nach oben

Erschienen in:

2019 | OriginalPaper | Buchkapitel

6. The Many Roads to an Ideal Paper-based Device

verfasst von : Margot Karlikow, Keith Pardee

Erschienen in: Paper-based Diagnostics

Verlag: Springer International Publishing

Einloggen

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

search-config

KI-gestützte Suche

Aus

Abstract

The recent Zika and Ebola virus outbreaks highlight the need for low-cost diagnostics that can be rapidly deployed and used outside of established clinical infrastructure. This demand for robust point-of-care (POC) diagnostics is further driven by the increasing burden of drug-resistant diseases, concern for food and water safety, and bioterrorism. As has been discussed in previous chapters, paper-based tests provide a simple and compelling solution to such needs.

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 "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Vorheriges Kapitel Printed Functionalities on Paper Substrates Towards Fulfilment of the ASSURED Criteria

Nächstes Kapitel The Fascination of Paper

Yagoda H (1937) Applications of confined spot tests in analytical chemistry: preliminary paper. Ind Eng Chem Anal Ed 9:79–82CrossRef

Davies RJ, Eapen SS, Carlisle SJ (2008) Lateral-flow Immunochromatographic assays. In: Handbook of biosensors and biochips. John Wiley & Sons, Ltd, New JerseyCrossRef

Anderson CE, Shah KG, Yager P (2017) Sensitive protein detection and quantification in paper-based microfluidics for the point of care. Methods Enzymol 589:383–411CrossRef

Sia SK, Linder V, Parviz BA, Siegel A, Whitesides GM (2004) An integrated approach to a portable and low-cost immunoassay for resource-poor settings. Angew Chem Int Ed 43:498–502CrossRef

Martinez AW, Phillips ST, Butte MJ, Whitesides GM (2007) Patterned paper as a platform for inexpensive, low-volume, portable bioassays. Angew Chem Int Ed 46:1318–1320CrossRef

WHO (2004) TDR|Mapping the landscape of diagnostics for sexually transmitted infections [WWW Document]. WHO. http://www.who.int/tdr/publications/tdr-research-publications/mapping-landscape-sti/en/. Accessed 7 July 2017

Brehm-Stecher B, Young C, Jaykus L-A, Tortorello ML (2009) Sample preparation: the forgotten beginning. J Food Prot 72:1774–1789CrossRef

Mariella R (2008) Sample preparation: the weak link in microfluidics-based biodetection. Biomed Microdevices 10:777–784CrossRef

Niemz A, Ferguson TM, Boyle DS (2011) Point-of-care nucleic acid testing for infectious diseases. Trends Biotechnol 29:240–250CrossRef

10.

Tang RH, Yang H, Choi JR, Gong Y, Feng SS, Pingguan-Murphy B, Huang QS, Shi JL, Mei QB, Xu F (2016) Advances in paper-based sample pretreatment for point-of-care testing. Crit Rev Biotechnol 1–18

11.

Kumar AA, Hennek JW, Smith BS, Kumar S, Beattie P, Jain S, Rolland JP, Stossel TP, Chunda-Liyoka C, Whitesides GM (2015) From the bench to the field in low-cost diagnostics: two case studies. Angew Chem Int Ed Engl 54:5836–5853CrossRef

12.

Anderson NL, Anderson NG (2002) The human plasma proteome: history, character, and diagnostic prospects. Mol Cell Proteomics 1:845–867CrossRef

13.

Obermoser G, Presnell S, Domico K, Xu H, Wang Y, Anguiano E, Thompson-Snipes L, Ranganathan R, Zeitner B, Bjork A, Anderson D, Speake C, Ruchaud E, Skinner J, Alsina L, Sharma M, Dutartre H, Cepika A, Israelsson E, Nguyen P, Nguyen Q-A, Harrod AC, Zurawski SM, Pascual V, Ueno H, Nepom GT, Quinn C, Blankenship D, Palucka K, Banchereau J, Chaussabel D (2013) Systems scale interactive exploration reveals quantitative and qualitative differences in response to influenza and pneumococcal vaccines. Immunity 38:831–844CrossRef

14.

Robison EH, Mondala TS, Williams AR, Head SR, Salomon DR, Kurian SM (2009) Whole genome transcript profiling from fingerstick blood samples: a comparison and feasibility study. BMC Genomics 10:617CrossRef

15.

Paliwal S, Hwang BH, Tsai KY, Mitragotri S (2013) Diagnostic opportunities based on skin biomarkers. Eur J Pharm Sci 50:546–556CrossRef

16.

Fernando GJP, Chen X, Prow TW, Crichton ML, Fairmaid EJ, Roberts MS, Frazer IH, Brown LE, Kendall MAF (2010) Potent immunity to low doses of influenza vaccine by probabilistic guided micro-targeted skin delivery in a mouse model. PLoS One 5:e10266CrossRef

17.

Matriano JA, Cormier M, Johnson J, Young WA, Buttery M, Nyam K, Daddona PE (2002) Macroflux microprojection array patch technology: a new and efficient approach for intracutaneous immunization. Pharm Res 19:63–70CrossRef

18.

