Abstract. The electrochemical properties of three structurally different flavonoids ((+)-catechin, quercetin and rutin) on a glassy carbon electrode were studied at different pH by cyclic, differential pulse and square-wave voltammetry. It was determined that in all investigated compounds oxidation of catechol 3',4'-dihydroxy group on the B-ring (the first oxidation peak) occurs. This process is reversible, pH dependent and includes the transfer of 2e^sup -^ and 2H^sup +^. The products of electrochemical oxidation of all investigated flavonoids (especially of quercetin) strongly adsorb on the electrode surface. In terms of quantification, the absorbance value, proportional to the remaining ABTS+* concentration, is measured after a fixed reaction time. Results are expressed as Trolox equivalents (TEAC value), that is, as the concentration of Trolox solution (mmol dm^sup -3^) with an antioxidant capacity equivalent to that found for 1.0 mmol dm^sup -3^ of the substance under investigation. It was found that the TEAC values depend on the concentration of the investigated compounds. The activity sequence of the investigated, structurally different, flavonoids follows the sequence: quercetin > (+)-catechin > rutin.
Keywords: flavonoids, electrochemistry, oxidation, antioxidant properties, TEAC assay
(ProQuest: ... denotes formula omitted.)
INTRODUCTION
Flavonoids are a class of secondary plant phenolics consisting of fifteen carbon atoms, arranged in a C^sub 6^-C^sub 3^- C^sub 6^ configuration. More than 5000 flavonoids have been identified up to date, they have been mostly found in leaves, seeds, bark and flowers of plants, where they have a protective role against ultraviolet radiation, pathogens and herbivors.1,2 The anthocyanin copigments, which attract pollinating insects, are responsible for the characteristic red and blue colours of berries, wines and certain vegetables (major sources of flavonoids in human diet). Most of the beneficial health effects of flavonoids (anti-inflammatory, anti-cancer, cardio protective) are attributed to their antioxidant and chelating abilities.3
In the last two decades flavonoids were studied by different techniques. Electrochemical properties of flavonoids were studied by voltammetric techniques (cyclic voltammetry,4-8,10-18,21-38,42 differential pulse voltammetry, 5,8,12-15,23-25,27,29,31,37,41 square wave voltammetry, 5,12,14,26,29,38 linear sweep voltammetry,8,25,31,39,40 chronocoulometry,30,42 chronoamperometry17 AC impedance spectroscopy20 and rotating disk electrode voltammetry16,17), UV-spectroelectrochemistry,25,34 semiempirical calculations4 and biosensors.9,12 Antioxidant capacity of flavonoids was studied by cyclic voltammetry, 19,43-45 differential pulse voltammetry,46 Flow Injection Analysis (FIA),47,48 chronoamperometry,49 biosensors,50 UV/Vis spectroscopy (with different reagents e.g. Folin-Ciocalteau,19,50 FRAP,43,51 DPPH,19,49,52 ABTS,19,50-52 etc.), photochemiluminescence19, spectrofluorimetry (ORAC method)50,52 and electron spin resonance (ESR) spectroscopy39.
The structure of flavonoids is a key determinant of their radical scavenging and metal chelating activity, which is referred to as the structure-activity relationship (SAR). Some of the structural features and nature of substitutions on rings B and C which determine the antioxidant activity of flavonoids include the following: a) the degree of hydroxylation and the positions of the -OH groups in the B ring, in particular an orthodihydroxyl structure of ring B (catechol group) results in a higher activity; b) a double bond between C-2 and C-3, combined with a 3-OH, in ring C, enhances the active radical scavenging capacity of flavonoids; c) substitution of the 3-OH in ring C results in increase in torsion angle and loss of coplanarity, which subsequently reduces antioxidant activity and d) a double bond between C-2 and C-3, conjugated with the 4-oxo group in ring C also enhances the radical scavenging capacity of flavonoids.1
Since the chemical activities of flavonoids in terms of their reducing properties as hydrogen or electron- donating agents could predict their potential to act as antioxidants (lower oxidation potential points to a higher antioxidant activity),53 studying of electrochemical and antioxidant properties could help to better understand the mentioned group of compounds.
The purpose of this study was to show application of electrochemical methods (cyclic, differential pulse and square-wave voltammetry) in systematic investigation of electrochemical properties of three structurally different flavonoids (Figure 1), one flavanol ((+)-catechin) and two flavonols (rutin and quercetin) and to determine the antioxidant capacities of the investigated compounds by a Trolox equivalent antioxidant capacity (TEAC) assay.
EXPERIMENTAL
All chemicals were of the highest purity commercially available and were used without further purification. Rutin trihydrate (C^sub 27^H^sub 30^O^sub 16^*3H^sub 2^O), Quercetin dihydrate (C^sub 15^H^sub 10^O^sub 7^*2H^sub 2^O), (+)-Catechin hydrate (C^sub 15^H^sub 14^O^sub 6^ -H2O) and 2,2'-Azinobis (3-ethylbenzothiazoline-6-sulfonic acid) diammonium salt (ABTS) were obtained from Sigma (St. Louis, MO, SAD). (±)-6-Hydroxy-2,5,7,8- tetramethylchroman-2-carboxylic acid (Trolox) was purchased from Fluka (Buchs, Switzerland). All other chemicals were obtained from Kemika (Zagreb, Croatia). Stock solutions of investigated flavonoids (c = 1.10^sup -2^ mol dm^sup -3^) were prepared in methanol and kept in the refrigerator (solutions were stable for at least 1 month). Prior to use, stock solutions were diluted to the desired concentration with a buffer supporting electrolyte (I^sub c^ = 0.1 mol dm^sup -3^). Buffer supporting electrolyte solutions were prepared in high-purity water from a Millipore Milli-Q system (resistivity greater than or equal to 18 MW cm). A phosphate buffer solution of pH = 8.0 and 7.0, and an acetate buffer solution of pH = 5.5, 4.5 and 3.5 were used.
The electrochemical experiments were preformed with an EG & G Princeton Applied Research Model 273A potentiostat controlled by a computer in a threeelectrode system, consisting of a glassy carbon working electrode (Bioanalytical System, d = 3 mm), a saturated calomel reference electrode (S.C.E.) and a platinum counter electrode. The glassy carbon working electrode was polished with -Al2O3 powder (0.05 -m, Buehler, USA) before each measurement. The cyclic voltammetry scan rate was 50 mV/s. The differential pulse voltammetry conditions were: scan increment 5 mV, pulse amplitude 50 mV, pulse width 70 ms and scan rate 5 mV/s. The applied square-wave voltammetry conditions used were: frequency 50 Hz, pulse amplitude 50 mV and scan increment 2 mV (effective scan rate of 100 mV/s).
Antioxidant properties of investigated flavonoids were studied by a Trolox equivalent antioxidant capacity (TEAC) decolourisation assay (the procedure was taken from Ivekovi- et al.)47 on J. P. Selecta UV/Vis spectrophotometer Model UV 2005. A stock solution of ABTS radical cation was prepared by mixing 0.2 ml ammonium peroxodisulfate solution (c = 65 mmol dm^sup -3^) with 50 ml of ABTS solution (c =1 mmol dm^sup -3^) in a phosphate buffer (I^sub c^ = 0.1 mol dm^sup -3^ NaH2PO4, pH = 7.40). The mixture was left to stand overnight. A 0.5 ml of ABTS radical cation stock solution was put into a 1 cm glass cuvette, diluted with 2 ml of phosphate buffer and the absorbance of the ABTS radical cation at 734 nm was read. Subsequently, a 0.1 ml of sample solution was added into the cuvette, the solution was quickly mixed and the absorbance was monitored at 734 nm for 60 s. The decrease of absorbance after 60 s (ΔA sample) was compared with the decrease of absorbance caused by the addition of 0.1 ml of Trolox solution (c = 400 -mol dm^sup -3^) (ΔA ^sub Trolox^) and the TEAC value was calculated according to the formula:47
...
The pH measurements were carried out at the room temperature with the Metrel MA 5736 pH-meter.
RESULTS AND DISCUSSION
Cyclic Voltammetry
Cyclic voltammograms of (+)-catechin (Table 1a), quercetin (Table 1b) and rutin (Table 1c) (c = 1.10^sup -5^ mol dm^sup -3^) were recorded in the buffer solutions (Ic = 0.1 mol dm^sup -3^) in the pH range from pH = 3.5 to pH = 8.0. An example of their cyclic voltammograms recorded at pH = 5.5 is shown in Figure 2. Cyclic voltammetry of (+)-catechin showed two oxidation peaks associated with the oxidation centres present in the molecule, a reversible oxidation peak (E^sub p,a,1^ = 0.339 V) which corresponds to the oxidation of the 3',4'-dihydroxy substituent on the B-ring and an irreversible oxidation peak (E^sub p,a,2^ = 0.715 V),4,5,8 which some authors associate with the oxidation of OH group at the position 3 on the C ring5 and other with the oxidation of 5,7-dihydroxy substituent on the A ring.4,8 The reduction peak of the 3',4'-diquinone formed in the first oxidation peak appeared at E^sub p,c^ = 0.147 V.4,5,8 The peak separation is ,?Ep = E^sub p,a^ - E^sub p,c^ = 192 mV which agrees with some literature data.8 Somewhat high peak separation value could point to the EC oxidation mechanism, which includes reversible electrochemical oxidation of (+)-catechin to o-quinon followed by a chemical reaction of catechin's oxidation products.
Cyclic voltammograms of rutin and quercetin have shown one reversible oxidation peak for rutin (E^sub p,a^ = 0.318 V) and quercetin (E^sub p,a^ = 0.248 V), which corresponds to the oxidation of the 3',4'-dihydroxy substituent on the B-ring. The reduction peak of the 3',4'-diquinone formed during the rutin or quercetin oxidation process, appeared at E^sub p,c^ = 0.281 V for rutin and at E^sub p,c^ = 0.218 V for quercetin. The peak separation is ΔE^sub p^ = E^sub p,a^ - E^sub p,c^ = 37 mV for rutin and 32 mV for quercetin, which points to a reversible electrode reaction involving two electrons on the glassy carbon electro-de.14,16,25,29,31,33,41
Results of this method show structural differences of the investigated flavonoids, since different values of oxidation (E^sub p,a^) and reduction (E^sub p,c^) peak potentials were observed, which can also be connected with their different antioxidant activities (lower oxidation potential points to the higher antioxidant activity).53
Differential Pulse Voltammetry
Differential-pulse voltammetry was used for the investigation of oxidation peak current (I^sub p^) as a function of pH (from pH = 3.5 to pH = 8.0) and to study the adsorption of the investigated compounds on the glassy carbon electrode. As is shown in Table 2, the highest peak current of the first oxidation peak was around pH = 4.5 (for (+)-catechin) and around pH = 5.5 (for rutin and quercetin) and it decreased in more acidic and alkaline media. Oxidation peak potentials for all investigated compounds decreased with an increase of pH.
The plot of the peak potential (Ep) vs. pH for the first oxidation peak showed linearity with the slope 58.7 mV (for (+)-catechin), 73.1 mV (for quercetin) and 60.6 mV (for rutin), which corresponds to the mechanism involving the same number of protons and electrons and agrees with data found in literature.4,5,14,16,25,29,31,33,37,41,42 The plot of the peak potential (Ep) vs. pH for the second oxidation peak of (+)-catechin showed linearity with the slope 63.3 mV which agrees with literature data5 and also points to the oxidation mechanism which involves the exchange of the same number of protons and electrons.
Differential pulse voltammetry revealed a second oxidation peak of rutin and quercetin around 0.9 V which corresponds to oxidation of 5,7-dihydroxyl group on the A-ring and agrees with literature data.14,16,25,29 Both peaks of rutin, quercetin and (+)-catechin decreased with successive scans (Figure 3) for all pH values studied, which confirmed adsorption of their oxidation products on the glassy carbon electrode surface (the decrease of the oxidation peaks in the second scan was the most visible for quercetin, which confirms that the products of quercetin oxidation block the electrode surface and agrees with literature data).14 Even though, two other oxidation peaks of quercetin, peak 2 around 0.3 V (vs. Ag/AgCl), which corresponds to oxidation of 3-OH group at ring C and peak 3 around 0.6 V (vs. Ag/AgCl), which corresponds to oxidation of 5-OH group at ring A, were found by Brett et all,14 those peaks were not observed in our study at any pH value. The oxidation products of investigated flavonoids can also undergo homogenous chemical reactions with water following their oxidation at a glassy carbon electrode. 5,14,29,31
Dissociation diagrams of (+)-catechin, quercetin and rutin (Figures 4-6), calculated from their microscopic dissociation constants deduced from NMR measurements for (+)-catechin54 (pK^sub a3'^ = 9.02; pK^sub a4'^ = 9.12; pK^sub a5^ = 9.43 and pK^sub a7^ = 9.58) and from potentiometry and spectrophotometry for quercetin55 (pK^sub a3'^ = 6.74; pK^sub a4'^ = 9.02 and pK^sub a5^,7 = 11.55) and rutin56 (pK^sub a7^ = 7.35; pKa4' = 8.80; pKa3' = 11.04 and pKa5 = 11.90) show that their spontaneous deprotonation doesn't occur below pH = 6 for (+)-catechin (the similar result was obtained by Martinez et al.)4 and below pH = 5 for quercetin and rutin. It means that the neutral molecules of the investigated flavonoids participate in an electrochemical oxidation reaction and adsorption processes up to pH = 6 for (+)-catechin and up to pH = 5 for quercetin and rutin. At higher pH values, spontaneous deprotonation of flavonoids occur, different dissociated species of (+)- catechin, quercetin and rutin are formed and the possibility of occurrence of much more complex electrochemical and adsorption processes exists, which agrees with the results of Martinez et al.4 for (+)-catechin (they assumed the possibility of occurrence of electron or hydrogen abstraction reactions of catechin in the range of physiological pH).
Square-Wave Voltammetry
Square-wave voltammograms were recorded over the same pH interval (Table 3) investigated by cyclic voltammetry and differential-pulse voltammetry. The results have confirmed adsorption of oxidation products of investigated flavonoids on the electrode surface since the oxidation peak currents decreased with increasing scan number. The advantage of this method compared to differential pulse and cyclic voltammetry lies in greater speed of analysis, lower consumption of electroactive species and reduced problems with blocking of the electrode surface (the current is sampled in positive and negative- going pulses, so the oxidation and reduction peaks of electroactive species can be obtained at the same time). The reversibility of the first oxidation peak of (+)- catechin, quercetin and rutin was confirmed since both the oxidation (forward current) and reduction (backward current) peaks appeared at the same potential, E^sub p^ = 0.34 V for (+)-catechin (at pH = 4.5), E^sub p^ = 0.25 V for quercetin (at pH =5.5) and Ep = 0.33 V for rutin (at pH =5.5) (Figure 7). The square-wave voltammograms have confirmed the irreversibility of the second oxidation peak of (+)-catechin, since there was no corresponding reduction peak in the investigated pH interval.
A possible oxidation mechanism of (+)-catechin, which corresponds to the oxidation of 3',4'-dihydroxy substituent on the B-ring and includes transfer of two electrons and two protons is given in Figure 8. The mechanism involves ionization of (+)-catechin, losing a proton to give the monoanionic species followed by a one electron, one proton oxidation of the monoanionic species to form a radical anion. This then undergoes a second reversible one-electron oxidation to give dehydro- form of (+)-catechin. The latter species is rapidly protonated and then dehydrated to yield the final product o-quinone.4,5,8
The mentioned oxidation mechanism is pH dependent (the highest oxidation peak current was obtained around pH= 4.5). According to some authors,4 at lower pH values the first oxidation step of (+)-catechin follows the eH mechanism (neutral molecule of (+)- catechin losses one electron first and after that one proton). At higher pH values (pH = 7.4) the first oxidation step follows two parallel reaction paths, - the eH mechanism (phenol/radical cation/phenoxyl radical) and the He mechanism (phenol/phenolat anion/phenoxyl radical). The second oxidation step of (+)-catechin follows the He mechanism (neutral molecule of (+)- catechin losses one proton and after that one electron). The coproportionation reaction between o-quinone and (+)-catechine is also possible, which leads to a semiquinonic radical, which is able to give an electroinactive dimer.8
The second irreversible oxidation peak of (+)- catechin which some authors associate with the oxidation of OH group at the position 3 on the C ring5 and other with the oxidation of 5,7-dihydroxy substituent on the A ring,4,8 also includes transfer of two protons and two electrons. The final oxidation product is a catechin polymer which is the result of head to tail polymerization mechanism (repeated condensation reactions between the A-ring of one unit and the B-ring of another unit).8
A possible oxidation mechanism of quercetin and rutin, which corresponds to the oxidation of 3',4'- dihydroxy substituent on the B-ring and includes transfer of two electrons and protons is given in Figure 8. The mechanism involves ionization of quercetin /rutin, losing a proton to give the monoanionic species followed by a one electron, one proton oxidation of the monoanionic species to form a radical anion. This then undergoes a second reversible one-electron oxidation to give dehydro-form of quercetin/rutin. The latter species is rapidly protonated and then dehydrated to yield the final product o-quinone14,27 and in the quercetin oxidation mechanism semi-quinone and p-quinone methide could also be formed27 (it was found that quercetin/rutin and their oxidation products are both adsorbed on the electrode surface).14,29,31,33,23 Quercetin can react as a nucleofil with its oxidation product quercetin-o-quinone to form a dimer17 and can be degraded by air oxygen to produce relatively smaller phenolic acids or 3,4- dihydroxy and 2,4,6-trihydroxyphenylglyoxylic acid.27 The oxidation mechanism is pH dependent and the optimal pH value for the oxidation process of both flavonoids was found to be around pH=5.5 which agrees with data found in literature.15,41 The second oxidation peak of quercetin and rutin found in differential pulse voltammograms, which corresponds to the oxidation of 5,7- dihydroxy group on the A-ring is an irreversible oxidation process.16,29,37
TEAC assay
In this study, the antioxidant capacities of (+)-catechin, quercetin and rutin solutions of different concentrations, expressed as Trolox equivalents, were determined by the classic TEAC decolourisation assay. It was found that TEAC values of all investigated compounds are concentration dependent (Figure 9), which agrees with data found in literature.57 Due to the concentration dependency of the TEAC values of investigated compounds, the TEAC values measured at concentration, c = 100 ?mol dm^sup -3^ were used for comparison and they amounted to: 3.42 for quercetin, 2.95 for (+)-catechin and 2.87 for rutin. Since a higher TEAC value points to a higher antioxidant capacity, it can be concluded that quercetin has the highest antioxidant capacity followed by (+)-catechin and rutin. The TEAC assay gave the same relative order of antioxidant capacities of investigated flavonoids as obtained by cyclic voltammetry, since a lower half-wave potential value (E1/2) of the first oxidation wave, also points to the higher antioxidant capacity53 (quercetin has the lowest E1/2 values (Table 1b), followed by (+)-catechin (Table 1a) and rutin (Table 1c). The obtained results also agree with data found in literature.21,43,44,47,51
Different antioxidant capacities of investigated flavonoids, obtained in this study, can be explained by their structural differences. Antioxidant activity of (+)- catechin, quercetin and rutin can be ascribed to common 3',4'-catechol structure of the B-ring, which indicates a higher antioxidant activity (during the oxidation process on the B-ring of a flavonoid molecule, o-semiquinone radical is formed, which is a good antioxidant). Different antioxidant capacities can be explained by the presence of a double bond between C-2 and C-3, conjugated with the 4-oxo group in the ring C (present in quercetin and rutin molecules), as well as with the presence of 3- OH group in ring C (present in quercetin molecule) which enhance the radical scavenging capacity of flavonoids. Lower antioxidant capacity of rutin compared to quercetin and (+)-catechin can be explained by a lower number of -OH groups in a rutin molecule (quercetin and (+)-catechin have five -OH groups and rutin has four) and by supstitution of 3-OH in ring C with rutinose, which increases the steric tension and reduces the antioxidant activity. Higher antioxidant capacity of quercetin compared to (+)-catechin, can be explained by the presence of a double bond between C- 2 and C-3, conjugated with the 4-oxo group in ring C in a quercetin molecule which enhances its antioxidant activity.58,59
CONCLUSIONS
The results of this study have shown that the electrochemical oxidation of (+)-catechin, quercetin and rutin on a glassy carbon electrode, which corresponds to oxidation of 3',4'-dihydroxy substituent on the B-ring (the first oxidation peak), is pH dependent, includes the transfer of two electrons and two protons and that the oxidation products of all flavonoids studied are strongly adsorbed on the electrode surface. Peak current dependence on pH revealed the maximum at around pH = 4.5 for (+)-catechin and pH = 5.5 for quercetin and rutin (it decreased in more acidic and alkaline media). Structural differences of the investigated flavonoids were shown through obtained different values of their oxidation and reduction potentials. TEAC assay results have shown that the TEAC values of all three investigated compounds are concentration dependent. The activity sequence of the investigated, structurally different, flavonoids is: quercetin > (+)-catechin > rutin.
SAZETAK
Elektrokemijska i antioksidacijska svojstva (+)-katehina, kvercetina i rutina
Martina Medvidovic-Kosanovic, Marijan seruga, Lidija Jakobek i Ivana Novak
Zavod za primijenjenu kemiju i ekologiju, Prehrambeno-tehnoloski fakultet, Sveuciliste J. J. Strossmayera u Osijeku, Kuhaceva 18, P.O. Box 709, HR-31000 Osijek, Hrvatska
Istrazivana su elektrokemijska svojstva tri strukturno razlicita flavonoida ((+)-katehina, kvercetina i rutina) na elektrodi od staklastog ugljika, pri razlicitim pH vrijednostima, uporabom ciklicke, diferencijalne pulsne i pravokutnovalne voltametrije. Utvrceno je da se u svim istrazivanim spojevima oksidira kateholna 3',4'-dihidroksilna skupina na B-prstenu (prvi oksidacijski pik). Taj proces je reverzibilan, ovisi o pH i ukljucuje izmjenu 2e^sup -^ i 2H^sup +^. Produkti elektrokemijske oksidacije svih ispitivanih flavonoida (osobito kvercetina) se snazno adsorbiraju na elektrodnu povrsinu. U terminima kvantifikacije, vrijednost apsorbancije, proporcionalna koncentraciji preostalog ABTS+*, mjerena je nakon konstantnog vemena reakcije. Rezultati su izrazeni kao ekvivalenti Troloksa (TEAC vrijednost), tj. kao koncentracija otopine Troloksa (mmol dm^sup -3^), koja ima antioksidacijski kapacitet ekvivalentan vrijednosti odrecenoj za 1.0 mmol dm^sup -3^ ispitivane tvari. Utvrceno je da TEAC vrijednosti ovise o koncentraciji istrazivanih spojeva. Aktivnosni slijed ispitivanih, strukturno razlicitih, flavonoida slijedi niz: kvercetin > (+)- katehin > rutin.
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Martina Medvidovic-Kosanovic,* Marijan Seruga, Lidija Jakobek, and Ivana Novak
Department of Applied Chemistry and Ecology, Faculty of Food Technology, J. J. Strossmayer University of Osijek,
Kuhaceva 18, P.O. Box 709, HR-31000 Osijek, Croatia
RECEIVED JANUARY 28, 2009; REVISED JULY 22, 2009; ACCEPTED DECEMBER 14, 2009
* Author to whom correspondence should be addressed. (E-mail: [email protected])
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Copyright Croatica Chemica Acta, Croatian Chemical Society 2010
Abstract
The electrochemical properties of three structurally different flavonoids ((+)-catechin, quercetin and rutin) on a glassy carbon electrode were studied at different pH by cyclic, differential pulse and square-wave voltammetry. It was determined that in all investigated compounds oxidation of catechol 3',4'-dihydroxy group on the B-ring (the first oxidation peak) occurs. This process is reversible, pH dependent and includes the transfer of 2e^sup -^ and 2H^sup +^. The products of electrochemical oxidation of all investigated flavonoids (especially of quercetin) strongly adsorb on the electrode surface. In terms of quantification, the absorbance value, proportional to the remaining ABTS+* concentration, is measured after a fixed reaction time. Results are expressed as Trolox equivalents (TEAC value), that is, as the concentration of Trolox solution (mmol dm^sup -3^) with an antioxidant capacity equivalent to that found for 1.0 mmol dm^sup -3^ of the substance under investigation. It was found that the TEAC values depend on the concentration of the investigated compounds. The activity sequence of the investigated, structurally different, flavonoids follows the sequence: quercetin > (+)-catechin > rutin. [PUBLICATION ABSTRACT]
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Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer