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2019 | OriginalPaper | Buchkapitel

Recent Advances in Paper-Based Analytical Devices: A Pivotal Step Forward in Building Next-Generation Sensor Technology

verfasst von : Charu Agarwal, Levente Csóka

Erschienen in: Sustainable Polymer Composites and Nanocomposites

Verlag: Springer International Publishing

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Abstract

Of late, the paper has attracted the significant attention of researchers as a substrate for sensing devices. Paper is a fibrous network of cellulose, a ubiquitous biopolymer, which is fast emerging as a sustainable raw material and replacing the non-renewable ones. Paper possesses many striking features such as hydrophilicity and low-cost, which make it an excellent choice for sensing platforms. Paper-based sensing devices are flexible, foldable, portable, economical, user-friendly and disposable. Recently, numerous works have reported the use of paper substrates for sensor fabrication in the fields of biomedical health care, environmental analysis, food and water quality, and forensics. The current chapter aims to present a concise overview of the recent developments in the area of paper-based sensing, particularly in the ongoing decade. It briefly discusses the sensing approach for the detection of various analytes and focuses on their applications in various sectors.

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Vorheriges Kapitel Processing and Industrial Applications of Sustainable Nanocomposites Containing Nanofillers

Nächstes Kapitel Polymers and Polymer Composites for Adsorptive Removal of Dyes in Water Treatment

Nayak S, Blumenfeld NR, Laksanasopin T, Sia SK (2017) Point-of-care diagnostics: recent developments in a connected age. Anal Chem 89:102–123CrossRef

Gong MM, Sinton D (2017) Turning the page: advancing paper-based microfluidics for broad diagnostic application. Chem Rev 117:8447–8480CrossRef

Sher M, Zhuang R, Demirci U, Asghar W (2017) Paper-based analytical devices for clinical diagnosis: recent advances in the fabrication techniques and sensing mechanisms. Expert Rev Mol Diagn 17:351–366CrossRef

Zarei M (2017) Portable biosensing devices for point-of-care diagnostics: recent developments and applications. Trends Anal Chem 91:26–41CrossRef

Martinez AW (2011) Microfluidic paper-based analytical devices: from POCKET to paper-based ELISA. Bioanalysis 3:2589–2592CrossRef

Martinez AW, Phillips ST, Whitesides GM, Carrilho E (2010) Diagnostics for the developing world: Microfluidic paper-based analytical devices. Anal Chem 82:3–10CrossRef

Morbioli GG, Mazzu-Nascimento T, Stockton AM, Carrilho E (2017) Technical aspects and challenges of colorimetric detection with microfluidic paper-based analytical devices (mPADs)—a review. Anal Chim Acta 970:1–22CrossRef

Tseng SC et al (2012) Eco-friendly plasmonic sensors: using the photothermal effect to prepare metal nanoparticle-containing test papers for highly sensitive colorimetric detection. Anal Chem 84:5140–5145CrossRef

Tao H et al (2011) Metamaterials on paper as a sensing platform. Adv Mater 23:3197–3201CrossRef

10.

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

11.

Parolo C, Merkoci A (2013) Paper-based nanobiosensors for diagnostics. Chem Soc Rev 42:450–457CrossRef

12.

Ge S, Zhang L, Zhang Y, Lan F, Yan M, Yu J (2017) Nanomaterials-modified cellulose paper as a platform for biosensing applications. Nanoscale 9:4366–4382CrossRef

13.

Alvarez-Diduk R, Orozco J, Merkoci A (2017) Paper strip-embedded graphene quantum dots: a screening device with a smartphone readout. Sci Rep 7:976–984CrossRef

14.

Carrasquilla C, Little JR, Li Y, Brennan JD (2015) Patterned paper sensors printed with long-chain DNA aptamers. Chemistry 21:7369–7373CrossRef

15.

Rat S et al (2016) Elastic coupling between spin-crossover particles and cellulose fibers. Chem Commun 52:11267–11269CrossRef

16.

Lim WY, Goh BT, Khor SM (2017) Microfluidic paper-based analytical devices for potential use in quantitative and direct detection of disease biomarkers in clinical analysis. J Chromatogr B 1060:424–442CrossRef

17.

Mahato K, Srivastava A, Chandra P (2017) Paper based diagnostics for personalized health care: emerging technologies and commercial aspects. Biosens Bioelectron 96:246–259CrossRef

18.

Wang S, Chinnasamy T, Lifson MA, Inci F, Demirci U (2016) Flexible substrate-based devices for point-of-care diagnostics. Trends Biotechnol 34:909–921CrossRef

19.

Meredith NA, Quinn C, Cate DM, Reilly TH 3rd, Volckens J, Henry CS (2016) Paper-based analytical devices for environmental analysis. Analyst 141:1874–1887CrossRef

20.

Bulbul G, Hayat A, Andreescu S (2015) Portable nanoparticle-based sensors for food safety assessment. Sensors 15:30736–30758CrossRef

21.

Hua M, Li S, Wang S, Lu X (2018) Detecting chemical hazards in foods using microfluidic paper-based analytical devices (μPADs): The real-world application. Micromachines 9:32–45CrossRef

22.

Ansari N, Lodha A, Pandya A, Menon SK (2017) Determination of cause of death using paper-based microfluidic device as a colorimetric probe. Anal Methods 9:5632–5639CrossRef

23.

Song Y, Gyarmati P, Araujo AC, Lundeberg J, Brumer H 3rd, Stahl PL (2014) Visual detection of DNA on paper chips. Anal Chem 86:1575–1582CrossRef

24.