Prausnitz MR (2004) Microneedles for transdermal drug delivery. Adv Drug Deliv Rev 56:581–587CrossRef

19.

Wang PM, Cornwell M, Prausnitz MR (2005) Minimally invasive extraction of dermal interstitial fluid for glucose monitoring using microneedles. Diabetes Technol Ther 7:131–141CrossRef

20.

Corrie SR, Fernando GJP, Crichton ML, Brunck MEG, Anderson CD, Kendall MAF (2010) Surface-modified microprojection arrays for intradermal biomarker capture, with low non-specific protein binding. Lab Chip 10:2655–2658CrossRef

21.

Lee KT, Muller DA, Coffey JW, Robinson KJ, McCarthy JS, Kendall MAF, Corrie SR (2014) Capture of the circulating Plasmodium falciparum biomarker HRP2 in a multiplexed format, via a wearable skin patch. Anal Chem 86:10474–10483CrossRef

22.

Matriano JA, Cormier MJN (2004). Method for transdermal nucleic acid sampling. US6749575 B2

23.

Aas JA, Paster BJ, Stokes LN, Olsen I, Dewhirst FE (2005) Defining the normal bacterial Flora of the oral cavity. J Clin Microbiol 43:5721–5732CrossRef

24.

Muzanye G, Morgan K, Johnson J, Mayanja-Kizza H (2009) Impact of mouth rinsing before sputum collection on culture contamination. Afr Health Sci 9:200

25.

Boehme CC, Nabeta P, Hillemann D, Nicol MP, Shenai S, Krapp F, Allen J, Tahirli R, Blakemore R, Rustomjee R, Milovic A, Jones M, O’Brien SM, Persing DH, Ruesch-Gerdes S, Gotuzzo E, Rodrigues C, Alland D, Perkins MD (2010a) Rapid molecular detection of tuberculosis and rifampin resistance. N Engl J Med 363:1005–1015CrossRef

26.

Ferguson TM, Weigel KM, Lakey Becker A, Ontengco D, Narita M, Tolstorukov I, Doebler R, Cangelosi GA, Niemz A (2016a) Pilot study of a rapid and minimally instrumented sputum sample preparation method for molecular diagnosis of tuberculosis. Sci Rep 6:19541CrossRef

27.

Chanda-Kapata P, Kapata N, Klinkenberg E, Grobusch MP, Cobelens F (2017) The prevalence of HIV among adults with pulmonary TB at a population level in Zambia. BMC Infect Dis 17:236CrossRef

28.

Perkins MD, Cunningham J (2007) Facing the crisis: improving the diagnosis of tuberculosis in the HIV era. J Infect Dis 196:S15–S27CrossRef

29.

Mansuy JM, Mengelle C, Pasquier C, Chapuy-Regaud S, Delobel P, Martin-Blondel G, Izopet J (2017) Zika virus infection and prolonged Viremia in whole-blood specimens. Emerg Infect Dis 23:863–865CrossRef

30.

Barzon L, Pacenti M, Berto A, Sinigaglia A, Franchin E, Lavezzo E, Brugnaro P, Palù G (2016) Isolation of infectious Zika virus from saliva and prolonged viral RNA shedding in a traveller returning from the Dominican Republic to Italy, January 2016. Eur Secur 21:30159CrossRef

31.

Atkinson B, Hearn P, Afrough B, Lumley S, Carter D, Aarons EJ, Simpson AJ, Brooks TJ, Hewson R (2016) Detection of Zika virus in semen. Emerg Infect Dis 22:940CrossRef

32.

Mansuy JM, Dutertre M, Mengelle C, Fourcade C, Marchou B, Delobel P, Izopet J, Martin-Blondel G (2016) Zika virus: high infectious viral load in semen, a new sexually transmitted pathogen? Lancet Infect Dis 16:405CrossRef

33.

Panpradist N, Toley BJ, Zhang X, Byrnes S, Buser JR, Englund JA, Lutz BR (2014) Swab sample transfer for point-of-care diagnostics: characterization of swab types and manual agitation methods. PLoS One 9:e105786CrossRef

34.

Huang S, Abe K, Bennett S, Liang T, Ladd PD, Yokobe L, Anderson CE, Shah K, Bishop J, Purfield M, Kauffman PC, Paul S, Welch AE, Strelitz B, Follmer K, Pullar K, Sanchez-Erebia L, Gerth-Guyette E, Domingo GJ, Klein E, Englund JA, Fu E, Yager P (2017) Disposable autonomous device for rapid swab-to-result diagnosis of influenza. Anal Chem

35.

Liu C, Mauk M, Gross R, Bushman FD, Edelstein PH, Collman RG, Bau HH (2013) Membrane-based, sedimentation-assisted plasma separator for point-of-care applications. Anal Chem 85:10463–10470CrossRef

36.

Son JH, Lee SH, Hong S, Park S, Lee J, Dickey AM, Lee LP (2014) Hemolysis-free blood plasma separation. Lab Chip 14:2287–2292CrossRef

37.

