen wie Telemonitoring, »ambient assisted living« und pHealth an. Aufgezeigt werden Trends und Treiber des Themas »personalized health« mit dem Schwerpunkt Selbstmonitoring, unter Einbeziehung der technischen Basis, die diese Entwicklungen ermöglicht. Selbstmonitoring erfolgt häufig unter Verwendung intelligenter miniaturisierter Komponenten bzw. Computersysteme, sog. Wearables. Wearables interagieren in der Regel drahtlos über entsprechende Netzwerke, deren konzeptionell weitestgehende Ausprägung das »Internet der Dinge« (»Internet of Things«) darstellt. Die Methoden zur Datenauswertung werden unter dem Begriff »Big-Data-Analyse« zusammengefasst.

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Literatur

  1. Anonymous (2000) In: Kohn LT, Corrigan JM, Donaldson MS (eds) To Err is Human: Building a Safer Health System. Washington (DC)

    Google Scholar 

  2. Banaee H, Ahmed MU, Loutfi A (2013) Data mining for wearable sensors in health monitoring systems: a review of recent trends and challenges. Sensors (Basel) 13:17472–17500

    Google Scholar 

  3. Blenner SR, Köllmer M, Rouse AJ et al. (2016) Privacy policies of android diabetes apps and sharing of health information. JAMA 315:1051–1052

    Google Scholar 

  4. Freckmann G, Schmid C, Baumstark A et al. (2012) System Accuracy Evaluation of 43 Blood Glucose Monitoring Systems for Self-Monitoring of Blood Glucose according to DIN EN ISO 15197. Journal of Diabetes Science and Technology 6:1060–1075

    Google Scholar 

  5. Gao W, Emaminejad S, Nyein HYY et al. (2016) Fully integrated wearable sensor arrays for multiplexed in situ perspiration analysis. Nature 529:509–514

    Google Scholar 

  6. https://blog.wdr.de/digitalistan/cebit-2016-ich-war-zu-feige-mir-diesen-cyborg-chip-implantieren-zu-lassen/

  7. http://review.gemalto.com/post/the-future-of-wearables-video

  8. https://de.statista.com/infografik/4426/weltweiter-markt-fuer-wearables/

  9. http://de.statista.com/statistik/daten/studie/173048/umfrage/weltweiter-absatz-der-smartphone-hersteller-nach-quartalen/

  10. https://digiwell.de/252/dangerous-things-xnt-rfid-nfc-implantat-comfort-kit?c=258

  11. http://dx.doi.org/10.1038/nature16521

  12. http://fortune.com/2015/12/18/fda-wearables-health/

  13. http://mobihealthnews.m/content/study-12-percent-us-consumers-own-fitness-band-or-smartwatch

  14. http://people.cis.ksu.edu/~hatcliff/890-High-Assurance/Reading/YaoSchmitzWarren-TITB.pdf

  15. https://rockhealth.com/reports/predictive-analytics/

  16. http://support.polar.com/de/support/the_what_and_how_of_orthostatic_test

  17. http://www.aktiv-imleben.de/den-megatrend-healthstyle-zum-lifestyle-machen

  18. http://www.beechamresearch.com/files/BRL %20Wearable %20Tech %20Report %20Outline.pdf

  19. https://www.bitkom-akademie.de/news-info/big-data-analysen- %E2 %80 %93-die-zukunft-vorhersagen-statt-nur-reports-erstellen

  20. http://www.iis.fraunhofer.de/de/ff/lok/proj/opal.html

  21. http://www.gsaglobal.org/events/2014/0513/documents/HarryStrasserWearableTechnologiesGSA052014.pdf

  22. http://www.kma-online.de/guide/medica/it/wearables-smarte-accessoires-auf-dem-weg-zum-medizinprodukt___id__36227___view.html

  23. https://www.medien.ifi.lmu.de/lehre/ws0607/mmi1/essays/Felix-Lauber.xhtml#geschichte-des-wearable-computing

  24. https://www.pwc.de/de/technologie-medien-und-telekommunikation/assets/pwc-media-trend-outlook_wearables.pdf

  25. https://www.tagesschau.de/inland/cebit-chips-technik-messe-101.html

  26. http://www.trendsderzukunft.de/wearables-neue-schweiss-sensoren-liefern-gesundheitsdaten-in-echtzeit/2016/01/28

  27. http://www.tuev-sued.de/tuev-sued-konzern/presse/pressearchiv/tuv-sud-stellt-neues-prufzeichen-fur-wearables-vor

  28. http://www.ubiq.com/hypertext/weiser/SciAmDraft3.html

  29. http://www.wearable-technologies.com/»Wearable Technologies is the pioneer and worldwide leading innovation and market development platform for Technologies worn close to the body, on the body or even in the body«

  30. http://www.zdnet.de/88256118/ces-ibm-bringt-watson-in-wearables-und-roboter/

  31. Kish LJ, Topol EJ (2015) Unpatients – why patients should own their medical data. Nat Biotech 33:921–924

    Google Scholar 

  32. Komatireddy R, Topol EJ (2012) Medicine unplugged: the future of laboratory medicine. Clin Chem 58:1644–1647

    Google Scholar 

  33. Lippi G, Favaloro EJ, Plebani M (2011) Direct-to-consumer testing: more risks than opportunities. Int J Clin Pract 65:1221–1229

    Google Scholar 

  34. Nichols JH (2011) Blood glucose testing in the hospital: error sources and risk management. J Diabetes Sci Technol 5:173–177

    Google Scholar 

  35. Schmedt M (2016) Fitness-Tracker: Der Datenhunger wächst. Dtsch Arztebl International 113:257–258

    Google Scholar 

  36. Swan M (2013) The quantified self: Fundamental disruption in big data science and biological discovery. Big Data 1:85–99

    Google Scholar 

  37. Varma N (2007) Rationale and design of a prospective study of the efficacy of a remote monitoring system used in implantable cardioverter defibrillator follow-up: The Lumos-T Reduces Routine Office Device Follow-Up Study (TRUST) Study. Am Heart J;154:1029–34

    Google Scholar 

  38. Zeevi D, Korem T, Zmora N et al. (2015) Personalized nutrition by prediction of glycemic responses. Cell 163:1079–1094

    Google Scholar 

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Author information

Authors and Affiliations

  1. TCI GmbH, Wildbader Straße 9, 68239, Mannheim, Deutschland

    Christina Rode-Schubert

  2. IIS/BMT, Fraunhofer Institut für Integrierte Schaltungen, Am Wolfsmantel 33, 91058, Erlangen, Deutschland

    Thomas Norgall

  3. Institut für Klinische Chemie und Pathobiochemie, Klinikum rechts der TU München, Ismaninger Straße 22, 81675, München, Deutschland

    Dr. Andreas Bietenbeck

Authors
  1. Christina Rode-Schubert
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  2. Thomas Norgall
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  3. Dr. Andreas Bietenbeck
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Editor information

Editors and Affiliations

  1. TU München Klinikum rechts der Isar, München, Deutschland

    Peter B. Luppa

  2. Universitätsklinikum Schleswig-Holstein, Kiel, Deutschland

    Ralf Junker

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Rode-Schubert, C., Norgall, T., Bietenbeck, A. (2017). Potenziale für POCT im Internet of Things (IoT). In: Luppa, P., Junker, R. (eds) POCT - Patientennahe Labordiagnostik. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-54196-8_42

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