Ge S, Zhang L, Zhang Y, Liu H, Huang J, Yan M, Yu J (2015) Electrochemical K-562 cells sensor based on origami paper device for point-of-care testing. Talanta 145:12–19CrossRef

25.

Nilghaz A, Guan L, Tan W, Shen W (2016) Advances of paper-based microfluidics for diagnostics—the original motivation and current status. ACS Sens 1:1382–1393CrossRef

26.

Yamada K, Shibata H, Suzuki K, Citterio D (2017) Toward practical application of paper-based microfluidics for medical diagnostics: state-of-the-art and challenges. Lab Chip 17:1206–1249CrossRef

27.

Tao X, Jia H, He Y, Liao S, Wang Y (2017) Ultrafast paper thermometers based on a green sensing ink. ACS Sens 2:449–454CrossRef

28.

Yang J, Kwak TJ, Zhang X, McClain R, Chang WJ, Gunasekaran S (2016) Iridium oxide-reduced graphene oxide nanohybrid thin film modified screen-printed electrodes as disposable electrochemical paper microfluidic pH sensors. J Vis Exp 117:e53339–e53345

29.

Balde M, Vena A, Sorli B (2015) Fabrication of porous anodic aluminium oxide layers on paper for humidity sensors. Sens Actuators B Chem 220:829–839CrossRef

30.

Yuan Y, Zhang Y, Liu R, Liu J, Li Z, Liu X (2016) Humidity sensor fabricated by inkjet-printing photosensitive conductive inks PEDOT:PVMA on a paper substrate. RSC Adv 6:47498–47508CrossRef

31.

Koren K, Kühl M (2015) A simple laminated paper-based sensor for temperature sensing and imaging. Sens Actuators B Chem 210:124–128CrossRef

32.

Nagy V et al (2014) Cellulose fiber nanocomposites displaying spin-crossover properties. Colloids Surf A Physicochem Eng Asp 456:35–40CrossRef

33.

Nagy V, Suleimanov I, Molnár G, Salmon L, Bousseksou A, Csóka L (2015) Cellulose–spin crossover particle composite papers with reverse printing performance: a proof of concept. J Mater Chem C 3:7897–7905CrossRef

34.

Zhao H, Zhang T, Qi R, Dai J, Liu S, Fei T (2017) Drawn on paper: a reproducible humidity sensitive device by handwriting. ACS Appl Mater Interfaces 9:28002–28009CrossRef

35.

Lopez-Ruiz N, Curto VF, Erenas MM, Benito-Lopez F, Diamond D, Palma AJ, Capitan-Vallvey LF (2014) Smartphone-based simultaneous pH and nitrite colorimetric determination for paper microfluidic devices. Anal Chem 86:9554–9562CrossRef

36.

Lee C-Y, Lei KF, Tsai S-W, Tsang N-M (2016) Development of graphene-based sensors on paper substrate for the measurement of pH value of analyte. BioChip J 10:182–188CrossRef

37.

Liu X, Mwangi M, Li X, O’Brien M, Whitesides GM (2011) Paper-based piezoresistive MEMS sensors. Lab Chip 11:2189–2196CrossRef

38.

Lee J, Lee YJ, Ahn YJ, Choi S, Lee G-J (2018) A simple and facile paper-based colorimetric assay for detection of free hydrogen sulfide in prostate cancer cells. Sens Actuators B Chem 256:828–834CrossRef

39.

Silva TG, de Araujo WR, Munoz RA, Richter EM, Santana MH, Coltro WK, Paixao TR (2016) Simple and sensitive paper-based device coupling electrochemical sample pretreatment and colorimetric detection. Anal Chem 88:5145–5151CrossRef

40.

Cha R, Wang D, He Z, Ni Y (2012) Development of cellulose paper testing strips for quick measurement of glucose using chromogen agent. Carbohydr Polym 88:1414–1419CrossRef

41.

Yamada K, Suzuki K, Citterio D (2017) Text-displaying colorimetric paper-based analytical device. ACS Sens 2:1247–1254CrossRef

42.

Chen X, Chen J, Wang F, Xiang X, Luo M, Ji X, He Z (2012) Determination of glucose and uric acid with bienzyme colorimetry on microfluidic paper-based analysis devices. Biosens Bioelectron 35:363–368CrossRef

43.

Chan SK, Lim TS (2016) A straw-housed paper-based colorimetric antibody–antigen sensor. Anal Methods 8:1431–1436CrossRef

44.

Costa MN et al (2014) A low cost, safe, disposable, rapid and self-sustainable paper-based platform for diagnostic testing: lab-on-paper. Nanotechnology 25:094006–094017CrossRef

45.

Tian T et al (2016) Integration of target responsive hydrogel with cascaded enzymatic reactions and microfluidic paper-based analytic devices (mPADs) for point-of-care testing (POCT). Biosens Bioelectron 77:537–542CrossRef

46.

Wei X et al (2016) Microfluidic distance readout sweet hydrogel integrated paper-based analytical device (µDiSH-PAD) for visual quantitative point-of-care testing. Anal Chem 88:2345–2352CrossRef

47.

Wei X et al (2015) Target-responsive DNA hydrogel mediated “stop-flow” microfluidic paper-based analytic device for rapid, portable and visual detection of multiple targets. Anal Chem 87:4275–4282CrossRef

48.