Chatterjee A, Mirer PL, Zaldivar Santamaria E, Klapperich C, Sharon A, Sauer-Budge AF (2010) RNA isolation from mammalian cells using porous polymer monoliths: an approach for high-throughput automation. Anal Chem 82:4344–4356CrossRef

38.

Song S, Singh AK, Kirby BJ (2004) Electrophoretic concentration of proteins at laser-patterned nanoporous membranes in microchips. Anal Chem 76:4589–4592CrossRef

39.

Zhu L, Zhang Q, Feng H, Ang S, Chau FS, Liu W-T (2004) Filter-based microfluidic device as a platform for immunofluorescent assay of microbial cells. Lab Chip 4:337–341CrossRef

40.

Van der Bruggen B, Mänttäri M, Nyström M (2008) Drawbacks of applying nanofiltration and how to avoid them: a review. Sep Purif Technol 63:251–263CrossRef

41.

Byrnes SA, Bishop JD, Lafleur L, Buser JR, Lutz B, Yager P (2015) One-step purification and concentration of DNA in porous membranes for point-of-care applications. Lab Chip 15:2647–2659CrossRef

42.

D’Amico L, Ajami NJ, Adachi JA, Gascoyne PRC, Petrosino JF (2017) Isolation and concentration of bacteria from blood using microfluidic membraneless dialysis and dielectrophoresis. Lab Chip 17:1340–1348CrossRef

43.

Walker GM, Beebe DJ (2002) An evaporation-based microfluidic sample concentration method. Lab Chip 2:57–61CrossRef

44.

Wong SY, Cabodi M, Rolland J, Klapperich CM (2014) Evaporative concentration on a paper-based device to concentrate analytes in a biological fluid. Anal Chem 86:11981–11985CrossRef

45.

Choi K, Boyacı E, Kim J, Seale B, Barrera-Arbelaez L, Pawliszyn J, Wheeler AR (2016) A digital microfluidic interface between solid-phase microextraction and liquid chromatography-mass spectrometry. J Chromatogr A 1444:1–7CrossRef

46.

Allen V, Nicol MP, Tow LA (2016) Sputum processing prior to Mycobacterium tuberculosis detection by culture or nucleic acid amplification testing: a narrative review. Res Rev J Microbiol Biotechnol 17(Suppl 1):69

47.

Boehme CC, Nicol MP, Nabeta P, Michael JS, Gotuzzo E, Tahirli R, Gler MT, Blakemore R, Worodria W, Gray C, Huang L, Caceres T, Mehdiyev R, Raymond L, Whitelaw A, Sagadevan K, Alexander H, Albert H, Cobelens F, Cox H, Alland D, Perkins MD (2011) Feasibility, diagnostic accuracy, and effectiveness of decentralised use of the Xpert MTB/RIF test for diagnosis of tuberculosis and multidrug resistance: a multicentre implementation study. Lancet 377:1495–1505CrossRef

48.

Mirzayev F (2012) Current dynamics in the Xpert MTB/RIF assay pricing mechanisms [WWW Document]. http://www.stoptb.org/wg/gli/assets/html/day%202/Mirzayev%20-%20Xpert%20cartridge%20price%20dynamics.pdf. Accessed 27 June 17

49.

Puri L, Oghor C, Denkinger CM, Pai M (2016) Xpert MTB/RIF for tuberculosis testing: access and price in highly privatised health markets. Lancet Glob Health 4:e94–e95CrossRef

50.

Kim J, Johnson M, Hill P, Gale BK (2009) Microfluidic sample preparation: cell lysis and nucleic acid purification. Integr Biol (Camb) 1:574–586CrossRef

51.

Sambrook J, Russel DW (2001) Molecular cloning a LABORATORY MANUAL. Cold Spring Harbor, New York

52.

Heiniger EK, Buser JR, Mireles L, Zhang X, Ladd PD, Lutz BR, Yager P (2016) Comparison of point-of-care-compatible lysis methods for bacteria and viruses. J Microbiol Methods 128:80–87CrossRef

53.

Lee W-C, Lien K-Y, Lee G-B, Lei H-Y (2008) An integrated microfluidic system using magnetic beads for virus detection. Diagn Microbiol Infect Dis 60:51–58CrossRef

54.

Pardee K, Green AA, Takahashi MK, Braff D, Lambert G, Lee JW, Ferrante T, Ma D, Donghia N, Fan M, Daringer NM, Bosch I, Dudley DM, O’Connor DH, Gehrke L, Collins JJ (2016a) Rapid, low-cost detection of zika virus using programmable biomolecular components. Cell 165:1255–1266CrossRef

55.

Waters LC, Jacobson SC, Kroutchinina N, Khandurina J, Foote RS, Ramsey JM (1998) Microchip device for cell lysis, multiplex PCR amplification, and electrophoretic sizing. Anal Chem 70:158–162CrossRef

56.

Gumus A, Ahsan S, Dogan B, Jiang L, Snodgrass R, Gardner A, Lu Z, Simpson K, Erickson D (2016) Solar-thermal complex sample processing for nucleic acid based diagnostics in limited resource settings. Biomed Opt Express 7:1974–1984CrossRef

57.

Bera A, Herbert S, Jakob A, Vollmer W, Götz F (2005) Why are pathogenic staphylococci so lysozyme resistant? The peptidoglycan O-acetyltransferase OatA is the major determinant for lysozyme resistance of Staphylococcus aureus. Mol Microbiol 55:778–787CrossRef

58.

Leonard RB, Carroll KC (1997) Rapid lysis of gram-positive cocci for pulsed-field gel electrophoresis using achromopeptidase. Diagn Mol Pathol 6:288–291CrossRef

59.

Slifkin M, Cumbie R (1987) Serogrouping single colonies of beta-hemolytic streptococci with achromopeptidase extraction. [WWW Document]. http://jcm.asm.org/content/25/8/1555.short. Accessed 7 July 2017

60.

Buser JR, Zhang X, Byrnes SA, Ladd PD, Heiniger EK, Wheeler MD, Bishop JD, Englund JA, Lutz B, Weigl BH, Yager P (2016) A disposable chemical heater and dry enzyme preparation for lysis and extraction of DNA and RNA from microorganisms. Anal Methods 8:2880–2886CrossRef

61.

Hilligoss D, Keller LM, Ramadan S, Coady J, Hellyer TJ (2011) Use of achromopeptidase for lysis at room temperature. WO2011115975 A2

62.

Schilling EA, Kamholz AE, Yager P (2002) Cell Lysis and protein extraction in a microfluidic device with detection by a Fluorogenic enzyme assay. Anal Chem 74:1798–1804CrossRef

63.

Byrnes S, Fan A, Trueb J, Jareczek F, Mazzochette M, Sharon A, Sauer-Budge AF, Klapperich CM (2013) A portable, pressure driven, room temperature nucleic acid extraction and storage system for point of care molecular diagnostics. Anal Methods 5:3177–3184CrossRef

64.

Jangam SR, Agarwal AK, Sur K, Kelso DM (2013) A point-of-care PCR test for HIV-1 detection in resource-limited settings. Biosens Bioelectron 42:69–75CrossRef

65.

Jangam SR, Yamada DH, McFall SM, Kelso DM (2009) Rapid, point-of-care extraction of human immunodeficiency virus type 1 proviral DNA from whole blood for detection by real-time PCR. J Clin Microbiol 47:2363–2368CrossRef

66.

McFall SM, Wagner RL, Jangam SR, Yamada DH, Hardie D, Kelso DM (2015) A simple and rapid DNA extraction method from whole blood for highly sensitive detection and quantitation of HIV-1 proviral DNA by real-time PCR. J Virol Methods 214:37–42CrossRef

67.

Di Carlo D, Jeong K-H, Lee LP (2003) Reagentless mechanical cell lysis by nanoscale barbs in microchannels for sample preparation. Lab Chip 3:287–291CrossRef

68.

Doebler RW, Erwin B, Hickerson A, Irvine B, Woyski D, Nadim A, Sterling JD (2009) Continuous-flow, rapid Lysis devices for biodefense nucleic acid diagnostic systems. J Assoc Lab Autom 14:119–125CrossRef

69.

Gootenberg JS, Abudayyeh OO, Lee JW, Essletzbichler P, Dy AJ, Joung J, Verdine V, Donghia N, Daringer NM, Freije CA, Myhrvold C, Bhattacharyya RP, Livny J, Regev A, Koonin EV, Hung DT, Sabeti PC, Collins JJ, Zhang F (2017) Nucleic acid detection with CRISPR-Cas13a/C2c2. Science 356:438–442CrossRef

70.

ClaremontBio. OmniLyse® Lysis Cartridges|ClaremontBio.com [WWW Document]. URL http://www.claremontbio.com/OmniLyse_Cell_Disruption_Kits_s/27.htm. Accessed 7 July 2017

71.

Belgrader P, Hansford D, Kovacs GT, Venkateswaran K, Mariella R, Milanovich F, Nasarabadi S, Okuzumi M, Pourahmadi F, Northrup MA (1999) A minisonicator to rapidly disrupt bacterial spores for DNA analysis. Anal Chem 71:4232–4236CrossRef

72.

Baier T, Hansen-Hagge TE, Gransee R, Crombé A, Schmahl S, Paulus C, Drese KS, Keegan H, Martin C, O’Leary JJ, Furuberg L, Solli L, Grønn P, Falang IM, Karlgård A, Gulliksen A, Karlsen F (2009) Hands-free sample preparation platform for nucleic acid analysis. Lab Chip 9:3399–3405CrossRef

73.

Govindarajan AV, Ramachandran S, Vigil GD, Yager P, Böhringer KF (2012) A low cost point-of-care viscous sample preparation device for molecular diagnosis in the developing world; an example of microfluidic origami. Lab Chip 12:174–181CrossRef

74.

