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2012 | OriginalPaper | Buchkapitel

4. Microcantilever Sensors: Electrochemical Aspects and Biomedical Applications

verfasst von : Lana Norman, Garima Thakur, Thomas Thundat

Erschienen in: Biomedical Applications

Verlag: Springer US

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Abstract

Microfabricated cantilevers, similar to those used in Atomic Force Microscopy (AFM), are generating growing interest as a sensor platform for label-free detection of chemical and biological molecules [1–17]. Using recent advances in surface microfabrication, it is possible to design and fabricate cantilevers and cantilever arrays with extremely high sensitivity for mass or surface stress. These cantilevers are generally fabricated from silicon or silicon nitride by top-down micromachining methods and can be produced efficiently and affordably. Although the cantilevers have micrometer dimensions, their response are in nanometer-scale, which lends itself to their reference as nanomechanical transducers. The cantilever can be made in different shapes and sizes allowing for flexibility in the design, which renders the resulting cantilevers ideal candidates for the possible incorporation in microfluidic and miniaturized lab-on-a-chip devices. Generally, these cantilevers are operated in either the static deflection mode or the dynamic resonant mode. The basic principle for the static mode is that a chemical or physical event occurring at the functionalized surface of one side of the cantilever generates a surface stress difference (between the active functionalized and passive non-functionalized sides) that causes the cantilever to bend away from its resting position. Whereas in the resonant mode, a binding event occurring on the cantilever increases the overall mass thus decreasing the resonant frequency, which is similar to quartz crystal microbalances. In general, when a force is applied to the end of a free standing cantilever a vertical bending will result. As described by Hooke’s Law ($ (F=-k_{spring}\Delta z),$), the bending or deflection (Δz) of the cantilever is directly proportional to the applied force F, and the cantilever spring constant k _spring is the proportionality factor. The cantilever spring constant dictates the flexibility and sensitivity of the cantilever and is defined by its dimensions and material constants. For a rectangular-shaped cantilever, k _spring, is given by [18]

$$ k_{spring}\frac{Ewt^{3}}{4l^3}$$

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Thundat T, Warmack RJ, Chen GY, Allison DP (1994) Appl Phys Lett 64:2894CrossRef

Gimzewski JK, Gerber C, Meyer E, Schlittler RR (1994) Chem Phys Lett 217:589CrossRef

Chen GY, Thundat T, Wachter EA, Warmack RJ (1995) J Appl Phys 77:3618CrossRef

Butt H-J (1996) J Colloid Interface Sci 180:251CrossRef

Thundat T, Oden PI, Warmack RJ (1997) Microscale Thermophys Eng 1:185CrossRef

Berger R, Delamarche E, Lang H-P, Gerber C, Gimzewski JK, Meyer E, Güntherodt H-J (1997) Science 276:2021CrossRef

Raiteri R, Grattarola M, Butt H-J, Skládal P (2001) Sens Actuators B 79:115CrossRef

Lang HP, Hegner M, Gerber C (2005) Mater Today 8:30CrossRef

Sepaniak M, Datskos P, Lavrik N, Tipple C (2002) Anal Chem 74:568ACrossRef

10.

Hansen KM, Thundat T (2005) Methods 37:57CrossRef

11.

Lang HP, Baller MK, Berger R, Gerber C, Gimzewski JK, Battiston FM, Fornaro P, Ramseyer JP, Meyer E, Güntherodt HJ (1999) Anal Chim Acta 393:59CrossRef

12.

Ziegler C (2004) Anal Bioanal Chem 379:946

13.

Lavrik NV, Sepaniak MJ, Datskos PG (2004) Rev Sci Instrum 75:2229CrossRef

14.

Goeders KM, Colton JS, Bottomley LA (2008) Chem Rev 108:522CrossRef

15.

Raiteri R, Grattarola M, Berger R (2002) Mater Today 5:22CrossRef

16.

Waggoner PS, Craighead HG (2007) Lab Chip 7:1238CrossRef

17.

Singamaneni S, LeMieux MC, Lang H-P, Gerber C, Jiang H, Naik RR, Bunning JJ, Tsukruk VV (2008) Adv Mater 20:653CrossRef

18.

Sader JE (2002) In: Hubbard A (ed) Encyclopedia of surface and colloid science. Marcel Dekker, New York, p 846

19.

Fritz J (2008) Analyst 133:855CrossRef

20.

Baller MK, Fritz J (2004) In: Kambhampati D (ed) Protein microarray technology. Wiley-VCH, Weinheim, p 195

21.

Berger R, Lang HP, Gerber C, Gimzewski JK, Fabian JH, Scandella L, Meyer E, Güntherodt H-J (1998) Chem Phys Lett 294:363CrossRef

22.

Barnes JR, Stephenson RJ, Woodburn CN, O’Shea SJ, Welland ME, Rayment T, Gimzewski JK, Gerber C (1994) Rev Sci Instrum 65:3793CrossRef

23.

Bachels T, Tiefenbacher F, Schäfer R (1999) J Chem Phys 110:10008CrossRef

24.

Krause AR, Van Neste C, Senesac L, Thundat T, Finot E (2008) J Appl Phys 103:094906CrossRef

25.

Barnes JR, Stephenson RJ, Welland ME, Gerber C, Gimzewski JK (1994) Nature 372:79CrossRef

26.

Wig A, Arakawa ET, Passian A, Ferrell TL, Thundat T (2006) Sens Actuators B 114:206CrossRef

27.

Burg TP, Godin M, Knudsen SM, Shen W, Carlson G, Foster JS, Babcock K, Manalis SR (2007) Nature 446:1066CrossRef

28.

Bryan AK, Goranov A, Amon A, Manalis SR (2010) Proc Natl Acad Sci 107:999CrossRef

29.

Godin M, Delgado FF, Son S, Grover WH, Bryan AK, Tzur A, Jorgensen P, Payer K, Grossman AD, Kirschner MW, Manalis SR (2010) Nat Methods 7:387CrossRef

30.

Stoney GG (1909) Proc R Soc London Ser A 82:172CrossRef

31.

Haiss W (2001) Rep Prog Phys 64:591CrossRef

32.

Godin M, Tabard-Cossa V, Grütter P, Williams P (2001) Appl Phys Lett 79:551CrossRef

33.

Tabard-Cossa V, Godin M, Beaulieu LY, Grütter P (2005) Sens Actuators B 107:233CrossRef

34.

Tabard-Cossa V, Godin M, Beaulieu LY, Grütter P (2006) Sens Actuators B 119:352CrossRef

35.

Ibach H (1997) Surf Sci Rep 29:195CrossRef

36.

Lang HP, Gerber C (2008) In: Samori P (ed) STM and AFM studies on (bio)molecular systems: unravelling the nanoworld, vol 285. Springer, Heidelberg, p. 1.

37.

Norman LL, Badia A (2009) J Am Chem Soc 131:2328CrossRef

38.

Evans DR, Craig VSJ (2006) J Phys Chem B 110:5450CrossRef

39.

Freund LB, Floro JA, Chason E (1999) Appl Phys Lett 74:1987CrossRef

40.

Jeon S, Thundat T (2004) Appl Phys Lett 85:1083CrossRef

41.

Klein CA (2000) J Appl Phys 88:5487CrossRef

42.

Mertens J, Álvarez M, Tamayo J (2005) Appl Phys Lett 87:234102CrossRef

43.

Rasmussen PA, Hansen O, Boisen A (2005) Appl Phys Lett 86:203502CrossRef

44.

Sader JE (2001) J Appl Phys 89:2911CrossRef

45.

Sader JE, Larson I, Mulvaney P, White LR (1995) Rev Sci Instrum 66:3789CrossRef

46.

Zhang Y, Ren Q, Zhoa Y-p (2004) J Phys D Appl Phys 37:2140CrossRef

47.

Miyatani T, Fujihira M (1997) J Appl Phys 80:7099CrossRef

48.

Khan A, Philip J, Hess P (2004) J Appl Phys 95:1667CrossRef

49.

Fritz J, Baller MK, Lang HP, Rothuizen H, Vettiger P, Meyer E, Güntherodt H-J, Gerber C, Gimzewski JK (2000) Science 288:316CrossRef

50.

Fritz J, Cooper EB, Gaudet S, Sorger PK, Manalis SR (2002) Proc Natl Acad Sci 99:14142CrossRef

51.

Mukhopadhyay R, Lorentzen M, Kjems J, Besenbacher F (2005) Langmuir 21:8400CrossRef

52.

Shu W, Liu D, Watari M, Riener CK, Strunz T, Welland ME, Balasubramanian S, McKendry RA (2005) J Am Chem Soc 127:17054CrossRef

53.

Mckendry RA, Zhang J, Arntz Y, Strunz T, Hegner M, Lang HP, Baller MK, Certa U, Meyer E, Güntherodt H-J, Gerber C (2002) Proc Natl Acad Sci 99:9783CrossRef

54.

Wu G, Ji H, Hansen K, Thundat T, Datar R, Cote R, Hagan MF, Chakraborty AK, Majumdar A (2001) Proc Natl Acad Sci 98:1560CrossRef

55.

Stachowiak JC, Yue M, Castelino K, Chakraborty AK, Majumdar A (2006) Langmuir 2006:263CrossRef

56.

Backmann N, Zahnd C, Huber F, Bietsch A, Plückthun A, Lang H-P, Güntherodt H-J, Hegner M, Gerber C (2005) Proc Natl Acad Sci 102: 14587CrossRef

57.

Savran CA, Knudsen SM, Ellington AD, Manalis SR (2004) Anal Chem 76:3194CrossRef

58.

Park J, Ryu J, Choi SK, Seo E, Cha JM, Ryu S, Kim J, Kim B, Lee SH (2005) Anal Chem 77:6571CrossRef

59.

Ilic B, Yang Y, Craighead HG (2004) Appl Phys Lett 85:2604CrossRef

60.

Álvarez M, Carrascosa LG, Moreno M, Calle A, Zaballos Á, Lechuga LM, Martínez-A C, Tamayo J (2004) Langmuir 20:9663CrossRef

61.

Khaled A-RA, Vafia K, Yang M, Zhang X, Ozkan CS (2003) Sens Actuators B 94:103CrossRef

62.

Watari M, Galbraith J, Lang H-P, Sousa M, Hegner M, Gerber C, Horton MA, McKendry RA (2007) J Am Chem Soc 129:601CrossRef

63.

Hagan MF, Majumdar A, Chakraborty AK (2002) J Phys Chem B 106:10163CrossRef

64.

Zhang J, Lang HP, Huber F, Bietsch A, Grange W, Certa U, McKendry RA, Güntherodt H-J, Hegner M, Gerber C (2006) Nat Nanotechnol 1:214CrossRef

65.

Ndieyira JW, Watari M, Barrera AD, Zhou D, Vögtli M, Batchelor M, Cooper MA, Strunz T, Horton MA, Abell C, Rayment T, Aeppli G, McKendry RA (2008) Nat Nanotechnol 3:691CrossRef

66.

Godin M, Laroche O, Tabard-Cossa V, Beaulie LY, Grütter P, Williams PJ (2003) Rev Sci Instrum 74:4902CrossRef

67.

Fischer LM, Pedersen C, Elkjær K, Noeth N-N, Dohn L, Boisen A, Tenje M (2011) Sens Actuators B 157:321CrossRef

68.

Tian F, Pei JH, Hedden DL, Brown GM, Thundat T (2004) Ultramicroscopy 100:217CrossRef

69.

Ansari MZ, Cho C (2009) Sensors 9:6046CrossRef

70.

Lee P-S, Lee J, Shin N, Lee K-H, Lee D, Jeon S, Choi D, Hwang W, Park H (2008) Adv Mater 20:1732CrossRef

71.

Sharma G, Svensson S, Ogden S, Klintberg L, Hjort K (2011) J Micromechanics Microeng 21, 075010

72.

Lee W-B, Chen Y-H, Lin H-I, Shiesh S-C, Lee G-B (2011) Sens Actuators B Chem 157:710CrossRef

73.

Ogilvie IRG, Sieben VJ, Cortese B, Mowlem MC, Morgan H (2011) Lab Chip 11:2455CrossRef

74.

Ricciardi C, Canavese G, Castagna R, Ferrante I, Ricci A, Marasso SL, Napione L, Bussolino F (2010) Biosens Bioelectron 26:1565CrossRef

75.

Avila M, Zougagh M, Escarpa A, Rios A (2009) Electrophoresis 30:3413CrossRef

76.

Ezkerra A, Fernández LJ, Mayora K, Ruano-López JM (2011) Sens Actuators B Chem 155:505CrossRef

77.

Leichle T, Nicu L, Descamps E, Corso B, Mailley P, Livache T, Bergaud C (2006) Appl Phys Lett 88:254108CrossRef

78.

Bange AF, Brown GM, Senesac LR, Thundat T (2009) Surf Sci 603:L125CrossRef

79.

Brunt TA, Rayment T, O’Shea SJ, Welland ME (1996) Langmuir 12:5942CrossRef

80.

Brunt TA, Chabala ED, Rayment T, O’Shea SJ, Welland ME (1996) J Chem Soc Faraday Trans 92:3807CrossRef

81.

Bard AJ, Faulkner LR (2001) Electrochemical methods fundamentals and applications, 2nd edn. Wiley, New York

82.

Herrero E, Buller LJ, Abruña HD (2001) Chem Rev 101:1897CrossRef

83.

Qazi M, Koley G (2008) Sensors 8:7144CrossRef

84.

Mandeles A, Christofides C (1993) Physics, chemistry and technology of solid state gas sensor devices. Wiley, New York, NY

85.

Koley G, Qazi M, Lakshmanan L, Thundat T (2007) Appl Phys Lett 90:173105CrossRef

86.

Koley G, Spencer MG (2001) J Appl Phys 90:337CrossRef

87.

Sasaki N, Tsukada M (1998) Jpn J Appl Phys 2(37):L533CrossRef

88.

Lahav M, Durkan C, Gabai R, Katz E, Willner I, Welland ME (2001) Angew Chem Int Ed 40:4095CrossRef

89.

Tabard-Cossa V, Godin M, Grütter P, Burgess I, Lennox RB (2005) J Phys Chem B 109:17531CrossRef

90.

Smela E (2003) Adv Mater 15:481CrossRef

91.

Bumbu G-G, Kircher G, Wolkenhauer M, Berger R, Gutmann JS (2004) Macromol Chem Phys 205:1713CrossRef

92.

Bumbu G-G, Wolkenhauer M, Kircher G, Gutmann JS, Berger R (2007) Langmuir 23:2203CrossRef

93.

Zhou F, Biesheuvel PM, Choi E-Y, Shu W, Poetes R, Steiner U, Huck WTS (2008) Nano Lett 8:725CrossRef

94.

Zhou F, Huck WTS (2006) Phys Chem Chem Phys 8:3815CrossRef

95.

Zhou F, Shu W, Welland ME, Huck WTS (2006) J Am Chem Soc 128: 5326CrossRef

96.

Liu Y, Flood AH, Bonvallet PA, Vignon SA, Northrop BH, Tseng H-R, Jeppesen JO, Huang TJ, Brough B, Baller M, Magonova S, Solares SD, Goddard WA, Ho C-M, Stoddard JF (2005) J Am Chem Soc 127:9745CrossRef

97.

Huang TJ, Brough B, Ho C-M, Liu Y, Flood AH, Bonvallet PA, Tseng H-R, Stoddard JF, Baller M, Magonova S (2004) Appl Phys Lett 85:5391CrossRef

98.

Juluri BK, Kumar AS, Liu Y, Ye T, Yang Y-W, Flood AH, Fang L, Stoddard JF, Weiss PS, Huang TJ (2009) ACS Nano 3:291CrossRef

99.

Bay L, Jacobsen T, Skaarup S, West K (2001) J Phys Chem B 105:8492CrossRef

100.

Roemer M, Kurzenknabe T, Oesterschulze E, Nicoloso N (2002) Anal Bioanal Chem 373:754CrossRef

101.

Liu Y, Flood AH, Bonvallet PA, Vignon SA, Northrop BH, Tseng H-R, Jeppesen JO, Huang TJ, Brough B, Baller M, Magonov S, Solares SD, Goddard WA, Ho C-M, Stoddard JF (2005) J Am Chem Soc 127:9745CrossRef

102.

Chegel V, Raitman O, Katz E, Gabai R, Willner I (2001) Chem Commun 10:883CrossRef

103.

Howse JR, Topham P, Crook CJ, Gleeson AJ, Bras W, Jones RAL, Ryan AJ (2006) Nano Lett 6:73CrossRef

104.

Valiaev A, Abu-Lail NI, Lim DW, Chilkoti A, Zauscher S (2007) Langmuir 33:339CrossRef

105.

Igarashi S, Itakura AN, Toda M, Kitajima M, Chu L, Chifen AN, Förch R, Berger R (2006) Sens Actuators B 117:43CrossRef

106.

Abu-Lail NI, Kaholek M, LaMattina B, Clark RL, Zauscher S (2006) Sens Actuators B 114:371CrossRef

107.

Rant U, Arinaga K, Fujita S, Yokoyama N, Abstreiter G, Tornow M (2004) Nano Lett 4:2441CrossRef

108.

Rant U, Arinaga K, Fujita S, Yokoyama N, Abstreiter G, Tornow M (2006) Org Biomol Chem 4:3448CrossRef

109.

Shen G, Tercero N, Gaspar MA, Varughese B, Shepard K, Levicky R (2006) J Am Chem Soc 128:8427CrossRef

110.

Sushko ML, Harding JH, Shluger AL, McKendry RA, Watari M (2008) Adv Mater 20:3848CrossRef

111.

Tabard-Cossa V, Godin M, Burgess IJ, Monga T, Lennox RB, Grütter P (2007) Anal Chem 79:8136CrossRef

112.

Kohale S, Molina SM, Weeks BL, Kare R, Hope-Weeks LJ (2007) Langmuir 23:1258CrossRef

113.

Godin M, Williams PJ, Tabard-Cossa V, Laroche O, Beaulie LY, Lennox RB, Grütter P (2004) Langmuir 20:7090CrossRef

114.

Headrick JJ, Sepaniak MJ, Lavrik NV, Datskos PG (2003) Ultramicroscopy 97:417CrossRef

115.

Lavrik NV, Tipple CA, Sepaniak MJ, Datskos PG (2001) Chem Phys Lett 336:371CrossRef

116.

Hansen AG, Martensen MW, Anderson JET, Ulstrup J, Kuhlue A, Garnaes J, Boisen A (2001) Probe Microsc 2:139

117.

Desikan R, Lee I, Thundat T (2006) Ultramicroscopy 106:795CrossRef

118.

Mertens J, Calleja M, Tarýn A, Tamayo J (2007) J Appl Phys 101:034904CrossRef

119.

Berger R, Delamarche E, Lang HP, Gerber C, Gimzewski JK, Meyer E, Güntherodt H-J (1998) Appl Phys A 66:S55CrossRef

120.

Desikan R, Armel S, Meyer HM III, Thundat T (2007) Nanotechnology 18:424028CrossRef

121.

Quist F, Tabard-Cossa V, Badia A (2003) J Phys Chem B 107:10691CrossRef

122.

Norman LL, Badia A (2011) J Phys Chem C 115:1985CrossRef

123.

Finklea HO (1996) In: Bard AJ, Rubinstein I (eds) Electroanalytical chemistry, vol 19. Marcel Dekker, New York, p 109

124.

Weber KS, Creager SE (1998) J Electroanal Chem 458:17CrossRef

125.

Valincius G, Niaura G, Kazakevičienė B, Talaikytė Z, Kažemėkaitė M, Butkus E, Razumas V (2004) Langmuir 20:6631CrossRef

126.

Kazakevičienė B, Valincius G, Niaura G, Talaikytė Z, Kažemėkaitė M, Razumas V, Plaušinaitis D, Teišerskienė A, Lisauskas V (2007) Langmuir 23:4965CrossRef

127.

Ju H, Leech D (1999) Phys Chem Chem Phys 1:1549CrossRef

128.

Lee LYS, Sutherland TC, Rucareanu S, Lennox RB (2006) Langmuir 22:4438CrossRef

129.

Sato Y, Mizutani F, Shimazu K, Ye S, Uosaki K (1999) J Electroanal Chem 474:94CrossRef

130.

Kondo T, Okamura M, Uosaki K (2001) J Organomet Chem 637–639:841CrossRef

131.

Auletta T, van Veggel FCJM, Reinhoudt DN (2002) Langmuir 18:1288CrossRef

132.

Kazakevičienė B, Valincius G, Niaura G, Talaikytė Z, Kažemėkaitė M, Razumas V (2003) J Phys Chem B 1007:6661CrossRef

133.

Viana AS, Jones AH, Abrantes LM, Kalaji M (2001) J Electroanal Chem 500:290CrossRef

134.

Weber KS, Hockett LA, Creager SE (1997) J Phys Chem B 101:8286CrossRef

135.

Sondag-Huethorst JAM, Fokkink LGJ (1994) Langmuir 10:4380CrossRef

136.

Luk Y-Y, Abbott NL (2003) Science 301:623CrossRef

137.

Calvente JJ, Andreu R, Molero M, Lopez-Perez G, Domínguez M (2001) J Phys Chem B 105:9557CrossRef

138.

Smith CP, White HS (1992) Anal Chem 64:2398CrossRef

139.

Koev ST, Powers MA, Yi H, Wu LQ, Bentley WE, Rubloff GW, Payne GF, Ghodssi R (2007) Lab Chip 7:103CrossRef

140.

Payne GF, Wu LQ (2004) Trends Biotechnol 22:593CrossRef

141.

Payne GF, Yi HM, Wu LQ, Bentley WE, Ghodssi R, Rubloff GW, Culver JN (2005) Biomacromolecules 6:2881CrossRef

142.

Lee JA, Yun JY, Lee SS, Lee KC (2006) Key Eng Mater 326–328:1359CrossRef

143.

Xu Y, Zhang B, Wu S, Xia Y (2009) Anal Chim Acta 649:117CrossRef

144.

Fasano M, Bergamasco B, Lopiano L (2006) J Neurochem 96:909CrossRef

145.

Pei J, Tian F, Thundat T (2004) Anal Chem 76:292CrossRef

146.

Subramanian A, Oden PI, Kennel SJ, Jacobson KB, Warmack RJ, Thundat T, Doktycz MJ (2002) Appl Phys Lett 81:385CrossRef

147.

Chen T, Chang DP, Liu T, Desikan R, Datar R, Thundat T, Berger R, Zauscher S (2010) J Mater Chem 20:3391CrossRef

148.

Yan X, Xu KX, Ji H-F (2005) Anal Chem 77:6197CrossRef

Titel: Microcantilever Sensors: Electrochemical Aspects and Biomedical Applications
verfasst von: Lana Norman
Garima Thakur
Thomas Thundat
Verlag: Springer US
Buch: Biomedical Applications
Print ISBN: 978-1-4614-3124-4

Electronic ISBN: 978-1-4614-3125-1

Copyright-Jahr: 2012
DOI: https://doi.org/10.1007/978-1-4614-3125-1_4

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