Zhang Y et al (2016) Naked-eye quantitative aptamer-based assay on paper device. Biosens Bioelectron 78:538–546CrossRef

49.

Santhiago M, Kubota LT (2013) A new approach for paper-based analytical devices with electrochemical detection based on graphite pencil electrodes. Sens Actuators B Chem 177:224–230CrossRef

50.

Yao Y, Zhang C (2016) A novel screen-printed microfluidic paper-based electrochemical device for detection of glucose and uric acid in urine. Biomed Microdevices 18:92–100CrossRef

51.

Narang J et al (2017) Lab on paper chip integrated with Si@GNRs for electroanalysis of diazepam. Anal Chim Acta 980:50–57CrossRef

52.

Narang J, Malhotra N, Singhal C, Mathur A, Chakraborty D, Ingle A, Pundir CS (2017) Point of care with micro fluidic paper based device incorporated with nanocrys of Zeolite–GO for electrochemical sensing of date rape drug. Proc Technol 27:91–93CrossRef

53.

Wang P, Ge L, Yan M, Song X, Ge S, Yu J (2012) Paper-based three-dimensional electrochemical immunodevice based on multi-walled carbon nanotubes functionalized paper for sensitive point-of-care testing. Biosens Bioelectron 32:238–243CrossRef

54.

Teengam P, Siangproh W, Tuantranont A, Henry CS, Vilaivan T, Chailapakul O (2017) Electrochemical paper-based peptide nucleic acid biosensor for detecting human papillomavirus. Anal Chim Acta 952:32–40CrossRef

55.

Wang Y et al (2016) A novel label-free microfluidic paper-based immunosensor for highly sensitive electrochemical detection of carcinoembryonic antigen. Biosens Bioelectron 83:319–326CrossRef

56.

Kumar S et al (2015) Reduced graphene oxide modified smart conducting paper for cancer biosensor. Biosens Bioelectron 73:114–122CrossRef

57.

Scida K, Cunningham JC, Renault C, Richards I, Crooks RM (2014) Simple, sensitive, and quantitative electrochemical detection method for paper analytical devices. Anal Chem 86:6501–6507CrossRef

58.

Wang CC et al (2016) A paper-based “pop-up” electrochemical device for analysis of beta-hydroxybutyrate. Anal Chem 88:6326–6333CrossRef

59.

Jagadeesan KK, Kumar S, Sumana G (2012) Application of conducting paper for selective detection of troponin. Electrochem Commun 20:71–74CrossRef

60.

Yang M et al (2016) Flexible and disposable sensing platforms based on newspaper. ACS Appl Mater Interfaces 8:34978–34984CrossRef

61.

Cunningham JC, Brenes NJ, Crooks RM (2014) Paper electrochemical device for detection of DNA and thrombin by target-induced conformational switching. Anal Chem 86:6166–6170CrossRef

62.

Mirasoli M, Guardigli M, Michelini E, Roda A (2014) Recent advancements in chemical luminescence-based lab-on-chip and microfluidic platforms for bioanalysis. J Pharm Biomed Anal 87:36–52CrossRef

63.

Liu W, Luo J, Guo Y, Kou J, Li B, Zhang Z (2014) Nanoparticle coated paper-based chemiluminescence device for the determination of L-cysteine. Talanta 120:336–341CrossRef

64.

Liu F, Zhang C (2015) A novel paper-based microfluidic enhanced chemiluminescence biosensor for facile, reliable and highly-sensitive gene detection of Listeria monocytogenes. Sens Actuators B Chem 209:399–406CrossRef

65.

Zhao M, Li H, Liu W, Guo Y, Chu W (2016) Plasma treatment of paper for protein immobilization on paper-based chemiluminescence immunodevice. Biosens Bioelectron 79:581–588CrossRef

66.

Liu W, Cassano CL, Xu X, Fan ZH (2013) Laminated paper-based analytical devices (LPAD) with origami-enabled chemiluminescence immunoassay for cotinine detection in mouse serum. Anal Chem 85:10270–10276CrossRef

67.

Chen Y, Wang J, Liu Z, Wang X, Li X, Shan G (2018) A simple and versatile paper-based electrochemiluminescence biosensing platform for hepatitis B virus surface antigen detection. Biochem Eng J 129:1–6CrossRef

68.

Ge L, Yan J, Song X, Yan M, Ge S, Yu J (2012) Three-dimensional paper-based electrochemiluminescence immunodevice for multiplexed measurement of biomarkers and point-of-care testing. Biomaterials 33:1024–1031CrossRef

69.

Ge S, Liang L, Lan F, Zhang Y, Wang Y, Yan M, Yu J (2016) Photoelectrochemical immunoassay based on chemiluminescence as internal excited light source. Sens Actuators B Chem 234:324–331CrossRef

70.

Shi L, Li L, Li X, Zhang G, Zhang Y, Dong C, Shuang S (2017) Excitation-independent yellow-fluorescent nitrogen-doped carbon nanodots for biological imaging and paper-based sensing. Sens Actuators B Chem 251:234–241CrossRef

71.

Cai Y, You J, You Z, Dong F, Du S, Zhang L (2018) Profuse color-evolution-based fluorescent test paper sensor for rapid and visual monitoring of endogenous Cu²⁺ in human urine. Biosens Bioelectron 99:332–337CrossRef

72.

Samanta S, Halder S, Dey P, Manna U, Ramesh A, Das G (2018) A ratiometric fluorogenic probe for the real-time detection of SO₃²⁻ in aqueous medium: Application in a cellulose paper based device and potential to sense SO₃²⁻ in mitochondria. Analyst 143:250–257CrossRef

73.

Thom NK, Lewis GG, Yeung K, Phillips ST (2014) Quantitative fluorescence assays using a self-powered paper-based microfluidic device and a camera-equipped cellular phone. RSC Adv 4:1334–1340CrossRef

74.

Mei Q, Zhang Z (2012) Photoluminescent graphene oxide ink to print sensors onto microporous membranes for versatile visualization bioassays. Angew Chem Int Ed 51:5602–5606CrossRef

75.

Derikvand F, Yin DT, Barrett R, Brumer H (2016) Cellulose-based biosensors for esterase detection. Anal Chem 88:2989–2993CrossRef

76.

Li B, Zhou X, Liu H, Deng H, Huang R, Xing D (2018a) Simultaneous detection of antibiotic resistance genes on paper-based chip using [Ru(phen)₂dppz]²⁺ turn-on fluorescence probe. ACS Appl Mater Interfaces. https://doi.org/10.1021/acsami.7b17653

77.

Rosa AM, Louro AF, Martins SA, Inacio J, Azevedo AM, Prazeres DM (2014) Capture and detection of DNA hybrids on paper via the anchoring of antibodies with fusions of carbohydrate binding modules and ZZ-domains. Anal Chem 86:4340–4347CrossRef

78.

Wang Y, Wang S, Ge S, Wang S, Yan M, Zang D, Yu J (2013) Facile and sensitive paper-based chemiluminescence DNA biosensor using carbon dots dotted nanoporous gold signal amplification label. Anal Methods 5:1328–1336CrossRef

79.

Zhou F, Noor MO, Krull UJ (2014) Luminescence resonance energy transfer-based nucleic acid hybridization assay on cellulose paper with upconverting phosphor as donors. Anal Chem 86:2719–2726CrossRef

80.

Oliveira MJ et al (2017) Office paper decorated with silver nanostars—an alternative cost effective platform for trace analyte detection by SERS. Sci Rep 7:2480–2493CrossRef

81.

Hu SW, Qiao S, Pan JB, Kang B, Xu JJ, Chen HY (2018) A paper-based SERS test strip for quantitative detection of Mucin-1 in whole blood. Talanta 179:9–14CrossRef

82.

Abbas A, Brimer A, Slocik JM, Tian L, Naik RR, Singamaneni S (2013) Multifunctional analytical platform on a paper strip: separation, preconcentration, and subattomolar detection. Anal Chem 85:3977–3983CrossRef

83.

Banaei N, Foley A, Houghton JM, Sun Y, Kim B (2017) Multiplex detection of pancreatic cancer biomarkers using a SERS-based immunoassay. Nanotechnology 28:455101–455111CrossRef

84.

Kim W-S, Shin J-H, Park H-K, Choi S (2016) A low-cost, monometallic, surface-enhanced Raman scattering-functionalized paper platform for spot-on bioassays. Sens Actuators B Chem 222:1112–1118CrossRef

85.

Liu Q et al (2014) Paper-based plasmonic platform for sensitive, noninvasive, and rapid cancer screening. Biosens Bioelectron 54:128–134CrossRef

86.

Ngo YH, Li D, Simon GP, Garnier G (2012) Gold nanoparticle-paper as a three-dimensional surface enhanced Raman scattering substrate. Langmuir 28:8782–8790CrossRef

87.

Tadepalli S et al (2015) Peptide functionalized gold nanorods for the sensitive detection of a cardiac biomarker using plasmonic paper devices. Sci Rep 5:16206–16216CrossRef

88.

Noor MO, Krull UJ (2014) Camera-based ratiometric fluorescence transduction of nucleic acid hybridization with reagentless signal amplification on a paper-based platform using immobilized quantum dots as donors. Anal Chem 86:10331–10339CrossRef

89.

Liu X, Yang Y, Li Q, Wang Z, Xing X, Wang Y (2018c) Portably colorimetric paper sensor based on ZnS quantum dots for semi-quantitative detection of Co²⁺ through the measurement of grey level. Sens Actuators B Chem. https://doi.org/10.1016/j.snb.2018.01.121

90.

Dhavamani J, Mujawar LH, El-Shahawi MS (2018) Hand drawn paper-based optical assay plate for rapid and trace level determination of Ag⁺ in water. Sens Actuators B Chem 258:321–330CrossRef

91.

Yakoh A, Rattanarat P, Siangproh W, Chailapakul O (2018) Simple and selective paper-based colorimetric sensor for determination of chloride ion in environmental samples using label-free silver nanoprisms. Talanta 178:134–140CrossRef

92.

Chaiyo S, Siangproh W, Apilux A, Chailapakul O (2015) Highly selective and sensitive paper-based colorimetric sensor using thiosulfate catalytic etching of silver nanoplates for trace determination of copper ions. Anal Chim Acta 866:75–83CrossRef

93.

Hossain SM, Brennan JD (2011) b-Galactosidase-based colorimetric paper sensor for determination of heavy metals. Anal Chem 83:8772–8778CrossRef

94.

Giokas DL, Tsogas GZ, Vlessidis AG (2014) Programming fluid transport in paper-based microfluidic devices using razor-crafted open channels. Anal Chem 86:6202–6207CrossRef

95.

Kappi FA, Tsogas GZ, Christodouleas DC, Giokas DL (2017) Calibrant-loaded paper-based analytical devices for standard addition quantitative assays. Sens Actuators B Chem 253:860–867CrossRef

96.

Cuartero M, Crespo GA, Bakker E (2015) Paper-based thin-layer coulometric sensor for halide determination. Anal Chem 87:1981–1990CrossRef

97.

Ruecha N, Chailapakul O, Suzuki K, Citterio D (2017) Fully inkjet-printed paper-based potentiometric ion-sensing devices. Anal Chem 89:10608–10616CrossRef

98.

Yoon JH et al (2017) Fabrication of newspaper-based potentiometric platforms for flexible and disposable ion sensors. J Colloid Interface Sci 508:167–173CrossRef

99.

Zor E, Alpaydin S, Arici A, Saglam ME, Bingol H (2018) Photoluminescent nanopaper-based microcuvette for iodide detection in seawater. Sens Actuators B Chem 254:1216–1224CrossRef

100.

Chen PC, Li YC, Ma JY, Huang JY, Chen CF, Chang HT (2016) Size-tunable copper nanocluster aggregates and their application in hydrogen sulfide sensing on paper-based devices. Sci Rep 6:24882–24890CrossRef

101.

Zhang M, Ge L, Ge S, Yan M, Yu J, Huang J, Liu S (2013) Three-dimensional paper-based electrochemiluminescence device for simultaneous detection of Pb²⁺ and Hg²⁺ based on potential-control technique. Biosens Bioelectron 41:544–550CrossRef

102.

Prabphal J, Vilaivan T, Praneenararat T (2018) Fabrication of a paper-based turn-off fluorescence sensor for Cu²⁺ ion from a pyridinium porphyrin. ChemistrySelect 3:894–899CrossRef

103.

Sun T, Niu Q, Li Y, Li T, Hu T, Wang E, Liu H (2018) A novel oligothiophene-based colorimetric and fluorescent “turn on” sensor for highly selective and sensitive detection of cyanide in aqueous media and its practical applications in water and food samples. Sens Actuators B Chem 258:64–71CrossRef

104.

Li B, Zhang Z, Qi J, Zhou N, Qin S, Choo J, Chen L (2017) Quantum dot-based molecularly imprinted polymers on three-dimensional origami paper microfluidic chip for fluorescence detection of phycocyanin. ACS Sens 2:243–250CrossRef

105.

Zhao H, Zang L, Wang L, Qin F, Zhang Z, Cao W (2015) Luminescence ratiometric oxygen sensor based on gadolinium labeled porphyrin and filter paper. Sens Actuators B Chem 215:405–411CrossRef

106.

Kim Y, Jang G, Lee TS (2015) New fluorescent metal-ion detection using a paper-based sensor strip containing tethered rhodamine carbon nanodots. ACS Appl Mater Interfaces 7:15649–15657CrossRef

107.

Lee M, Oh K, Choi HK, Lee SG, Youn HJ, Lee HL, Jeong DH (2018) Subnanomolar sensitivity of filter paper-based SERS sensor for pesticide detection by hydrophobicity change of paper surface. ACS Sens 3:151–159CrossRef

108.

Lee J-C, Kim W, Choi S (2017) Fabrication of a SERS-encoded microfluidic paper-based analytical chip for the point-of-assay of wastewater. Int J Precis Eng Manuf-Green Tech 4:221–226CrossRef

109.

Bharadwaj S, Pandey A, Yagci B, Ozguz V, Qureshi A (2018) Graphene nano-mesh-Ag-ZnO hybrid paper for sensitive SERS sensing and self-cleaning of organic pollutants. Chem Eng J 336:445–455CrossRef

110.

Jokerst JC, Adkins JA, Bisha B, Mentele MM, Goodridge LD, Henry CS (2012) Development of a paper-based analytical device for colorimetric detection of select foodborne pathogens. Anal Chem 84:2900–2907CrossRef

111.

Alhogail S, Suaifan G, Zourob M (2016) Rapid colorimetric sensing platform for the detection of Listeria monocytogenes foodborne pathogen. Biosens Bioelectron 86:1061–1066CrossRef

112.

Hakovirta M, Aksoy B, Hakovirta J (2015) Self-assembled micro-structured sensors for food safety in paper based food packaging. Mater Sci Eng, C 53:331–335CrossRef

113.

Swerin A, Mira I (2014) Ink-jettable paper-based sensor for charged macromolecules and surfactants. Sens Actuators B Chem 195:389–395CrossRef

114.

Kong Q, Wang Y, Zhang L, Ge S, Yu J (2017) A novel microfluidic paper-based colorimetric sensor based on molecularly imprinted polymer membranes for highly selective and sensitive detection of bisphenol A. Sens Actuators B Chem 243:130–136CrossRef

115.

Liu C-C, Wang Y-N, Fu L-M, Chen K-L (2018) Microfluidic paper-based chip platform for benzoic acid detection in food. Food Chem 249:162–167CrossRef

116.

Ma L, Nilghaz A, Choi JR, Liu X, Lu X (2018) Rapid detection of clenbuterol in milk using microfluidic paper-based ELISA. Food Chem 246:437–441CrossRef

117.

Gao N, Huang P, Wu F (2018) Colorimetric detection of melamine in milk based on Triton X-100 modified gold nanoparticles and its paper-based application. Spectrochim Acta A Mol Biomol Spectrosc 192:174–180CrossRef

118.

Ha N-R, Jung I-P, Kim S-H, Kim AR, Yoon M-Y (2017) Paper chip-based colorimetric sensing assay for ultra-sensitive detection of residual kanamycin. Process Biochem 62:161–168CrossRef

119.

Xiao L, Zhang Z, Wu C, Han L, Zhang H (2017) Molecularly imprinted polymer grafted paper-based method for the detection of 17b-Estradiol. Food Chem 221:82–86CrossRef

120.

Nouanthavong S, Nacapricha D, Henry CS, Sameenoi Y (2016) Pesticide analysis using nanoceria-coated paper-based devices as a detection platform. Analyst 141(5):1837–1846CrossRef

121.

Liu C-C, Wang Y-N, Fu L-M, Yang D-Y (2017) Rapid integrated microfluidic paper-based system for sulfur dioxide detection. Chem Eng J 316:790–796CrossRef

122.

Busa LS, Mohammadi S, Maeki M, Ishida A, Tani H, Tokeshi M (2016) A competitive immunoassay system for microfluidic paper-based analytical detection of small size molecules. Analyst 141:6598–6603CrossRef

123.

Lopez Marzo AM, Pons J, Blake DA, Merkoci A (2013) All-integrated and highly sensitive paper based device with sample treatment platform for Cd²⁺ immunodetection in drinking/tap waters. Anal Chem 85:3532–3538CrossRef

124.

Nath P, Arun RK, Chanda N (2014) A paper based microfluidic device for the detection of arsenic using a gold nanosensor. RSC Adv 4:59558–59561CrossRef

125.

Cinti S, Basso M, Moscone D, Arduini F (2017) A paper-based nanomodified electrochemical biosensor for ethanol detection in beers. Anal Chim Acta 960:123–130CrossRef

126.

Chaiyo S, Apiluk A, Siangproh W, Chailapakul O (2016) High sensitivity and specificity simultaneous determination of lead, cadmium and copper using μPAD with dual electrochemical and colorimetric detection. Sens Actuators B Chem 233:540–549CrossRef

127.

Bi X-M, Wang H-R, Ge L-Q, Zhou D-M, Xu J-Z, Gu H-Y, Bao N (2018) Gold-coated nanostructured carbon tape for rapid electrochemical detection of cadmium in rice with in situ electrodeposition of bismuth in paper-based analytical devices. Sens Actuators B Chem. https://doi.org/10.1016/j.snb.2018.01.007

128.

Koskela J et al (2015) Monitoring the quality of raw poultry by detecting hydrogen sulfide with printed sensors. Sens Actuators B Chem 218:89–96CrossRef

129.

Mraovic M, Muck T, Pivar M, Trontelj J, Pletersek A (2014) Humidity sensors printed on recycled paper and cardboard. Sensors 14:13628–13643CrossRef

130.

Morales-Narváez E, Naghdi T, Zor E, Merkoçi A (2015) Photoluminescent lateral-flow immunoassay revealed by graphene oxide: highly sensitive paper-based pathogen detection. Anal Chem 87:8573–8577CrossRef

131.

Guzman JMCC, Tayo LL, Liu C-C, Wang Y-N, Fu L-M (2018) Rapid microfluidic paper-based platform for low concentration formaldehyde detection. Sens Actuators B Chem 255:3623–3629CrossRef

132.

Liu C-C, Wang Y-N, Fu L-M, Huang Y-H (2018) Microfluidic paper-based chip platform for formaldehyde concentration detection. Chem Eng J 332:695–701CrossRef

133.

Zhang Y, Zuo P, Ye BC (2015) A low-cost and simple paper-based microfluidic device for simultaneous multiplex determination of different types of chemical contaminants in food. Biosens Bioelectron 68:14–19CrossRef

134.

Jin SQ, Guo SM, Zuo P, Ye BC (2015) A cost-effective Z-folding controlled liquid handling microfluidic paper analysis device for pathogen detection via ATP quantification. Biosens Bioelectron 63:379–383CrossRef

135.

Mirasoli M, Buragina A, Dolci LS, Simoni P, Anfossi L, Giraudi G, Roda A (2012) Chemiluminescence-based biosensor for fumonisins quantitative detection in maize samples. Biosens Bioelectron 32:283–287CrossRef

136.

Liu W, Guo Y, Luo J, Kou J, Zheng H, Li B, Zhang Z (2015) A molecularly imprinted polymer based a lab-on-paper chemiluminescence device for the detection of dichlorvos. Spectrochim Acta A Mol Biomol Spectrosc 141:51–57CrossRef

137.

Liu W, Kou J, Xing H, Li B (2014) Paper-based chromatographic chemiluminescence chip for the detection of dichlorvos in vegetables. Biosens Bioelectron 52:76–81CrossRef

138.

Li D, Ma Y, Duan H, Deng W, Li D (2018) Griess reaction-based paper strip for colorimetric/fluorescent/SERS triple sensing of nitrite. Biosens Bioelectron 99:389–398CrossRef

139.

Zhu Y, Li M, Yu D, Yang L (2014) A novel paper rag as ‘D-SERS’ substrate for detection of pesticide residues at various peels. Talanta 128:117–124CrossRef

140.

Tseng SY, Li SY, Yi SY, Sun AY, Gao DY, Wan D (2017) Food quality monitor: Paper-based plasmonic sensors prepared through reversal nanoimprinting for rapid detection of biogenic amine odorants. ACS Appl Mater Interfaces 9:17307–17317

141.

Gonzalez CM, Iqbal M, Dasog M, Piercey DG, Lockwood R, Klapotke TM, Veinot JG (2014) Detection of high-energy compounds using photoluminescent silicon nanocrystal paper based sensors. Nanoscale 6:2608–2612CrossRef

142.

Sablok K, Bhalla V, Sharma P, Kaushal R, Chaudhary S, Suri CR (2013) Amine functionalized graphene oxide/CNT nanocomposite for ultrasensitive electrochemical detection of trinitrotoluene. J Hazard Mater 248–249:322–328CrossRef

143.

Peters KL, Corbin I, Kaufman LM, Zreibe K, Blanes L, McCord BR (2015) Simultaneous colorimetric detection of improvised explosive compounds using microfluidic paper-based analytical devices (μPADs). Anal Methods 7:63–70CrossRef

144.

Aparna RS, Anjali Devi JS, Sachidanandan P, George S (2018) Polyethylene imine capped copper nanoclusters-fluorescent and colorimetric onsite sensor for the trace level detection of TNT. Sens Actuators B Chem 254:811–819CrossRef

145.

Nergiz SZ, Gandra N, Farrell ME, Tian L, Pellegrino PM, Singamaneni S (2013) Biomimetic SERS substrate: peptide recognition elements for highly selective chemical detection in chemically complex media. J Mater Chem A 1:6543–6549CrossRef

146.

Hughes S, Dasary SS, Begum S, Williams N, Yu H (2015) Meisenheimer complex between 2,4,6-trinitrotoluene and 3-aminopropyltriethoxysilane and its use for a paper-based sensor. Sens Biosensing Res 5:37–41CrossRef

147.

Pesenti A, Taudte RV, McCord B, Doble P, Roux C, Blanes L (2014) Coupling paper-based microfluidics and lab on a chip technologies for confirmatory analysis of trinitro aromatic explosives. Anal Chem 86:4707–4714CrossRef

148.

Huang S, He Q, Xu S, Wang L (2015) Polyaniline-based photothermal paper sensor for sensitive and selective detection of 2,4,6-trinitrotoluene. Anal Chem 87:5451–5456CrossRef

149.

da Silva GO, de Araujo WR, Paixao T (2018) Portable and low-cost colorimetric office paper-based device for phenacetin detection in seized cocaine samples. Talanta 176:674–678CrossRef

150.

Narang J, Malhotra N, Singhal C, Mathur A, Pn AK, Pundir CS (2017) Detection of alprazolam with a lab on paper economical device integrated with urchin like Ag@ Pd shell nano-hybrids. Mater Sci Eng, C 80:728–735CrossRef

151.

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

152.

Zhu W-J, Feng D-Q, Chen M, Chen Z-D, Zhu R, Fang H-L, Wang W (2014) Bienzyme colorimetric detection of glucose with self-calibration based on tree-shaped paper strip. Sens Actuators B Chem 190:414–418CrossRef

153.

Malekghasemi S, Kahveci E, Duman M (2016) Rapid and alternative fabrication method for microfluidic paper based analytical devices. Talanta 159:401–411CrossRef

154.

Kannan B, Jahanshahi-Anbuhi S, Pelton RH, Li Y, Filipe CD, Brennan JD (2015) Printed paper sensors for serum lactate dehydrogenase using pullulan-based inks to immobilize reagents. Anal Chem 87:9288–9293CrossRef

155.

Pardee K et al (2016) Rapid, low-cost detection of Zika virus using programmable biomolecular components. Cell 165:1255–1266CrossRef

156.

Sharpe E, Frasco T, Andreescu D, Andreescu S (2013) Portable ceria nanoparticle-based assay for rapid detection of food antioxidants (NanoCerac). Analyst 138:249–262CrossRef

157.

Guan L, Tian J, Cao R, Li M, Cai Z, Shen W (2014) Barcode-like paper sensor for smartphone diagnostics: an application of blood typing. Anal Chem 86:11362–11367CrossRef

158.

Khatri V, Halasz K, Trandafilovic LV, Dimitrijevic-Brankovic S, Mohanty P, Djokovic V, Csoka L (2014) ZnO-modified cellulose fiber sheets for antibody immobilization. Carbohydr Polym 109:139–147CrossRef

159.

Noiphung J, Songjaroen T, Dungchai W, Henry CS, Chailapakul O, Laiwattanapaisal W (2013) Electrochemical detection of glucose from whole blood using paper-based microfluidic devices. Anal Chim Acta 788:39–45CrossRef

160.

Wang P, Cheng Z, Chen Q, Qu L, Miao X, Feng Q (2018) Construction of a paper-based electrochemical biosensing platform for rapid and accurate detection of adenosine triphosphate (ATP). Sens Actuators B Chem 256:931–937CrossRef

161.

Li X, Liu X (2016) A microfluidic paper-based origami nanobiosensor for label-free, ultrasensitive immunoassays. Adv Healthc Mater 5:1326–1335CrossRef

162.

Scordo G, Moscone D, Palleschi G, Arduini F (2018) A reagent-free paper-based sensor embedded in a 3D printing device for cholinesterase activity measurement in serum. Sens Actuators B Chem 258:1015–1021CrossRef

163.

Lee SH, Lee JH, Tran V-K, Ko E, Park CH, Chung WS, Seong GH (2016) Determination of acetaminophen using functional paper-based electrochemical devices. Sens Actuators B Chem 232:514–522CrossRef

164.

Adkins JA, Noviana E, Henry CS (2016) Development of a quasi-steady flow electrochemical paper-based analytical device. Anal Chem 88:10639–10647CrossRef

165.

da Costa TH, Song E, Tortorich RP, Choi J-W (2015) A paper-based electrochemical sensor using inkjet-printed carbon nanotube electrodes. ECS J Solid State Sci Technol 4:S3044–S3047CrossRef

166.

Cinti S, Minotti C, Moscone D, Palleschi G, Arduini F (2017) Fully integrated ready-to-use paper-based electrochemical biosensor to detect nerve agents. Biosens Bioelectron 93:46–51CrossRef

167.

Nantaphol S, Channon RB, Kondo T, Siangproh W, Chailapakul O, Henry CS (2017) Boron doped diamond paste electrodes for microfluidic paper-based analytical devices. Anal Chem 89:4100–4107CrossRef

168.

Zhang H, Zhao Z, Lei Z, Wang Z (2016) Sensitive detection of polynucleotide kinase activity by paper-based fluorescence assay with l exonuclease-assistance. Anal Chem 88:11358–11363CrossRef

169.

Jiang P, He M, Shen L, Shi A, Liu Z (2017) A paper-supported aptasensor for total IgE based on luminescence resonance energy transfer from upconversion nanoparticles to carbon nanoparticles. Sens Actuators B Chem 239:319–324CrossRef

170.

Liang L et al (2016) Aptamer-based fluorescent and visual biosensor for multiplexed monitoring of cancer cells in microfluidic paper-based analytical devices. Sens Actuators B Chem 229:347–354CrossRef

171.

Saha B, Baek S, Lee J (2017) Highly sensitive bendable and foldable paper sensors based on reduced graphene oxide. ACS Appl Mater Interfaces 9:4658–4666CrossRef

172.

Gong MM, Nosrati R, San Gabriel MC, Zini A, Sinton D (2015) Direct DNA analysis with paper-based ion concentration polarization. J Am Chem Soc 137:13913–13919CrossRef

173.

Davaji B, Lee CH (2014) A paper-based calorimetric microfluidics platform for bio-chemical sensing. Biosens Bioelectron 59:120–126CrossRef

174.

Chen GH, Chen WY, Yen YC, Wang CW, Chang HT, Chen CF (2014) Detection of mercury (II) ions using colorimetric gold nanoparticles on paper-based analytical devices. Anal Chem 86:6843–6849CrossRef

175.

Sicard C et al (2015) Tools for water quality monitoring and mapping using paper-based sensors and cell phones. Water Res 70:360–369CrossRef

176.

Wang B, Lin Z, Wang M (2015) Fabrication of a paper-based microfluidic device to readily determine nitrite ion concentration by simple colorimetric assay. J Chem Educ 92:733–736CrossRef

177.

Rattanarat P, Dungchai W, Cate D, Volckens J, Chailapakul O, Henry CS (2014) Multilayer paper-based device for colorimetric and electrochemical quantification of metals. Anal Chem 86:3555–3562CrossRef

178.

Cho YB, Jeong SH, Chun H, Kim YS (2018) Selective colorimetric detection of dissolved ammonia in water via modified Berthelot’s reaction on porous paper. Sens Actuators B Chem 256:167–175CrossRef

179.

Lamas-Ardisana PJ et al (2017) Disposable electrochemical paper-based devices fully fabricated by screen-printing technique. Electrochem Commun 75:25–28CrossRef

180.

Qin Y, Pan S, Howlader MM, Ghosh R, Hu NX, Deen MJ (2016) Paper-based, hand-drawn free chlorine sensor with poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate). Anal Chem 88:10384–10389CrossRef

181.

Cinti S, Talarico D, Palleschi G, Moscone D, Arduini F (2016) Novel reagentless paper-based screen-printed electrochemical sensor to detect phosphate. Anal Chim Acta 919:78–84CrossRef

182.

Li H, Wang W, Lv Q, Xi G, Bai H, Zhang Q (2016) Disposable paper-based electrochemical sensor based on stacked gold nanoparticles supported carbon nanotubes for the determination of bisphenol A. Electrochem Commun 68:104–107CrossRef

183.

Chouler J, Cruz-Izquierdo A, Rengaraj S, Scott JL, Di Lorenzo M (2018) A screen-printed paper microbial fuel cell biosensor for detection of toxic compounds in water. Biosens Bioelectron 102:49–56CrossRef

184.

Zhang R, Zhang C-J, Song Z, Liang J, Kwok RTK, Tang BZ, Liu B (2016) AIEgens for real-time naked-eye sensing of hydrazine in solution and on a paper substrate: structure-dependent signal output and selectivity. J Mater Chem C 4:2834–2842CrossRef

185.

Fraiwan A, Lee H, Choi S (2016) A paper-based cantilever array sensor: monitoring volatile organic compounds with naked eye. Talanta 158:57–62CrossRef

186.

Bulbul G, Eskandarloo H, Abbaspourrad A (2018) A novel paper based colorimetric assay for the detection of TiO₂ nanoparticles. Anal Methods 10:275–280CrossRef

Titel: Recent Advances in Paper-Based Analytical Devices: A Pivotal Step Forward in Building Next-Generation Sensor Technology
verfasst von: Charu Agarwal
Levente Csóka
Verlag: Springer International Publishing
Buch: Sustainable Polymer Composites and Nanocomposites
Print ISBN: 978-3-030-05398-7

Electronic ISBN: 978-3-030-05399-4

Copyright-Jahr: 2019
DOI: https://doi.org/10.1007/978-3-030-05399-4_18

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