Hülsheger H, Potel J, Niemann EG (1983) Electric field effects on bacteria and yeast cells. Radiat Environ Biophys 22:149–162CrossRef

75.

Cadossi R, Ronchetti M, Cadossi M (2014) Locally enhanced chemotherapy by electroporation: clinical experiences and perspective of use of electrochemotherapy. Future Oncol Lond Engl 10:877–890CrossRef

76.

Luft C, Ketteler R (2015) Electroporation knows no boundaries: the use of electrostimulation for siRNA delivery in cells and tissues. J Biomol Screen 20:932–942CrossRef

77.

Gao J, Yin X-F, Fang Z-L (2004) Integration of single cell injection, cell lysis, separation and detection of intracellular constituents on a microfluidic chip. Lab Chip 4:47–52CrossRef

78.

Ameri SK, Singh PK, Dokmeci MR, Khademhosseini A, Xu Q, Sonkusale SR (2014) All electronic approach for high-throughput cell trapping and lysis with electrical impedance monitoring. Biosens Bioelectron 54:462–467CrossRef

79.

Lee DW, Cho YH (2007) A continuous electrical cell lysis device using a low dc voltage for a cell transport and rupture - ScienceDirect [WWW Document]. URL http://www.sciencedirect.com/science/article/pii/S0925400506008033. Accessed 7 July 2017

80.

Wang H-Y, Banada PP, Bhunia AK, Lu C (2007) Rapid electrical lysis of bacterial cells in a microfluidic device. Methods Mol Biol 385:23–35CrossRef

81.

Besant JD, Das J, Sargent EH, Kelley SO (2013) Proximal bacterial lysis and detection in nanoliter wells using electrochemistry. ACS Nano 7:8183–8189CrossRef

82.

Lessing J, Glavan AC, Walker SB, Keplinger C, Lewis JA, Whitesides GM (2014) Inkjet printing of conductive inks with high lateral resolution on omniphobic “R(F) paper” for paper-based electronics and MEMS. Adv Mater 26:4677–4682CrossRef

83.

Glavan AC, Christodouleas DC, Mosadegh B, Yu HD, Smith BS, Lessing J, Fernández-Abedul MT, Whitesides GM (2014) Folding analytical devices for electrochemical ELISA in hydrophobic R(H) paper. Anal Chem 86:11999–12007CrossRef

84.

Nie Z, Nijhuis CA, Gong J, Chen X, Kumachev A, Martinez AW, Narovlyansky M, Whitesides GM (2010) Electrochemical sensing in paper-based microfluidic devices. Lab Chip 10:477–483CrossRef

85.

Nguyen TH, Fraiwan A, Choi S (2014) Paper-based batteries: a review. Biosens Bioelectron 54:640–649CrossRef

86.

Cunningham JC, DeGregory PR, Crooks RM (2016) New functionalities for paper-based sensors lead to simplified user operation, lower limits of detection, and new applications. Annu Rev Anal Chem (Palo Alto, Calif) 9:183–202CrossRef

87.

Gaydos C, Hardick J (2014) Point of care diagnostics for sexually transmitted infections: perspectives and advances. Expert Rev Anti-Infect Ther 12:657–672CrossRef

88.

Hu J, Wang S, Wang L, Li F, Pingguan-Murphy B, Lu TJ, Xu F (2014) Advances in paper-based point-of-care diagnostics. Biosens Bioelectron 54:585–597CrossRef

89.

Cate DM, Adkins JA, Mettakoonpitak J, Henry CS (2015) Recent developments in paper-based microfluidic devices. Anal Chem 87:19–41CrossRef

90.

Parolo C, de la Escosura-Muñiz A, Merkoçi A (2013a) Enhanced lateral flow immunoassay using gold nanoparticles loaded with enzymes. Biosens Bioelectron 40:412–416CrossRef

91.

Gerbers R, Foellscher W, Chen H, Anagnostopoulos C, Faghri M (2014) A new paper-based platform technology for point-of-care diagnostics. Lab Chip 14:4042–4049CrossRef

92.

Li J, Baird MA, Davis MA, Tai W, Zweifel LS, Waldorf KMA, Gale M Jr, Rajagopal L, Pierce RH, Gao X (2017) Dramatic enhancement of the detection limits of bioassays via ultrafast deposition of polydopamine. Nat Biomed Eng 1:0082CrossRef

93.

Ramachandran S, Fu E, Lutz B, Yager P (2014) Long-term dry storage of an enzyme-based reagent system for ELISA in point-of-care devices. Analyst 139:1456–1462CrossRef

94.

Pardee K, Slomovic S, Nguyen PQ, Lee JW, Donghia N, Burrill D, Ferrante T, McSorley FR, Furuta Y, Vernet A, Lewandowski M, Boddy CN, Joshi NS, Collins JJ (2016b) Portable, on-demand biomolecular manufacturing. Cell 167:248–259.e12CrossRef

95.

Fu E, Liang T, Houghtaling J, Ramachandran S, Ramsey SA, Lutz B, Yager P (2011) Enhanced sensitivity of lateral flow tests using a two-dimensional paper network format. Anal Chem 83:7941–7946CrossRef

96.

Rohrman BA, Leautaud V, Molyneux E, Richards-Kortum RR (2012) A lateral flow assay for quantitative detection of amplified HIV-1 RNA. PLoS One 7:e45611CrossRef

97.

Yuan L, Hua X, Wu Y, Pan X, Liu S (2011) Polymer-functionalized silica nanosphere labels for ultrasensitive detection of tumor necrosis factor-alpha. Anal Chem 83:6800–6809CrossRef

98.

Nielsen K, Yu WL, Lin M, Davis SAN, Elmgren C, Mackenzie R, Tanha J, Li S, Dubuc G, Brown EG, Keleta L, Pasick J (2007) Prototype single step lateral flow technology for detection of avian influenza virus and chicken antibody to avian influenza virus. J Immunoassay Immunochem 28:307–318CrossRef

99.

Connolly R, O’Kennedy R (2017) Magnetic lateral flow immunoassay test strip development --- considerations for proof of concept evaluation. Methods San Diego Calif 116:132–140CrossRef

100.

Zhao Y, Chen F, Li Q, Wang L, Fan C (2015) Isothermal amplification of nucleic acids. Chem Rev 115:12491–12545CrossRef

101.

Chun P (2009) Colloidal gold and other labels for lateral flow immunoassays. In: Lateral flow immunoassay. Humana Press, New York

102.

Du D, Wang L, Shao Y, Wang J, Engelhard MH, Lin Y (2011) Functionalized graphene oxide as a nanocarrier in a multienzyme labeling amplification strategy for ultrasensitive electrochemical immunoassay of phosphorylated p53 (S392). Anal Chem 83:746–752CrossRef

103.

Koczula KM, Gallotta A (2016) Lateral flow assays. Essays Biochem 60:111–120CrossRef

104.

Wilson R (2008) The use of gold nanoparticles in diagnostics and detection. Chem Soc Rev 37:2028–2045CrossRef

105.

Quesada-González D, Merkoçi A (2015) Nanoparticle-based lateral flow biosensors. Biosens Bioelectron 73:47–63CrossRef

106.

Ge X, Asiri AM, Du D, Wen W, Wang S, Lin Y (2014) Nanomaterial-enhanced paper-based biosensors. TrAC, Trends in Anal Chem 58:31–39CrossRef

107.

Fu E, Liang T, Spicar-Mihalic P, Houghtaling J, Ramachandran S, Yager P (2012a) Two-dimensional paper network format that enables simple multistep assays for use in low-resource settings in the context of malaria antigen detection. Anal Chem 84:4574–4579CrossRef

108.

Parolo C, Medina-Sánchez M, de la Escosura-Muñiz A, Merkoçi A (2013b) Simple paper architecture modifications lead to enhanced sensitivity in nanoparticle based lateral flow immunoassays. Lab Chip 13:386–390CrossRef

109.

Zhang C, Zhang Y, Wang S (2006) Development of multianalyte flow-through and lateral-flow assays using gold particles and horseradish peroxidase as tracers for the rapid determination of carbaryl and endosulfan in agricultural products. J Agric Food Chem 54:2502–2507CrossRef

110.

Danscher G, Nørgaard JO, Baatrup E (1987) Autometallography: tissue metals demonstrated by a silver enhancement kit. Histochemistry 86:465–469CrossRef

111.

Scopsi L, Larsson LI, Bastholm L, Nielsen MH (1986) Silver-enhanced colloidal gold probes as markers for scanning electron microscopy. Histochemistry 86:35–41CrossRef

112.

Cho I-H, Seo S-M, Paek E-H, Paek S-H (2010) Immunogold-silver staining-on-a-chip biosensor based on cross-flow chromatography. J Chromatogr B Analyt Technol Biomed Life Sci 878:271–277CrossRef

113.

Horton JK, Swinburne S, O’Sullivan MJ (1991) A novel, rapid, single-step immunochromatographic procedure for the detection of mouse immunoglobulin. J Immunol Methods 140:131–134CrossRef

114.

Smit PW, Elliott I, Peeling RW, Mabey D, Newton PN (2014) An overview of the clinical use of filter paper in the diagnosis of tropical diseases. Am J Trop Med Hyg 90:195–210CrossRef

115.

Ghani AC, Burgess DH, Reynolds A, Rousseau C (2015) Expanding the role of diagnostic and prognostic tools for infectious diseases in resource-poor settings. Nature 528(7580):S50-S502

116.

Curtis KA, Rudolph DL, Nejad I, Singleton J, Beddoe A, Weigl B, LaBarre P, Owen SM (2012) Isothermal amplification using a chemical heating device for point-of-care detection of HIV-1. PLoS One 7:e31432CrossRef

117.

Yan L, Zhou J, Zheng Y, Gamson AS, Roembke BT, Nakayama S, Sintim HO (2014) Isothermal amplified detection of DNA and RNA. Mol BioSyst 10:970–1003CrossRef

118.

Gan W, Zhuang B, Zhang P, Han J, Li C-X, Liu P (2014) A filter paper-based microdevice for low-cost, rapid, and automated DNA extraction and amplification from diverse sample types. Lab Chip 14:3719–3728CrossRef

119.

Linnes JC, Fan A, Rodriguez NM, Lemieux B, Kong H, Klapperich CM (2014) Paper-based molecular diagnostic for chlamydia trachomatis. RSC Adv 4:42245–42251CrossRef

120.

Craw P, Balachandran W (2012) Isothermal nucleic acid amplification technologies for point-of-care diagnostics: a critical review. Lab Chip 12:2469–2486CrossRef

121.

Compton J (1991) Nucleic acid sequence-based amplification. Nature 350:91–92CrossRef

122.

Houde A, Leblanc D, Poitras E, Ward P, Brassard J, Simard C, Trottier Y-L (2006) Comparative evaluation of RT-PCR, nucleic acid sequence-based amplification (NASBA) and real-time RT-PCR for detection of noroviruses in faecal material. J Virol Methods 135:163–172CrossRef

123.

Liu C, Geva E, Mauk M, Qiu X, Abrams WR, Malamud D, Curtis K, Owen SM, Bau HH (2011) An isothermal amplification reactor with an integrated isolation membrane for point-of-care detection of infectious diseases. Analyst 136:2069–2076CrossRef

124.

Rodriguez NM, Linnes JC, Fan A, Ellenson CK, Pollock NR, Klapperich CM (2015) Paper-based rna extraction, in situ isothermal amplification, and lateral flow detection for low-cost, rapid diagnosis of influenza a (H1N1) from clinical specimens. Anal Chem 87:7872–7879CrossRef

125.

Vincent M, Xu Y, Kong H (2004) Helicase-dependent isothermal DNA amplification. EMBO Rep 5:795–800CrossRef

126.

Piepenburg O, Williams CH, Stemple DL, Armes NA (2006) DNA detection using recombination proteins. PLoS Biol 4:e204CrossRef

127.

Mondal D, Ghosh P, Khan MAA, Hossain F, Böhlken-Fascher S, Matlashewski G, Kroeger A, Olliaro P, Abd El Wahed A (2016) Mobile suitcase laboratory for rapid detection of Leishmania donovani using recombinase polymerase amplification assay. Parasit Vectors 9:281CrossRef

128.

Renner LD, Zan J, Hu LI, Martinez M, Resto PJ, Siegel AC, Torres C, Hall SB, Slezak TR, Nguyen TH, Weibel DB (2017) Detection of ESKAPE bacterial pathogens at the point of care using isothermal DNA-based assays in a portable degas-actuated microfluidic diagnostic assay platform. Appl Environ Microbiol 83:e02449–e02416CrossRef

129.

Teoh B-T, Sam S-S, Tan K-K, Danlami MB, Shu M-H, Johari J, Hooi P-S, Brooks D, Piepenburg O, Nentwich O, Wilder-Smith A, Franco L, Tenorio A, AbuBakar S (2015) Early detection of dengue virus by use of reverse transcription-recombinase polymerase amplification. J Clin Microbiol 53:830–837CrossRef

130.

Daher RK, Stewart G, Boissinot M, Bergeron MG (2016) Recombinase polymerase amplification for diagnostic applications. Clin Chem 62:947–958CrossRef

131.

Cordray MS, Richards-Kortum RR (2012) Emerging nucleic acid-based tests for point-of-care detection of malaria. Am J Trop Med Hyg 87:223–230CrossRef

132.

Green AA, Silver PA, Collins JJ, Yin P (2014) Toehold switches: de-novo-designed regulators of gene expression. Cell 159:925–939CrossRef

133.

Pardee K, Green AA, Ferrante T, Cameron DE, DaleyKeyser A, Yin P, Collins JJ (2014) Paper-based synthetic gene networks. Cell 159:940–954CrossRef

134.

van der Meer JR, Belkin S (2010) Where microbiology meets microengineering: design and applications of reporter bacteria. Nat Rev Microbiol 8:511–522CrossRef

135.

Slomovic S, Pardee K, Collins JJ (2015) Synthetic biology devices for in vitro and in vivo diagnostics. Proc Natl Acad Sci U S A 112:14429–14435CrossRef

136.

Ostrov N, Jimenez M, Billerbeck S, Brisbois J, Matragrano J, Ager A, Cornish VW (2017) A modular yeast biosensor for low-cost point-of-care pathogen detection. Sci Adv 3:e1603221CrossRef

137.

IEA (2016) World Energy Outlook. https://www.iea.org/weo/newsroom/news/2016/november/world-energy-outlook-2016.html

138.

IEA (2014) Africa Energy Outlook, a focus on energy prospects in sub-saharan Africa [WWW Document]. URL https://www.iea.org/publications/freepublications/. Accessed 7 June 2017

139.

GMSA Intelligence (2017) GMSA Intelligence accesses June 2017 at https://www.gsmaintelligence.com

140.

Ventures Africa (2015) 60% OF THE WORLD’S POPULATION WILL OWN A MOBILE PHONE BY 2020 accessed June 2017. http://venturesafrica.com/60-of-the-worlds-population-will-own-a-mobile-phone-by-2020/

141.

World Bank (2017) Rapid Urbanization in Africa: Investing in the Development of Africa’s Cities [WWW Document]. World Bank. http://www.worldbank.org/en/news/feature/2017/05/02/rapid-urbanization-in-africa-investing-in-the-development-of-africas-cities. Accessed 7 June 2017

142.

Lafleur LK, Bishop JD, Heiniger EK, Gallagher RP, Wheeler MD, Kauffman P, Zhang X, Kline EC, Buser JR, Kumar S, Byrnes SA, Vermeulen NMJ, Scarr NK, Belousov Y, Mahoney W, Toley BJ, Ladd PD, Lutz BR, Yager P (2016) A rapid, instrument-free, sample-to-result nucleic acid amplification test. Lab Chip 16:3777–3787CrossRef

143.

Yager P, Domingo GJ, Gerdes J (2008) Point-of-care diagnostics for global health. Annu Rev Biomed Eng 10:107–144CrossRef

144.

Martinez AW, Phillips ST, Whitesides GM (2008) Three-dimensional microfluidic devices fabricated in layered paper and tape. Proc Natl Acad Sci U S A 105:19606–19611CrossRef

145.

Wang C-C, Hennek JW, Ainla A, Kumar AA, Lan W-J, Im J, Smith BS, Zhao M, Whitesides GM (2016) A paper-based “pop-up” electrochemical device for analysis of beta-hydroxybutyrate. Anal Chem 88:6326–6333CrossRef

146.

Zhou G, Mao X, Juncker D (2012) Immunochromatographic assay on thread. Anal Chem 84:7736–7743CrossRef

147.

Choi K, Ng AHC, Fobel R, Wheeler AR (2012) Digital microfluidics. Annu Rev Anal Chem (Palo Alto, Calif) 5:413–440CrossRef

148.

Srinivasan V, Pamula VK, Fair RB (2004) An integrated digital microfluidic lab-on-a-chip for clinical diagnostics on human physiological fluids. Lab Chip 4:310–315CrossRef

149.

Mousa NA, Jebrail MJ, Yang H, Abdelgawad M, Metalnikov P, Chen J, Wheeler AR, Casper RF (2009) Droplet-scale estrogen assays in breast tissue, blood, and serum. Sci Transl Med 1:1ra2CrossRef

150.

Ng AHC, Lee M, Choi K, Fischer AT, Robinson JM, Wheeler AR (2015) Digital microfluidic platform for the detection of rubella infection and immunity: a proof of concept. Clin Chem 61:420–429CrossRef

151.

Fobel R, Kirby AE, Ng AHC, Farnood RR, Wheeler AR (2014) Paper microfluidics goes digital. Adv Mater 26:2838–2843CrossRef

152.

Dixon C, Ng AHC, Fobel R, Miltenburg MB, Wheeler AR (2016) An inkjet printed, roll-coated digital microfluidic device for inexpensive, miniaturized diagnostic assays. Lab Chip 16:4560–4568CrossRef

153.

Fobel R, Fobel C, Wheeler AR (2013) DropBot: an open-source digital microfluidic control system with precise control of electrostatic driving force and instantaneous drop velocity measurement. Appl Phys Lett 102:193513CrossRef

154.

Güder F, Ainla A, Redston J, Mosadegh B, Glavan A, Martin TJ, Whitesides GM (2016) Paper-based electrical respiration sensor. Angew Chem Int Ed Engl 55:5727–5732CrossRef

155.

Conrad CC, Hilchey KG (2011) A review of citizen science and community-based environmental monitoring: issues and opportunities. Environ Monit Assess 176:273–291CrossRef

156.

Hamedi MM, Campbell VE, Rothemund P, Güder F, Christodouleas DC, Bloch J-F, Whitesides GM (2016) Electrically activated paper actuators. Adv Funct Mater 26:2446–2453CrossRef

157.

Safavieh R, Juncker D (2013) Capillarics: pre-programmed, self-powered microfluidic circuits built from capillary elements. Lab Chip 13:4180–4189CrossRef

158.

Jenum S, Dhanasekaran S, Lodha R, Mukherjee A, Saini DK, Singh S, Singh V, Medigeshi G, Haks MC, Ottenhoff THM, Doherty TM, Kabra SK, Ritz C, Grewal HMS (2016) Approaching a diagnostic point-of-care test for pediatric tuberculosis through evaluation of immune biomarkers across the clinical disease spectrum. Sci Rep 6:18520CrossRef

Titel: The Many Roads to an Ideal Paper-based Device
verfasst von: Margot Karlikow
Keith Pardee
Verlag: Springer International Publishing
Buch: Paper-based Diagnostics
Print ISBN: 978-3-319-96868-1

Electronic ISBN: 978-3-319-96870-4

Copyright-Jahr: 2019
DOI: https://doi.org/10.1007/978-3-319-96870-4_6

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht