Nov 12, 2014 - One of the important successes of potentiometric techniques was achieved with a biomolecule (valinomycin) as a recognition element around ...
Nov 12, 2014 - Centre of Medical Genetics, Department of Biomedical Sciences, University of Antwerp, Universiteitsplein 1, 2610 Antwerp,. Belgium.
Nov 12, 2014 - Centre of Medical Genetics, Department of Biomedical Sciences, University of Antwerp, Universiteitsplein 1, 2610 Antwerp,. Belgium.
for the potential of the indicator electrode, and the equi- ... same cell will be zero in the titration of ... detect the end point, which is marked by zero difference of.
Potentiometric titrations and poten- tiometry were reviewed by Banick (15),. Gross and Murray (88), and Hilton. (105). Acid-base titrations and pH measurements ...
Royce W. Murray and Charles N. Reilley, Department of Chemistry, University of North Carolina, Chapel Hill, N. C.. This ... Bates and Guggenheim (17) have.
.MA, registers some arbitrary convenient value, say 1.4. The switch is returned to position m and the voltage divider, D, is moved until the milliammeter again ...
through the literature reported in. Chemical Abstracts through November. 20,1967. Potentiometric titrations and poten- tiometry were reviewed by Banick (15),.
(1241 Spandau, H., and Brunneck, E., Z. anorg. u. allgem. Chem.,. 270, 201 (1952). (125) Stewart,T. D., and Cook, V., J. Am. Chem. Soc., 50, 1973. (1928).
Automatic Differential Potentiometric Titrations. Electrode Systems for Aqueous and Nonaqueous Titrations . V. MALMSTADT and E. R. FETT. Noyes Chemistry ...
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Article
Concentration Related Response Potentiometric Titrations to Study the Interaction of Small Molecules with Large Biomolecules Ezat Hamidi-Asl, Devin Daems, Karolien De Wael, Guy Van Camp, and Luc Jozef Nagels Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/ac503385x • Publication Date (Web): 12 Nov 2014 Downloaded from http://pubs.acs.org on November 17, 2014
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The 25-mer-DNA and random primers were obtained from Integrated DNA Technologies
137
(IDT, Gent, Belgium) and the others from Eurogentec (Liège, Belgium).
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2.3. Instrumentation
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Potentiometric working electrodes. The indicator electrode was made of a PVC cylinder (5
141
mm OD × 40 mm length). It contained a cylindrical substrate electrode (3 mm diameter × 1
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mm length), which is an electronically conducting graphite/PVC composite material.30 The
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composite substrate electrode was polished with Carbimet grit 600 (Buehler Ltd, USA). The
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rubber phase sensing membrane was coated on the composite substrate electrode. The
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electrodes with a composite substrate had the important property that the coated membrane
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and the composite were tightly mixed at the interface.31
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The membrane coating used for the detection of positively charged analytes contained 2%
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(w/w) TCPB, 33% (w/w) PVC and 65% (w/w) NPOE. 100 mg of this mixture was dissolved
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in 1mL THF and 2 × 40 µL of this solution were applied on the electrode surface (dip-coating)
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by 2 sequential steps. After evaporation at room temperature (1 h), the resulting ionically
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conductive rubber polymeric phase coated membrane had a thickness of 100 µm. The
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electrodes were kept in buffer solution (1mM MES pH 7.0) for at least 3 h to obtain a stable
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baseline for the potentiometric titration.
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Potentiometric setup. The potentiometric titrations were performed using an indicator
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electrode and a reference electrode, in a 10 mm diameter beaker. The buffer solution (1 mM
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MES pH 7.0) was stirred during the entire experiment with a magnetic stirrer (5 × 2 mm).
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After obtaining a stable baseline, the first injection was done by addition of the analyte (5 µL)
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to 500 µL of the buffer solution. Always, an exponential increase in potential could be seen in
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this step, reaching a plateau value. After obtaining a stable signal, the titrant was added using
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a micropipette at constant time intervals. The usual volume of the titrant was 8 µL and
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pipetting was done every 30 s, unless otherwise stated. The membrane potential was measured
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against an homemade miniaturized (1.4 mm OD × 40 mm length) reference electrode
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(Ag/AgCl) using a high impedance (1013 Ω) homemade amplifier. The detection signals were
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recorded on a data station composed of a PC equipped with a 6013 NI DA converter and
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LabVIEW 7 (National Instruments, US) based software. The overall time constant of the high
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impedance amplifier plus data station was set to 200 ms. All the measurements were done at
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least three times on three different working electrodes after conditioning and stabilization in
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the MES buffer solution. 6 ACS Paragon Plus Environment
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Page 7 of 20
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3. Results and Discussion
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3.1. Potentiometric detection of cocaine in a batch system Figure 1A shows the potentiometric signal obtained after injecting different concentrations of
Figure 1: Potentiometric signals in batch for cocaine. (A) Typical potentiometric recordings in batch after cocaine injection. The concentration of cocaine varied from 10-7 M (curve a) to 10-6.5 M (b), 10-6 M (c), 10-5.5 M (d), 10-5 M (e), 10-4.5 M (f) and 10-4 M (g) in 1 mM MES buffer (pH: 7.0). (B) Potentiometric responses of 10-5 to 10-8M cocaine injections in relation to log concentration. The measured potentiometric responses in figure 1A (◊) and equation 1 fitted by “Solver” (red curve) are shown. (C) Potentiometric responses of 10-7 to 10-5M cocaine injections after transformation to a concentration related signal (see also Eqn. 3). Insert: Cocaine concentrations from 10-8 to 10-6M.
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The potentiometric indicator electrode used was of the coated wire type, containing TCPB as
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an ionophore. Some initial spiking phenomena are observed (figure 1A) as we inject in a
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miniaturized (500 µL) system equipped with a large indicator electrode. The signal heights at
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the plateau values plotted versus the logarithm of the analyte concentrations follow calibration
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curves of the type shown in figure 1B and expressed by Eqn. 1: 7 ACS Paragon Plus Environment
Figure 2: Potentiometric titration of 10-5M cocaine in 500 µL MES buffer 1 mM with 5 µL additions of 10-4 M concentrations of respectively TCPB (a) and CBA (b) every 30 s.
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As shown in table 1, the obtained Ka values using either the “Equivalence Point Method”
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(Eqn. 4) or the “Post-EP Method” (Eqn. 6) both are in the 109 M-1 range for TCPB. ∆G0
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values are completely comparable as calculated by the two suggested methods. Similar results
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were obtained for potentiometric titrations of cocaine with CBA, yielding a ∆G value of 8.6 ±
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0.1 kcal mol-1 with the EP Method and 8.0 ± 0.1 kcal mol-1 with the PEP Method.
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Table 1: Comparison of the potentiometric titration of cocaine with TCPB between the two suggested methods based on the Equivalence Point (EP) and Post-EP (PEP). Mean values (n = number of different electrodes tested) of Ka and ∆G values are presented.
Method Ka (M-1)
∆G0 (kcal mol-1) n
EP
3.4 × 109
12.8 ± 0.2
3
PEP
9.0 × 109
13.3± 0.1
3
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All the results given later in this work are calculated with the “Post-EP Method”, because the
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latter method is much more suited for working in biomolecular conditions. These conditions
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include firstly the µg availability of biocomponents at high cost, leading to small numbers of 11 ACS Paragon Plus Environment
Figure 3: Potentiometric titration of cocaine with different titrants.(A): Potentiometric titration of 10-5M cocaine in 500 µL 1 mM MES buffer with 8 µL injections of 10-4 M CBA (curve a), CAPBA (b), 34-mer-RP (c) and 25-mer-DNA (d) every 30 s. (B): Association constants (Ka) of cocaine with CBA (a), CAPBA (b), 43-mer-RP (c) and 25-mer-DNA (d) and anti-cocaine antibody (e, see insert). Standard deviations are show in the histogram (with n = 6 different electrodes tested for a and n = 3 for b, c, d and e).
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Because CBA had 43 bases, a 43-mer-RP was chosen for the investigation of the selectivity.
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In the series of titrants, the CAPBA has the second largest response, followed by the 43-mer-
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RP and the 25-mer-DNA. Therefore, the 43-mer-RP and the 25-mer-DNA have little or no
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specific interaction with cocaine. This illustrates that the synthesized aptamer for cocaine has
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good recognition properties for its target, as shown by Hilton et al.28
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The calculated association constants for interaction between cocaine and different titrants
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shown in figure 3B are: 960 × 103 M-1 for CBA, 47 × 103 M-1 for CAPBA, 93 × 103 M-1 for
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the 43-mer-RP and 24 × 103 M-1 for the 25-mer-DNA, respectively. The calculated Kd for
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CBA in our approach (1.1 ± 0. 2) × 10-6 M (n = 6, n is the number of different electrodes
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tested) is in good agreement with the reported value for Kd (between 0.4 and 10 µM) in the
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paper describing the synthesis of this CBA.38 These Ka values correspond with a ∆G of 8.0 ±
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0.1 kcal mol-1 (n = 6). The results show that we can use this new potentiometric titration
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approach for fast evaluation of newly synthesized aptamers at low-cost and low biomolecule
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expenditure. It is also interesting to note that CBA had a Ka value around 106 M-1, as
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compared to a Ka value of around 1010 M-1 for TCPB (see above results). This would mean
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that this aptamer receptor molecule could not yet compete with TCPB for e.g. use in
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potentiometric sensors. TCPB, with its negative charge and stongly lipophilic character,
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clearly has a strong interaction (high Ka value) with positively charged lipophilic analyte 13 ACS Paragon Plus Environment
Figure 4: Potentiometric titration of different analytes with CBA. (A): Potentiometric titration of 10-5 M solutions of cocaine (a), metergoline (b), bromhexine (c) and lidocaine (d) in 500 µL 1 mM MES buffer with 8 µL 10-4 M CBA every 30 s. Y-axis units are normalized. (B): Association constants (Ka) of cocaine (a), metergoline (b), bromhexine (c) and lidocaine (d) with CBA. Standard deviations are shown in the histogram with n = 6 electrodes for a, n = 4 for c, n = 3 for b and d.
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Fig 4B shows the histogram of the Ka values. The selected aptamer has better interaction with
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metergoline than with cocaine. Little is known on the cross-reactivity in the papers describing
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this anti-cocaine aptamer. A strong point of the present study is that such cross-reactivities can
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be studied much faster than with the presently available methods. All calculated Ka and ∆G
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values are summarized in tables 2 and 3.
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Table 2: Titration of a 10-5 M solution of cocaine as an analyte, with of different titrants (8 µL injections of 10-4 M solutions) in 500 µL 1 mM MES buffer pH 7.
Titrant CBA
∆G (kcal mol-1) n Ka (M) 9.6 × 105 8.0 ± 0.1 6
25-mer-DNA
2.4 × 104
5.7 ± 0.3
3
9.3 × 10
4
6.7 ± 0.2
3
4.7 × 10
4
6.3 ± 0.1
3
9.0 × 10
9
13.3 ± 0.1
3
Anti-Coc Antibody 1.4 × 10
6
8.1 ± 0.4
3
43-mer-RP CAP-APT TCPB 394 395
15 ACS Paragon Plus Environment
Analytical Chemistry
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Table 3: Titration of 10-5 M solutions of different analytes with CBA as a titrant (8 µL injections of a 10-4 M solution) in 500 µL 1 mM MES buffer pH 7.
Ka (M) ∆G (kcal mol-1) n 9.6 × 105 8.0 ± 0.1 6
Analyte Cocaine Lidocaine
-
-
3
Metergoline 3.3 × 10
6
8.7 ± 0.1
3
Bromhexine 5.7 × 10
5
7.7 ± 0.1
4
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3.3.4. Titration of metergoline with different oligonucleotides
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The binding constant between metergoline and metergoline binding aptamer (MBA) was also
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studied, and compared to binding with CBA, and with an 80-mer-RP oligonucleotide (figure
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5). The calculated Ka and ∆G values were respectively 4.5 x 107 and 10.2 kcal mol-1 for MBA
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and 3.1 x 106 and 8.74 kcal mol-1 for CBA. No interaction was observed for the 80-mer-RP.
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The MBA shows stronger binding for its metergoline ligand than the other biomolecule/small
Figure 5: Potentiometric titration of metergoline as analyte (10-6 M) with different titrants: MBA (a), CBA (b) and 80mer-RP (c) (5 µL 10-6 M injections) in 500 µL 1 mM MES buffer pH 7.
Robbens, J. Int. J. Mol. Sci. 2012, 13, 17138-17159.
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(30) Mehta, J.; Van Dorst, B.; Rouah-Martin, E.; Herrebout, W.; Scippo, M.-L.; Blust, R.; Robbens, J. J. Biotechnol. 2011, 155, 361-369. (31) Nagels, L. J.; Bohets, H;, Jimidar M. Potentiometric electrode, gradient polymer, uses and method of preparation. U.S. Patent 7,857,962 B2. (32) Daems, D.; Van Camp, G.; Fernandez, M.; Guisez, Y.; Prinsen, E.; Nagels, L. J. Anal.
Chim. Acta 2013, 777, 25-31. (33) Daems, D.; De Wael, K.; Vissenberg, K.; Van Camp, G.; Nagels, L. Biosens. Bioelectron. 2014, 54, 515-520.
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