A Simple, Rapid, and Reliable Titrimetric Method for the Determination of Glycerol at Low Concentration

Santos, Luana O.; Rocha, Sheisi F. L. S.; Barra, Cristina M.; Tubino, Matthieu; Rocha Junior, José G.

doi:10.21577/0103-5053.20220004

Abstract

Glycerol can be determined in several products by various analytical techniques. Titrimetric ones have stood out for their low cost, being recommended as standards. However, reliable, simple, fast, and green methods with low quantification limits are still needed. Titration of glycerol is based on its oxidation by periodate (Malaprade reaction) producing formic acid, formic aldehyde, and iodate. Iodate and periodate are iodometrically titrated, but mutual interference between these ions has produced methods with some drawbacks. Here is proposed to mask periodate with molybdate, to eliminate interference, determining the glycerol content through iodate, employing iodometric titration. Solutions containing from 10 to 1000 µg of glycerol were analyzed (error < 3.4%). The method was successfully applied for the determination of glycerol in biodiesels from different raw materials. Recoveries were from 92.9 ± 0.4 to 111 ± 3%. Semi-micro extraction was done, providing a fast procedure for determining free glycerol in biodiesel (< 10 min).

Keywords:
glycerol; periodate; molybdate; Malaprade; biodiesel

Introduction

Glycerol (1,2,3-propanotriol) is a chemical compound widely employed in cosmetics, pharmaceuticals, detergents, and foods as well as in the manufacture of resins, additives, explosives, papers, and paints.¹1 Faccendini, P. L.; Ribone, M. E.; Lagier, C. M.; Sens. Actuators, B 2014, 193, 142.

2 Arévalo, F. J.; Osuna, Y.; Cortez, J. S.; Di, T. A.; Granero, A. M.; Robledo, S. N.; Zon, M. A.; Vettorazzi, N. R.; Martinez, J. L; Segura, E. P; Iliná, A.; Fernandez, H.; Sens. Actuators, B 2017, 244, 949.-³3 Semkiv, M. V.; Ruchala, J.; Dmytruk, K. V.; Sibirnya, A.; Trends Biotechnol. 2020, 38, 907. Due to this variety of applications, it is important that new, reliable, fast, and low-cost techniques are being developed to quantify glycerol.

The emollient, moisturizing and conditioning action of glycerol makes this compound used mainly in the formulation of cosmetics such as soaps, shower gels, toothpaste, and cream hair. However, its content in cosmetics must be controlled to avoid allergies and severe skin irritations.⁴4 Nanco, C. R.; Poklis, J. L.; Hiler, M. M.; Breland, A. B.; Eissenberg, T.; Wolf, C. E.; J. Anal. Toxicol. 2019, 43, 720.,⁵5 Motia, S.; Bouchikhi, B.; Llobet, E.; El Bari, N.; Talanta 2020, 216, 120953. In food industries, glycerol provides good sensory implications in several beverages, contributing to viscosity, softness, and flavor. Also, due to its properties it is widely used in adulteration of drinks.⁴4 Nanco, C. R.; Poklis, J. L.; Hiler, M. M.; Breland, A. B.; Eissenberg, T.; Wolf, C. E.; J. Anal. Toxicol. 2019, 43, 720.,⁶6 Zhao, X.; Procopio, S.; Becker, T.; J. Food Sci. Technol. 2015, 52, 7588.

7 Bortoletto, A. M.; Corrêa, A. C.; Alcarde, A. R.; J. Inst. Brew. 2016, 122, 293.-⁸8 Lachenmeier, D. W. In Advances in Food Authenticity Testing; Lachenmeier, D. W.; Downey, G., eds.; Woodhead Publishing: Cambridge, UK, 2016, ch. 21. In the beverage industry, the glycerol content is used as an indicator of the quality of fermented alcoholic beverages because it is a co-product of the alcoholic fermentation of sugar.⁹9 Sighinolfi, S.; Baneschi, I.; Manzini, S.; Tassi, L.; Dallai, L.; Marchetti, A.; J. Food Compos. Anal. 2018, 69, 33. From a biological point of view, glycerol acts as a key compound in several metabolic pathways, being determined in blood serum and in urine for the diagnosis of metabolic disorders.⁴4 Nanco, C. R.; Poklis, J. L.; Hiler, M. M.; Breland, A. B.; Eissenberg, T.; Wolf, C. E.; J. Anal. Toxicol. 2019, 43, 720.,¹⁰10 Ramonas, E.; Ratautas, D.; Dagys, M.; Meškys, R.; Kulys, J.; Talanta 2019, 200, 333.

Glycerol is also a co-product of biodiesel synthesis when this biofuel is produced by the transesterification of triglycerides contained in vegetable oils or animal fats.¹¹11 Martins, C. A.; Fernández, P. S.; Camara, G. A. In Increased Biodiesel Efficiency; Martins, C. A.; Fernández, P. S.; Camara, G. A.; Trindade, M., eds.; Springer: Cham, 2018, p. 159.,¹²12 Yaşar, F.; Fuel 2020, 264, 116817. Therefore, it can be present in biodiesel as free glycerol and as bound glycerol (glycerol portion of the mono-, di- and triglyceride molecules). Free and bound glycerol can cause problems in fuel storage tanks, besides clogging and causing deposits in parts of the engine, compromising the combustion process and the performance of the motor.²2 Arévalo, F. J.; Osuna, Y.; Cortez, J. S.; Di, T. A.; Granero, A. M.; Robledo, S. N.; Zon, M. A.; Vettorazzi, N. R.; Martinez, J. L; Segura, E. P; Iliná, A.; Fernandez, H.; Sens. Actuators, B 2017, 244, 949.,¹³13 Chen, W. C.; Li, P. Y.; Chou, C. H.; Chang, J. L.; Zen, J. M.; Electrochim. Acta 2015, 153, 295.

14 ASTM D6584: Standard Test Method for Determination of Total Monoglycerides, Total Diglycerides, Total Triglycerides, and Free and Total Glycerin in B-100 Biodiesel Methyl Esters by Gas Chromatography, West Conshohocken, PA, 2017.-¹⁵15 Eggly, G. M.; Blackhall, M.; de Araújo, A. G.; Santos, R.; de Araújo, M. C. U.; Pistonesi, M. F.; Microchem. J. 2018, 138, 296. To minimize these inconveniences, American Society for Testing and Materials (ASTM), European Committee for Standardization (CEN) and National Agency for Petroleum, Natural Gas and Biofuels (ANP, Brazil) established the limit content of 0.02 g per 100 g of free glycerol in biodiesel, through the resolutions ASTM D6751,¹⁶16 ASTM D6751: Standard Specification for Biodiesel Fuel Blend Stock (B100) for Middle Distillate Fuels, West Conshohocken, PA, 2020. EN 14214¹⁷ and 45/2014 (RANP 45/2014),¹⁸18 ANP: Resolução ANP No. 45, de 25 de Agosto de 2014, Publicada no DOU de 26 de Agosto de 2014, 2014, available at https://atosoficiais.com.br/anp/?q=45%2F2014, accessed in December 2021.
https://atosoficiais.com.br/anp/?q=45%2F... respectively. As for the total glycerol content, Brazilian and European norms establish a maximum limit of 0.25 g per 100 g, while in the United States the stipulated limit was 0.24 g per 100 g.

High performance liquid chromatography (HPLC) and gas chromatography (GC) are techniques widely recommended to determine the content of glycerol in various matrices.⁹9 Sighinolfi, S.; Baneschi, I.; Manzini, S.; Tassi, L.; Dallai, L.; Marchetti, A.; J. Food Compos. Anal. 2018, 69, 33.,¹⁴14 ASTM D6584: Standard Test Method for Determination of Total Monoglycerides, Total Diglycerides, Total Triglycerides, and Free and Total Glycerin in B-100 Biodiesel Methyl Esters by Gas Chromatography, West Conshohocken, PA, 2017.,¹⁹19 Simonzadeh, N.; Ronsen, B.; J. Chromatogr. Sci. 2012, 50, 644.

20 Rainey, C. L.; Shifflett, J. R.; Goodpaster, J. V.; Bezabeh, D. Z.; Contrib. Tob. Res. 2013, 25, 576.

21 AOAC 968.09: Alcohols (Higher) and Ethyl Acetate in Distilled Liquors. Gas Chromatographic Method, Rockville, MD, 1969.

22 AOAC 972.10: Alcohols (Higher) and Ethyl Acetate in Distilled Liquors. Alternative Gas Chromatographic Method, Rockville, MD, 1975.

23 EN 14106: Fat and Oil Derivatives - Fatty Acid Methyl Esters (FAME). Determination of Free Glycerol Content, BSI Group: London, United Kingdom, 2003.

24 EN 14105: Fat and Oil Derivatives - Fatty Acid Methyl Esters (FAME). Determination of Free and Total Glycerol and Mono-, Di-, Triglyceride Contents, BSI Group: London, United Kingdom, 2011.-²⁵25 De, A. K.; Chowdhury, P. P.; Chattopadhyay, S. P.; Adv. Phar. 2015, ID 567032. Chromatographic techniques present high sensitivity, good reproducibility and low limits of detection and quantification for the determination of the content of glycerol.⁵5 Motia, S.; Bouchikhi, B.; Llobet, E.; El Bari, N.; Talanta 2020, 216, 120953. However, they have certain limitations, such as the use of expensive and/or hazardous solvents, reagents, analytical standards, materials, and instrumentation. In addition, the use of GC requires derivatization of glycerol, which increases the time required for analysis.⁵5 Motia, S.; Bouchikhi, B.; Llobet, E.; El Bari, N.; Talanta 2020, 216, 120953.,¹⁰10 Ramonas, E.; Ratautas, D.; Dagys, M.; Meškys, R.; Kulys, J.; Talanta 2019, 200, 333.,²⁶26 Honório, G. G.; Cunha, J. N.; Assis, K. L. S. C.; Aguiar, P. F.; Andrade, D. F.; Souza, C. G.; D’Avila, L. A.; Archanjo, B. S.; Achete, C. A.; Pradelle, R. N. C.; Turkovics, F.; Neto, R. S.; D’Elia, E.; J. Solid State Electrochem. 2019, 23, 3057.,²⁷27 Assis, K. L. S. C.; Archanjo, B. S.; Achete, C. A.; D’Elia, E.; Mater. Res. 2020, 23, e20190513.

Enzymatic determination of glycerol content using different detection systems is an alternative to chromatographic methods.¹1 Faccendini, P. L.; Ribone, M. E.; Lagier, C. M.; Sens. Actuators, B 2014, 193, 142.,²⁸28 Gattas, E. A. L.; Peres, M. F. S.; Br PI 100348-3 2013.

29 Nario, N. A.; Insausti, M.; Domini, C. E.; Crunhut, M.; Energy Fuels 2019, 33, 9925.

30 Goriushkina, T. B.; Shkotova, L. V.; Gayda, G. Z.; Klepach, H. M.; Gonchar, M. V.; Soldatkin, A. P.; Dzyadevych, S. V.; Sens. Actuators, B 2010, 144, 361.

31 Luetkmeyer, T.; Santos, R. M.; Silva, A. B.; Amado, R. S.; Vieira, E. C.; Electroanalysis 2010, 22, 995.

32 Chiles, E.; Wang, Y.; Kalemba, K. M.; Kwon, H.; Wondisford, F. E.; Su, X.; Anal. Biochem. 2019, 575, 40.-³³33 Narwal, V.; Pundir, C. S.; Int. J. Biol. Macromol. 2019, 127, 57. However, despite some advantages of the enzymatic procedure, such as high selectivity and catalytic action, the cost of the enzymes and the loss of their activity are factors to be considered.

Several methods based on the Malaprade reaction (or Malaprade oxidation) have been developed to determine the content of glycerol in different matrices. This reaction involves the cleavage of glycols by the oxidation of the adjacent diols with periodic acid or periodate, in aqueous solution, to give the corresponding carbonyl functional groups.³⁴34 Malaprade, L.; Comptes Rendus 1928, 186, 382.,³⁵35 Zhang, Y.; Zhang, L.; Shao, S.; Chang, X.; Li, M.; ChemistrySelect 2020, 5, 6765. Oxidation of glycerol according to the Malaprade reaction produces formic aldehyde, formic acid, and iodate ion (equation 1). So, glycerol can be indirectly determined through the products of this reaction or by the unreacted periodate ion.⁷7 Bortoletto, A. M.; Corrêa, A. C.; Alcarde, A. R.; J. Inst. Brew. 2016, 122, 293.,¹³13 Chen, W. C.; Li, P. Y.; Chou, C. H.; Chang, J. L.; Zen, J. M.; Electrochim. Acta 2015, 153, 295.,³⁶36 AOAC 942.22: Cosmetics - Vanishing Cream - Glycerol, Washington, DC, USA, 1990.

37 Bondioli, P.; Bella, L.; Eur. J. Lipid Sci. Technol. 2005, 107, 153.

38 Pisarello, M. L.; Costa, B. O. D.; Veizaga, N. S.; Querini, C. A.; Ind. Eng. Chem. Res. 2010, 49, 8935.

39 Lima, M. B.; Insausti, M.; Domini, C. E.; Pistonesi, M. F.; Araújo, M. C. U.; Band, B. S. F.; Talanta 2012, 89, 21.

40 ASTM D7637: Standard Test Method for Determination of Glycerin Assay by Titration (Sodium Meta Periodate), West Conshohocken, PA, 2015.

41 AOCS Ea 6-94: Determination of Crude Glycerin, Titrimetric Method, Urbana, IL, USA, 2017.

42 Ashworth, M. R. F.; Analytical Methods for Glycerol, 1st ed.; Academic Press: New York, USA, 2017.

43 Pisarello, M. L.; Maquirriain, M. A.; Querini, C. A.; Energy Fuels 2018, 32, 8431.

44 Shishov, A.; Trufanov, I.; Nechaeva, D.; Bulatov, A.; Microchem. J. 2019, 150, 104134.

45 Soares, S.; Rocha, F. R.; Talanta 2020, 209, 120584.

46 Tábua, M. C. M.; Santiago, W. D.; Magalhães, M. L.; Ferreira, V. R. F. F.; Brandão, R. M.; Teixeira, M. L.; Pedroso, M. P.; Machado, M. R.; Nelson, D. L.; Cardoso, M. G.; J. Food Sci. Technol. 2020, 57, 505.-⁴⁷47 AOCS Ea 6-51: Glycerol, Sodium Periodate Oxidation Method, Urbana, IL, USA, 2017.

(1)

C_{3} H_{8} O_{3} + 2 {I O}_{4}^{-} \to 2 {C H}_{2} O + {C H}_{2} O_{2} + 2 {I O}_{3}^{-} + H_{2} O

The quantification of glycerol from formic aldehyde is carried out based on the formation of 3,5-diacetyl-1,4 dihydrolutidine produced in the cyclization reaction of formic aldehyde with acetylacetone (Hantzsch reaction). The 3,5-diacetyl-1,4-dihydrolutidine is then determined by spectrophotometry (λ = 410 nm) or by fluorometry (λ = 514 nm).³⁷37 Bondioli, P.; Bella, L.; Eur. J. Lipid Sci. Technol. 2005, 107, 153.,³⁹39 Lima, M. B.; Insausti, M.; Domini, C. E.; Pistonesi, M. F.; Araújo, M. C. U.; Band, B. S. F.; Talanta 2012, 89, 21.,⁴⁵45 Soares, S.; Rocha, F. R.; Talanta 2020, 209, 120584.,⁴⁶46 Tábua, M. C. M.; Santiago, W. D.; Magalhães, M. L.; Ferreira, V. R. F. F.; Brandão, R. M.; Teixeira, M. L.; Pedroso, M. P.; Machado, M. R.; Nelson, D. L.; Cardoso, M. G.; J. Food Sci. Technol. 2020, 57, 505. The toxicity and the low stability of the acetylacetone solution and the long time needed to build the analytical curve are factors that hinder the application of these methods,⁴⁸48 Kang, X. M.; Fan, X. Y.; Hao, P. Y.; Wang, W. M.; Zhao, B.; Inorg. Chem. Front. 2019, 6, 271.,⁴⁹49 Zhou, Y.; Ding, Y.; Gao, W.; Wang, J.; Liu, X.; Xian, M.; Feng, X.; Zhao, G.; Biotechnol. Biofuels 2020, 13, 88. despite using lower cost equipment in comparison to the chromatographic.

Acid-base titration has been used to determine the glycerol content from formic acid produced in the Malaprade oxidation (equation 1).³⁶36 AOAC 942.22: Cosmetics - Vanishing Cream - Glycerol, Washington, DC, USA, 1990.

37 Bondioli, P.; Bella, L.; Eur. J. Lipid Sci. Technol. 2005, 107, 153.-³⁸38 Pisarello, M. L.; Costa, B. O. D.; Veizaga, N. S.; Querini, C. A.; Ind. Eng. Chem. Res. 2010, 49, 8935.,⁴⁰40 ASTM D7637: Standard Test Method for Determination of Glycerin Assay by Titration (Sodium Meta Periodate), West Conshohocken, PA, 2015.,⁴¹41 AOCS Ea 6-94: Determination of Crude Glycerin, Titrimetric Method, Urbana, IL, USA, 2017.,⁴³43 Pisarello, M. L.; Maquirriain, M. A.; Querini, C. A.; Energy Fuels 2018, 32, 8431.,⁴⁷47 AOCS Ea 6-51: Glycerol, Sodium Periodate Oxidation Method, Urbana, IL, USA, 2017. The standard method ASTM D7637⁴⁰ recommends to titrate the formic acid with a standard solution of NaOH and bromothymol blue as indicator. However, this procedure is only applicable to aqueous mixtures with a high glycerol content (above 75% m/m), which limits its application in several matrices. The AOAC 942.22 standard method³⁶36 AOAC 942.22: Cosmetics - Vanishing Cream - Glycerol, Washington, DC, USA, 1990. is recommended to analyze glycerol in a cosmetic (vanishing cream), from which it is separated by partition with acidified water/chloroform. Then, the formic acid produced in the oxidation of glycerol (equation 1) is titrated with a standard aqueous solution of NaOH, using bromocresol purple as indicator. Pisarello et al.⁴³43 Pisarello, M. L.; Maquirriain, M. A.; Querini, C. A.; Energy Fuels 2018, 32, 8431. proposed the determination of free and total glycerol content in biodiesel-diesel blends. After the extraction of glycerol with distilled water the obtained aqueous solution was submitted to a tedious sequence of operations including successive neutralizations. To these boring procedures follows the oxidation with periodate and, then, is necessary to eliminate the excess of this ion using ethylene glycol in order to allow the determination of the formic acid. In general, the methods based on the titration of formic acid require additional steps in the analytical procedure and special care is necessary to avoid the presence of CO₂ into solution.

Quantification of glycerol from the remaining periodate or from the iodate produced in the Malaprade reaction (equation 1) has been performed mainly by iodometric titration. These ions are reduced by the iodide, producing triiodide, according to equations 2 and 3, respectively. Then triiodide is titrated using a standard solution of sodium thiosulfate (equation 4) or of arsenious acid (equation 5) and starch as indicator.

(2)

{I O}_{4}^{-} + 11 I^{-} + 8 H^{+} \to 4 I_{3}^{-} + 4 H_{2} O

(3)

{I O}_{3}^{-} + 8 I^{-} + 6 H^{+} \to 3 I_{3}^{-} + 3 H_{2} O

(4)

2 S_{2} O_{3}^{2 -} + I_{3}^{-} \to 3 I^{-} + S_{4} O_{6}^{2 -}

(5)

H_{3} {A s O}_{3} + 2 {H O}^{-} + I_{3}^{-} \to 3 I^{-} + H_{3} {A s O}_{4} + H_{2} O

For the iodometric quantification of glycerol in biodiesel, oils, and fats through the ABNT NBR 15771⁵⁰ and AOCS Ca 14-56⁵¹ standard methods, the reactions of iodide with the remaining periodate (equation 2) and with the iodate generated in the Malaprade reaction are performed simultaneously (equation 3). The glycerol present in the sample is extracted with an acetic acid aqueous solution or with water. It is then determined by the difference between the volume of the titrant used in the titration of the sample minus that of the blank (solvent). However, the high excess of periodate used in the Malaprade reaction, and the low quantity of iodate produced (due to low glycerol content) can cause a situation in which the difference between the volumes of titrant becomes very small, fact which magnifies the relative titration error. To increase this difference, the ABNT NBR 15771 standard method⁵⁰50 ABNT NBR 15771: Biodiesel - Determinação de Glicerina Livre - Método Volumétrico, Brazil, 2009. recommends the use of a large-scale sample. If this is not enough, re-analyses should be performed using different proportions of reagents, procedure which can make the determination very tedious. Therefore, the simultaneous reaction of periodate (equation 2) and iodate (equation 3) with iodide is not advisable and the analysis should preferably be carried out under conditions that inhibit the reaction of one of these ions.

For the determination of glycerol content in vanishing cream, the AOAC 942.22³⁶ recommends the iodometric titration carried out in the presence of sodium bicarbonate (pH 8), condition in which only the periodate reacts with iodide (equation 2). The glycerol is extracted with H₂SO₄ aqueous solution and then quantified by the difference between the amount of periodate added to the Malaprade reaction (obtained by titrating a blank) and the periodate remaining at the end of this reaction (determined by the titration of the sample). However, the method employs toxic substances, such as H₃AsO₃ and chloroform.

Although the low cost, all titrimetric methods above reported require a long time for analysis (> 60 min), because the Malaprade reaction is kinetically disadvantaged under the employed conditions. This problem is minimized if a high excess of periodate is used, but this leads to a substantial increase in titrant volume for the blank and for the sample, decreasing the sensitivity of the method. Alternatively, the excess of periodate is removed with other glycols so that the titrant volume for the blank is decreased and consequently the sensitivity is increased. However, with this procedure the analysis time becomes higher. Ideally, the Malaprade reaction should take place quickly, and the unreacted periodate should be promptly eliminated so that only the reaction of the iodate with the iodide occurs in the titration. In this case, the volume of titrant becomes directly proportional to the amount of glycerol in the sample.

Belcher and Townshend⁵²52 Belcher, R.; Townshend, A.; Anal. Chim. Acta 1968, 41, 395. proposed an iodometric titration for the determination of periodate and iodate in aqueous solutions containing a mixture of these ions. Sodium molybdate was used to mask the periodate (equation 6) and then iodide was added to react only with the iodate, according to equation 3. The produced triiodide was titrated with a standard sodium thiosulfate solution (equation 4). A second titration was carried out without the masking agent, and the periodate was determined by the difference between the volumes of the titrant spent in the two titrations.

(6)

6 {M o O}_{4}^{2 -} + {I O}_{4}^{-} + 8 H^{+} \to {[I {({M o O}_{4})}_{6}]}^{5 -} + 4 H_{2} O

Nakashima et al.,⁵³53 Nakashima, Y.; Shen, H.; Kusuyama, K.; Himeno, S.; Anal. Sci. 1999, 15, 725. by masking periodate with molybdate, determined periodate and iodate in water using capillary electrophoresis. According to these authors, the masking reaction (equation 6) is rapid and selective in a pH range of 3.0 to 4.5. In addition, the formed complex ([I(MoO₄)₆]⁵5 Motia, S.; Bouchikhi, B.; Llobet, E.; El Bari, N.; Talanta 2020, 216, 120953.-) was stable over a week in this condition. Ensafi and Chamjangali⁵⁴54 Ensafi, A. A.; Chamjangali, A. M.; Spectrochim. Acta, Part A 2003, 59, 2897. performed the sequential flow injection determination of iodate and periodate with spectrophotometric detection in water samples, using molybdate to mask periodate.

The present work proposes a reliable analytical procedure for the rapid determination of glycerol at low concentrations in aqueous medium using the Malaprade reaction. The method is based on the: (i) oxidation of glycerol with periodate (equation 1); (ii) masking of excess periodate with molybdate (equation 6); (iii) iodometric titration of iodate with thiosulfate (equation 4). As far as we know, for the determination of glycerol content, molybdate ion has not been used yet as masking agent for the unreacted periodate in the Malaprade reaction. The here proposed method was applied to determine the content of free glycerol in biodiesel produced from different raw materials, using semi-micro extraction procedure in order to have low reagents consumption and shorter analysis time.

Experimental

Apparatus

Volumetric flasks, pipettes and burettes class A were used. The preparations of standard and reference solutions were performed with 250 and 100 mL volumetric flasks, 10 mL pipette, 100-1000 µL micropipette (± 0.005 µL) and 1000-5000 µL micropipette (± 0.01 µL). Titrations were performed with 25, 10, and 5 mL burettes.

Reagents and materials

All reagents used were of analytical grade. Deionized water was employed to prepare the solutions. Sodium periodate solutions of 50 and of 5 mmol L^-1 were prepared dissolving, respectively, 2.68 and 0.268 g of NaIO₄ (Vetec, Duque de Caxias, Brazil) in 250 mL of water. These solutions were stored in closed amber flasks lined with aluminum foil. The aliquots taken from the solutions used for the analyses were pipetted directly from the flasks, which were closed immediately afterwards. A 0.2 mol L^-1 sodium molybdate solution was prepared dissolving 12.1 g of Na₂MoO₄.2H₂O (Vetec, Duque de Caxias, Brazil) in 250 mL of water. The solution was kept protected from light. A 2.0% potassium iodide (m/v) was prepared dissolving 5.0 g of KI (Êxodo Científica, Sumaré, Brazil) in 250 mL of water. A 3.0 mol L^-1 sulfuric acid solution was prepared by carefully diluting 33 mL of concentrated H₂SO₄ (Vetec, Duque de Caxias, Brazil) in 200 mL of water. A 2.8 mol L^-1 acetic acid solution at pH 3 was prepared by diluting 85 mL of glacial acetic acid (Vetec, Duque de Caxias, Brazil) with 415 mL of water and dissolving 0.666 g of sodium hydroxide (Vetec, Duque de Caxias, Brazil) in order to adjust the pH. 1% starch (m/v) solution was prepared by mixing 1.0 g of starch (Cinética Reagentes e Soluções, Jandira, Brazil) in 50 mL of water at room temperature. Afterwards, 50 mL of boiling water were added under vigorous agitation. The produced solution was boiled until it was transparent and then left to cool at room temperature. Glycerol (99.5%, Sigma-Aldrich, Duque de Caxias, Brazil), potassium iodate (99.4-100.4%, Vetec, Duque de Caxias, Brazil) and sodium thiosulfate (≥ 99.5%, Impex, São Paulo, Brazil) were used to prepare reference and standard solutions.

Biodiesels from soybean oil, palm kernel oil, macauba kernel oil, and used frying oil were synthesized and purified according to the methodology described by Rocha Jr. et al.⁵⁵55 Rocha Jr., J. G.; dos Santos, M. D. R.; Madeira, F. B.; Rocha, S. F. L. S.; Bauerfeldt, G. F.; da Silva, W. L. G.; Salomão, A. A.; Tubino, M.; J. Braz. Chem. Soc. 2019, 30, 1751.

Preparation of reference and standard solutions

Glycerol reference stock solution (10000 mg L^-1) was prepared by weighing approximately 1000 mg (accuracy ± 0.1 mg) of glycerol into a 100 mL volumetric flask, adding water to complete the volume. Glycerol reference solutions (GRS) of 10-1000 mg L^-1 were produced by pipetting aliquots of stock solution to a 100 mL volumetric flask, adding water up to the mark. Potassium iodate standard solutions of approximately 4 and 1.3 mmol L^-1 were prepared by dissolving with water into beakers, respectively, 210 and 70 mg (accuracy ± 0.1 mg) of KIO₃. The solutions were quantitatively transferred to 250 mL volumetric flasks which were adequately filled with water up to the mark. Standard solutions of 20 and 5 mmol L^-1 of sodium thiosulfate were prepared by adequately dissolving 1.2 and 0.3 g, respectively, of Na₂S₂O₃ with 250 mL of water. These sodium thiosulfate solutions were standardized titrating against potassium iodate solutions.

Standardization of sodium thiosulfate solutions

For the standardization of the 20 mmol L^-1 Na₂S₂O₃ solution, a 10 mL aliquot of the aqueous standard solution of 4 mmol L^-1 KIO₃ was pipetted into a 250 mL conical flask. Then, 1.0 mL of 3.0 mol L^-1 H₂SO₄ and 2.5 mL of 2.0% KI (m/v) aqueous solutions were added. Using a 25 mL burette, the mixture was titrated with the 20 mmol L^-1 Na₂S₂O₃ solution until a light-yellow color appeared, when the titration was interrupted. Then, 1.0 mL of 1% starch indicator (m/v) solution was added, producing dark blue color solution. Finally, the titration was continued until the blue color disappearance. The titration was carried out in triplicate.

The standardization of 5 mmol L^-1 Na₂S₂O₃ solution was similarly performed, however, the standard solution of 4 mmol L^-1 KIO₃ was replaced by another of 1.3 mmol L^-1 KIO₃.

Proposed method for the determination of the glycerol content

The proposed method was initially employed to determine the glycerol content in the GRS. For the analysis of the GRS with concentrations in the range from 10 100 mg L^-1, 1000 µL of GRS and 1000 µL of 5 mmol L^-1 NaIO₄ solutions were transferred to a 10 mL test tube having a screw cap. A 100-1000 µL micropipette was used for the transfers. The test tube was closed, vigorously shaken for 3 min and the content was transferred to a 250 mL conical flask. The inner walls of the test tube were washed with three portions of the 2.8 mol L^-1 acetic acid solution at pH 3.0. Each washing solution (totalizing 10 mL) was transferred to a 250 mL conical flask containing the glycerol/NaIO₄ mixture. Then, 3.0 mL of 0.20 mol L^-1 Na₂MoO₄.2H₂O solution was added and the mixture was vigorously stirred. Finally, 2.0 mL of 2.0% KI (m/v) was added, and the resulting solution was titrated with 20 mmol L^-1 Na₂S₂O₃ solution using a 5 mL burette, until observing a light-yellow color, when the titration was interrupted for the addition of 1.0 mL of 1% (m/v) starch indicator solution. Then, it was resumed until the disappearance of the blue color for at least 30 s.

Analysis of the blank was performed by replacing the GRS by the solvent (deionized water) and putting the starch indicator solution immediately after adding 2.0% KI (m/v). All titrations were carried out in quadruplicates.

Analyses of the 100 to 1000 mg L^-1 concentrations of GRS were performed by a similar procedure, but in these cases the less diluted NaIO₄ solution (50 mmol L^-1) and a 10 mL burette were used.

The glycerol content in the GRS was calculated according to equation 7.

(7)

{G L}_{G R S} = \frac{C_{{N a}_{2} S_{2} O_{3}} \times (V_{{N a}_{2} S_{2} O_{3}} - V_{b}) \times 92.09}{12}

where GL_GRS is the glycerol content in the GRS, in mg L^-1; is the concentration of the standard Na₂S₂O₃ solution, in mmol L^-1; and V_b are the volumes, in mL, of the Na₂S₂O₃ solution spent for the titration of the glycerol solution and of the blank, respectively; 92.09 is the molar mass of glycerol, in g mol^-1, and 12 is the stoichiometric factor.

Analysis of real samples and recovery

The proposed method was employed to determinate the free glycerol content in biodiesels from soybean oil, palm kernel oil, macauba kernel oil and used frying oil.

To perform the analysis, 400 μL of biodiesel were transferred to a 10 mL tared test tube with screw cap. The sample mass was determined using an analytical balance (± 0.0001 g). Free glycerol was extracted by adding 1600 μL of deionized water, 1600 μL of n-heptane, and vigorously shaking for 1 min. The mixture was then centrifuged at 2000 rpm for 1 min to separate the aqueous phase from the organic one. In sequence, an aliquot of 1000 μL of the aqueous phase was pipetted into a 10 mL test tube with screw cap and analyzed using the same procedure above described for the analysis of 1000 μL of GRS (10-100 mg L^-1). Determinations were performed in quintuplicates.

The free glycerol content in the biodiesel was calculated according to equation 8.

(8)

{G L}_{B D} = \frac{V_{E} \times C_{{N a}_{2} S_{2} O_{3}} \times (V_{{N a}_{2} S_{2} O_{3}} - V_{b}) \times 92.09}{V_{A} \times m_{bio} \times 12} \times 0.1

where GL_BD is the free glycerol content in the biodiesel, in g per100 g; m_bio is the mass of the analyzed biodiesel, in mg; V_E and V_A are the volumes, in mL, of the aqueous extract (1600 μL) and of the titrated solution (1000 μL), respectively; and 0.1 is the conversion factor used to express the concentration of GL_BD in g per 100 g.

The accuracy of the proposed method was evaluated performing recovery tests. Biodiesels samples were fortified with 100 μL of glycerol standards at three different concentrations (250, 500 and 1000 mg L^-1) which cause increases of approximately 0.03, 0.06, and 0.13 g per 100 g in the free glycerol contents. The extractions and determinations of the free glycerol contents of the fortified samples were carried out according to the procedure adopted in the analysis of the biodiesels samples. The determinations were performed in quintuplicates.

Monitoring the solutions of NaIO₄

Periodate ions react with water producing iodate ions which react with sodium thiosulfate causing a systematic error in the analysis, unless the volume of titrant spent on the blank titration is taken into account.⁵⁶56 Burgot, J. L.; Ionic Equilibria in Analytical Chemistry, 1st ed.; Springer: New York, USA, 2012.,⁵⁷57 Ghodbane, H.; Hamdaoui, O.; Desalin. Water Treat. 2016, 57, 4100. Even though from a thermodynamic point of view they are unstable, periodate solutions have been reported⁵⁶56 Burgot, J. L.; Ionic Equilibria in Analytical Chemistry, 1st ed.; Springer: New York, USA, 2012. to be kinetically stable, regardless of the pH value, as they oxidize water very slowly.

The 50 and 5 mmol L^-1 sodium periodate solutions were monitored to investigate whether they are stable enough to dispense blank titration. For such, after the preparation of the NaIO₄ solutions, the blank analysis was performed over time: in each case the number of drops of sodium thiosulfate solution necessary to change the color of the indicator was counted. The titrations were performed with sodium thiosulfate solutions of concentrations of 20 mmol L^-1 (with 10 mL burette) and of 5 mmol L^-1 (with 5 mL burette) versus, respectively, 50 and with 5 mmol L^-1 solutions of sodium periodate.

In order to investigate the effect of storage conditions, two groups of periodate solutions, used in this study, were stored in different conditions: (i) in closed flasks protected from light and from the environment; (ii) in open flasks unprotected from light and exposed to the environment.

Results and Discussion

Monitoring the solutions of NaIO₄

The monitoring of the sodium periodate solutions over time revealed that when exposed to the environment (atmosphere; light), until nine hours after their preparations, the iodate concentration does not decrease enough to influence the determination of glycerol (Figure 1). For both 50 and 5 mmol L^-1 solutions, either stored in open flasks or in closed flasks, only one drop of titrant was enough to turn the blue color of the solution (iodine-starch complex) to colorless (one drop corresponds to 0.04 mL for the 5 mL burette and to 0.07 mL for the 10 mL burette). Therefore, in such conditions, the reduction of the periodate ion in aqueous solution, due to light and other environmental conditions, producing iodate ion, is very small and it does not promote appreciable error in analysis.

Figure 1
Number of drops of 20 and 5 mmol L^-1 Na₂S₂O₃ solutions for the blank titration with 50 and 5 mmol L^-1 NaIO₄ solutions, respectively, both exposed and not exposed to environment (atmosphere; light).

Particularly, the periodate solutions stored in closed flasks and protected from light were not affected up to about 18.3 h after preparation. However, solutions stored in open flasks unprotected from light and environment, consumed from three to six drops of titrant when analyzed from about 18.3 h of storage or more (Figure 1).

If only one drop of titrant is spent in the titration of the blank it was disregarded in the calculations, because the volume of one drop was within the uncertainty of the volume of the added titrant.

The use of fresh solutions of NaIO₄ dispenses the blank analysis and the equations 7 and 8 can be changed to equations 9 and 10, respectively.

(9)

{G L}_{G R S} = \frac{C_{{N a}_{2} S_{2} O_{3}} \times V_{{N a}_{2} S_{2} O_{3}} \times 92.09}{12}

(10)

{G L}_{B D} = \frac{V_{E} \times C_{{N a}_{2} S_{2} O_{3}} \times V_{{N a}_{2} S_{2} O_{3}} \times 92.09}{V_{A} \times m_{b i o} \times 12} \times 0.1

Glycerol content in the reference solutions

The glycerol contents in GRS were determined by the proposed method with good accuracy (errors ≤ |3.4|%) and precision (coefficient of variation ≤ 8.0%) (Table 1). For the three highest glycerol concentrations in each series (100 1000 mg L^-1 and 10-100 mg L^-1), the coefficients of variation were ≤ 1.7% due to the increase of the titrant volume. The Student’s t-test revealed that, except in the GRS of 78.2 and 58.6 mg L^-1 where the calculated t values (4.14 and 3.29) were a little higher than the critical value (3.18), all average glycerol levels determined experimentally did not differ statistically from the glycerol content of the GRS, at the significance level (α) of 0.05 (degree of freedom = 3). Notwithstanding, the relative errors in the GRS of 78.2 and 58.6 mg L^-1 solutions were ≤ |3.0|%.

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Table 1
Nominal and experimental glycerol contents in GRS (from 100 to 1000 mg L^-1 and 10 to 100 mg L^-1), mean volume of the Na₂S₂O₃ solution spent in each titration, coefficient of variation, and relative error of each analysis

All titrimetric methods are subject to a systematic error caused by the indicator. As the volumes of titrants spent in the 10-100 mg L^-1 GRS are very low, this systematic error will be greater and, consequently, its reflection in the Student’s t-test can lead to an augmented t-value. Nevertheless, in the present case, this effect was only observed in the analysis of 78.2 and 58.6 mg L^-1 GRS, where the low values of the standard deviations imposed a narrowing of the confidence intervals.

The time required to perform one determination of the glycerol content in an aqueous solution, through the proposed method, is about 5 min. This time is quite less than that usually required by the current titrimetric procedures to determine this analyte in aqueous matrices. In the usual current titration methods only the step of glycerol oxidation with periodate (equation 1) requires from 10 to 90 min while the procedure here proposed requires only 3 min (Table 2). According to the work published by Hartman,⁶⁰60 Hartman, L.; J. Appl. Chem. 1953, 3, 308. 3 min would be enough time for the complete oxidation of glycerol by periodate.

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Table 2
Known titrimetric methods for the determination of the content of glycerol in various matrices and some of their characteristics, in comparison with the proposed iodometric method

Some current titration methods also employ small time intervals for the Malaprade reaction but in these procedures additional steps are required (pH adjustments, elimination of the unreacted periodate, and elimination of CO₂) causing increase in the determination time.⁶⁰60 Hartman, L.; J. Appl. Chem. 1953, 3, 308.,⁶¹61 Naviglio, D.; Romano, R.; Pizzolongo, F.; Santini, A.; De Vito, A.; Schiavo, L.; Nota, G.; Musso, S. S.; Food Chem. 2007, 102, 399. Also, some methods use harmful reagents and solvents which present risk to human health and to the environment (sodium arsenite and chloramine-T).⁵⁸58 Dantas, M. B.: Obtenção, Caracterização e Estudo Termoanalítico de Biodiesel de Milho (Zea mays L); MSc Dissertation, Universidade Federal da Paraíba, João Pessoa, Brazil, 2006, avalilable at https://www.ufpb.br/ppgq/contents/documentos/teses-e-dissertacoes/dissertacoes/2006/Dissertacao_Manoel_B_Dantas.pdf/view, accessed in December 2021.
https://www.ufpb.br/ppgq/contents/docume... ,⁶⁰60 Hartman, L.; J. Appl. Chem. 1953, 3, 308. There are yet other procedures that require a relatively high quantity of analyte to perform the titration (Table 2).⁶⁰60 Hartman, L.; J. Appl. Chem. 1953, 3, 308.,⁶¹61 Naviglio, D.; Romano, R.; Pizzolongo, F.; Santini, A.; De Vito, A.; Schiavo, L.; Nota, G.; Musso, S. S.; Food Chem. 2007, 102, 399.

The here proposed method determines smaller amounts of glycerol and uses smaller quantities of periodate than most of the known titrimetric methods (Table 2) for the determination of this analyte, ensuring less consumption of reagents. A procedure is described in the literature which allows the determination of low amounts of glycerol (see Rosas;⁵⁹59 Rosas, J. C. F.: Produção de Biodiesel Metílico Utilizando Óleo Residual de Fritura via Ultrassom; MSc Dissertation, Universidade Federal do Pará, Belém, Brazil, 2011, available at https://ppgeq.propesp.ufpa.br/ARQUIVOS/dissertacoes/J%C3%BAlio%20C%C3%A9sar%20Freitas%20Rosas.pdf, accessed in August 2021.
https://ppgeq.propesp.ufpa.br/ARQUIVOS/d... Table 2). However, it requires a long time for accomplishment of the Malaprade reaction (30 min), and as it is based on the AOCS Ca 14-56 standard it presents the same drawbacks previously reported in this work.

The low values of coefficient of variation, as observed in Table 1, are not common to be obtained in titration of small amounts of analyte. Very diluted solutions are undesirable in titration procedures, since the change-over of -log [a], where a is the analyte, as a function of the titrant volume, may not be enough high near the equivalence point in order to produce an evident shift of the indicator color. In this work quite dilute solutions were successfully titrated. One reason of this success is due to the fact that the influence of dilution in redox titrations is less significative than in acid-base, precipitation and complexometric titrations. Besides, the starch/I₃^- indicator acts by a non-redox mechanism,⁶⁷67 Harris, D. C.; Quantitative Chemical Analysis, 8th ed.; W. H. Freeman and Company: New York, USA, 2010. which makes the color change dependent only on the I₃^- concentration but not on the reduction potential of the redox reaction.

The quantification of glycerol at low concentrations by the proposed method was possible because an indicator capable of detecting small amounts of I₃^- was used. The starch indicator provides a limit of detection of I₃^- of approximately 5 × 10^-7 mol L^-1.⁶⁷67 Harris, D. C.; Quantitative Chemical Analysis, 8th ed.; W. H. Freeman and Company: New York, USA, 2010. However, this would not be sufficient if the burette did not have good accuracy (± 0.01 mL) and, the titrant solution was not diluted enough that small amounts of I₃^- required large volumes of titrant. These conditions were employed in the proposed method.

The ASTM D1615 standard⁶³63 ASTM D1615: Standard Test Methods for Glycerol, Ethylene Glycol, and Pentaerythritol in Alkyd Resins (Withdrawn 2004), West Conshohocken, PA, 1995. reports that the endpoint of an iodometric titration involving the ions iodate and periodate is not stable, fact which can be observed by the return of the blue color in about 5 min, at the end point of the titration. In this case, the titration must continue to be carried out until a stable endpoint is obtained. In the method here proposed, the instability of the endpoint was also observed in some analyses, but the persistence of the absence of the blue color for at least 30 s, after vigorous shaking of the solution, securely indicates the endpoint.

Similarly to the other methods cited here, which employ the Malaprade reaction, the proposed method is adequate for the analysis of samples in absence of glycols with adjacent hydroxyls, since they also do the Malaprade reaction,³⁴34 Malaprade, L.; Comptes Rendus 1928, 186, 382.,³⁵35 Zhang, Y.; Zhang, L.; Shao, S.; Chang, X.; Li, M.; ChemistrySelect 2020, 5, 6765. and also in absence of other impurities which react with periodate to produce iodate.

Biodiesel analysis and recovery tests

The biodiesels samples here analyzed by the proposed method presented contents above and below the limit allowed by the quality standards (0.02 g per 100 g) (Table 3). The recoveries of the added glycerol at three levels of concentrations are in the range from 92.9 to 111%, demonstrating that the proposed procedure presents good accuracy for the determination of free glycerol in the studied matrices.

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Table 3
Recovery test performed by adding standard solutions of glycerol to biodiesel (n = 5)

The extraction of free glycerol was based on the procedure proposed by Luetkmeyer et al.⁶⁸68 Luetkmeyer, T.; dos Santos, R. M.; da Silva, A. B.; Amado, R. S.; Vieira, E. C.; D’Elia, E.; Electroanalysis 2010, 22, 995. The authors extracted free glycerol from 400 µL of a biodiesel sample using 800 µL of distilled water, 800 µL of absolute ethanol and 1600 µL of n-heptane. The mixture was shaken in a vortex mixer and the phase separation was assisted by placing this tube in a centrifuge for about two minutes. In the work here reported, the polar phase used was 1600 µL of deionized water, the shaking was manual, and the centrifugation was performed for one minute. The good recoveries observed (Table 3) suggest that the adaptation of the procedure is adequate.

The semi-micro-scale extraction of the glycerol contained in the biodiesels samples allowed the optimization of the procedure by reducing the time necessary for the determination of this analyte. Thus, the time required for one single determination is about 10 min (except the preparation of the standard solutions), a time shorter than that used by other titrimetric methods for the determination of glycerol.

The use of such scale of extraction was only possible because the proposed method allows the determination of the analyte into aqueous solutions in small quantities (10-1000 µg).

Conclusions

As far as we know, the solution of sodium molybdate was used for the first time in the present work, as masking agent for the periodate ion in the titrimetric determination of the glycerol content, involving the Malaprade reaction. This approach provided the development of a method with a set of characteristics superior to any other titrimetric method previously reported for this purpose. It is of simple and fast execution, safe and environmentally secure. It is applicable for the determination of small amounts of glycerol in aqueous solutions. The glycerol content was determined with good accuracy and precision and the obtained results did not differ statistically from those of the reference glycerol solutions.

Periodic blank analysis is recommended to assess whether the periodate in solution suffered important reduction to iodate in an extent that it can affect the titration result. Nevertheless, blank analysis is unnecessary when a freshly prepared periodate solution stored, within a day, in a closed bottle and protected from light. Alternatively, the titrant volume spent for the blank can be discounted from the volume spent in the titration.

The proposed method presented satisfactory results in the analysis of free glycerol content in biodiesels prepared from different raw materials, using a semi-micro scale procedure for the extraction of free glycerol from the matrices.

Acknowledgments

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior-Brasil (CAPES)-Finance Code 001, and by the Conselho Nacional de Desenvolvimento Cientifico e Tecnológico-Brazil (CNPq).

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⁶²
Bradford, P.; Pohle, W. D.; Gunther, J. K.; Mehlenbacher, V. C.; Oil Soap 1942, 19, 189.
⁶³
ASTM D1615: Standard Test Methods for Glycerol, Ethylene Glycol, and Pentaerythritol in Alkyd Resins (Withdrawn 2004), West Conshohocken, PA, 1995.
⁶⁴
NP 16 018 05: Combustibles. Biodiesel Puro (B100). Requisitos Generales, Paraguay, 2011.
⁶⁵
Sanchez, D. L. R.: Butanol Production from Glycerol by Clostridium pasteurianum in Defined Culture Media - a Phenotypic Approach; MSc Dissertation, University of Maryland, College Park, USA, 2009, available at https://drum.lib.umd.edu/bitstream/handle/1903/9665/RamosSanchez_umd_0117N_10727.pdf?sequence=1&isAllowed=y, accessed in December 2021.
» https://drum.lib.umd.edu/bitstream/handle/1903/9665/RamosSanchez_umd_0117N_10727.pdf?sequence=1&isAllowed=y
⁶⁶
IRAM 5571: Determination of Glycerol Content, Argentina, 2003.
⁶⁷
Harris, D. C.; Quantitative Chemical Analysis, 8^th ed.; W. H. Freeman and Company: New York, USA, 2010.
⁶⁸
Luetkmeyer, T.; dos Santos, R. M.; da Silva, A. B.; Amado, R. S.; Vieira, E. C.; D’Elia, E.; Electroanalysis 2010, 22, 995.

Edited by

Editor handled this article: Maria Cristina Canela (Associate)

Publication Dates

Publication in this collection
30 May 2022
Date of issue
2022

History

Received
05 Aug 2021
Published
06 Jan 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[62] ⁶²
Bradford, P.; Pohle, W. D.; Gunther, J. K.; Mehlenbacher, V. C.; Oil Soap 1942, 19, 189.

[63] ⁶³
ASTM D1615: Standard Test Methods for Glycerol, Ethylene Glycol, and Pentaerythritol in Alkyd Resins (Withdrawn 2004), West Conshohocken, PA, 1995.

[64] ⁶⁴
NP 16 018 05: Combustibles. Biodiesel Puro (B100). Requisitos Generales, Paraguay, 2011.

[65] ⁶⁵
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» https://drum.lib.umd.edu/bitstream/handle/1903/9665/RamosSanchez_umd_0117N_10727.pdf?sequence=1&isAllowed=y

[66] ⁶⁶
IRAM 5571: Determination of Glycerol Content, Argentina, 2003.

[67] ⁶⁷
Harris, D. C.; Quantitative Chemical Analysis, 8^th ed.; W. H. Freeman and Company: New York, USA, 2010.

[68] ⁶⁸
Luetkmeyer, T.; dos Santos, R. M.; da Silva, A. B.; Amado, R. S.; Vieira, E. C.; D’Elia, E.; Electroanalysis 2010, 22, 995.

Concentration range / (mg L^-1)	Nominal content / (mg L^-1)	Volume of titrant / mL	Experimental content / (mg L^-1)	Coefficient of variation / %	Error / %	t value^a a t critical value = 3.18 (degree of freedom = 3; α = 0.05);
100-1000^b b 20 mmol L-1 Na2S2O3 solution and 10 mL burette;	997	6.44 ± 0.05	995 ± 6	0.6	-0.2	0.23
	798	5.26 ± 0.05	785 ± 5	0.6	-1.6	1.26
	598	3.77 ± 0.04	595 ± 10	1.7	-0.50	0.15
	391	2.58 ± 0.07	385 ± 10	2.8	-1.5	0.27
	195	1.29 ± 0.05	193 ± 7	3.6	-1.0	0.17
	99.7	0.648^c c the blank was discounted, according to equation 7; ± 0.010	96.3 ± 1.4	1.5	-3.4	1.2
10-100^d d 5 mmol L-1 Na2S2O3 solution and 5 mL burette.	97.7	2.388 ± 0.010	97.93 ± 0.10	0.1	0.24	0.23
	78.2	1.946 ± 0.005	79.8 ± 0.2	0.3	2.1	4.15
	58.6	1.471 ± 0.006	60.3 ± 0.3	0.5	2.9	3.29
	40.2	1.04^c c the blank was discounted, according to equation 7; ± 0.04	40.0 ± 1.6	4.0	-0.5	0.05
	20.1	0.522^c c the blank was discounted, according to equation 7; ± 0.010	20.0 ± 0.4	2.0	-0.5	0.06
	10.0	0.27^c c the blank was discounted, according to equation 7; ± 0.02	10.3 ± 0.8	8.0	3.0	0.13

Principle	Sample	Mass of glycerol	Oxidant agent/mass	time for Malaprade reaction / min	Agent for periodate elimination	time for periodate elimination / min	Blank	Titrant	Previous steps^a a Procedures for extracting the analyte or for pH adjustments, due to the intrinsic characteristics of the extraction solution, were disregarded; / estimated time^b b 3 min were considered for titration procedures;	Reference
Iodometric	biodiesel	4 mg	H₅IO₆/ 67.5 mg	30-90	none	-	yes	Na₂S₂O₃	none	⁵⁰50 ABNT NBR 15771: Biodiesel - Determinação de Glicerina Livre - Método Volumétrico, Brazil, 2009.
	vanishing cream	30-40 mg	KIO₄/ 230 mg	60	none	-	yes	H₃AsO₃	none	³⁶36 AOAC 942.22: Cosmetics - Vanishing Cream - Glycerol, Washington, DC, USA, 1990.
	fats and oils	600 µg	NaIO₄/ 275 mg	10	NaHCO₃	immediately	yes	NaAsO₂	none	⁵⁸58 Dantas, M. B.: Obtenção, Caracterização e Estudo Termoanalítico de Biodiesel de Milho (Zea mays L); MSc Dissertation, Universidade Federal da Paraíba, João Pessoa, Brazil, 2006, avalilable at https://www.ufpb.br/ppgq/contents/documentos/teses-e-dissertacoes/dissertacoes/2006/Dissertacao_Manoel_B_Dantas.pdf/view, accessed in December 2021. https://www.ufpb.br/ppgq/contents/docume... ^c c adapted from the AOCS Ca 14-56 standard;51dbased on the AOCS Ca 14-56 standard;51ebased on the IRAM 5571 standard;66faccording to the authors;
	fats and oils	15 µg	HIO₄/not reported	30	none	-	yes	Na₂S₂O₃	none	⁵⁹59 Rosas, J. C. F.: Produção de Biodiesel Metílico Utilizando Óleo Residual de Fritura via Ultrassom; MSc Dissertation, Universidade Federal do Pará, Belém, Brazil, 2011, available at https://ppgeq.propesp.ufpa.br/ARQUIVOS/dissertacoes/J%C3%BAlio%20C%C3%A9sar%20Freitas%20Rosas.pdf, accessed in August 2021. https://ppgeq.propesp.ufpa.br/ARQUIVOS/d... ^d
	water	30 mg	KIO₄/ 350 mg	5	KAsO₂^e	10	yes	chloramine-T	none	⁶⁰60 Hartman, L.; J. Appl. Chem. 1953, 3, 308.
Potentiometric	fats and oils	43-208 mg	NaIO₄/2.5 g	1	ethylene glycol	5	no	NaOH	pH adjustments/ 3 min	⁶¹61 Naviglio, D.; Romano, R.; Pizzolongo, F.; Santini, A.; De Vito, A.; Schiavo, L.; Nota, G.; Musso, S. S.; Food Chem. 2007, 102, 399.
Potentiometric	commercial glycerin	150 mg	H₅IO₆/1 g	60	none	-	yes	NaOH	pH adjustments/ 3 min	⁶²62 Bradford, P.; Pohle, W. D.; Gunther, J. K.; Mehlenbacher, V. C.; Oil Soap 1942, 19, 189.
Alkalimetric	water	400 mg	NaIO₄/3 g	30	ethylene glycol	20	yes	NaOH	evaluation of NaIO₄ solution/ 38 min	⁴⁰40 ASTM D7637: Standard Test Method for Determination of Glycerin Assay by Titration (Sodium Meta Periodate), West Conshohocken, PA, 2015.
	vanishing cream	30-40 mg	KIO₄/ 230 mg	60	propylene glycol	10	no	NaOH	none	³⁶36 AOAC 942.22: Cosmetics - Vanishing Cream - Glycerol, Washington, DC, USA, 1990.
	resin solutions	19-26 mg	HIO₄/ 550 mg	50-70	none	-	yes	NaOH	pH adjustments/ 3 min	⁶³63 ASTM D1615: Standard Test Methods for Glycerol, Ethylene Glycol, and Pentaerythritol in Alkyd Resins (Withdrawn 2004), West Conshohocken, PA, 1995.
	glycerol	100-120 mg	KIO₄/1.4 g	5	propylene glycol	few minutes^f	yes	NaOH	pH adjustments/ 3 min	⁵⁸58 Dantas, M. B.: Obtenção, Caracterização e Estudo Termoanalítico de Biodiesel de Milho (Zea mays L); MSc Dissertation, Universidade Federal da Paraíba, João Pessoa, Brazil, 2006, avalilable at https://www.ufpb.br/ppgq/contents/documentos/teses-e-dissertacoes/dissertacoes/2006/Dissertacao_Manoel_B_Dantas.pdf/view, accessed in December 2021. https://www.ufpb.br/ppgq/contents/docume...
	biodiesel	5-20 mg	NaIO₄/ 900 mg	30	ethylene glycol	20	no	NaOH	pH adjustments; boiling for CO₂ removal; cooling/ 15 min	³⁸38 Pisarello, M. L.; Costa, B. O. D.; Veizaga, N. S.; Querini, C. A.; Ind. Eng. Chem. Res. 2010, 49, 8935.
	biodiesel/ diesel blends	0.25-5 mg	NaIO₄/ 900 mg	30	ethylene glycol	20	yes	NaOH	pH adjustments; boiling for CO₂ removal; cooling/ 15 min	⁴³43 Pisarello, M. L.; Maquirriain, M. A.; Querini, C. A.; Energy Fuels 2018, 32, 8431.
	soaps and glycerin	150 mg	NaIO₄/ 900 mg	30	ethylene glycol	20	sometimes	NaOH	pH adjustments; boiling for CO₂ removal; cooling/ 15 min	⁶⁴64 NP 16 018 05: Combustibles. Biodiesel Puro (B100). Requisitos Generales, Paraguay, 2011.
	fermented glycerol broth	150-250 mg	NaIO₄/not reported	30	ethylene glycol	20	yes	NaOH	pH adjustments/ 3 min	⁶⁵65 Sanchez, D. L. R.: Butanol Production from Glycerol by Clostridium pasteurianum in Defined Culture Media - a Phenotypic Approach; MSc Dissertation, University of Maryland, College Park, USA, 2009, available at https://drum.lib.umd.edu/bitstream/handle/1903/9665/RamosSanchez_umd_0117N_10727.pdf?sequence=1&isAllowed=y, accessed in December 2021. https://drum.lib.umd.edu/bitstream/handl... ^g g based on the AOCS Ea 6-51 standard;47husing freshly prepared NaIO4 solution.
Iodometric	water	10-1000 µg	NaIO₄/ 1.07-10.7 mg	3	sodium molybdate	immediately	no^h	Na₂S₂O₃	none	proposed work

Biodiesel	Free glycerol content / (g per 100 g)	Added glycerol / (g per 100 g)	Found glycerol / (g per 100 g)	Recovery / %
Soybean	0.0268 ± 0.0017	0.031 ± 0.002	0.058 ± 0.003	100 ± 5
		0.062 ± 0.002	0.086 ± 0.003	97 ± 3
		0.131 ± 0.002	0.149 ± 0.006	93 ± 5
Palm kernel	0.011 ± 0.003	0.0306 ± 0.0003	0.040 ± 0.002	95 ± 5
		0.0617 ± 0.0013	0.071 ± 0.002	96 ± 4
		0.1281 ± 0.0011	0.1304 ± 0.0010	92.9 ± 0.4
Macauba kernel	0.052 ± 0.006	0.0305 ± 0.0004	0.085 ± 0.014	102 ± 6
		0.0631 ± 0.0010	0.115 ± 0.002	97 ± 4
		0.127 ± 0.003	0.182 ± 0.003	98 ± 8
Disposed frying oil	0.018 ± 0.003	0.0305 ± 0.0004	0.049 ± 0.002	111 ± 3
		0.0631 ± 0.0010	0.075 ± 0.009	101 ± 3
		0.125 ± 0.004	0.14 ± 0.03	102 ± 4

Brasil

Brasil

A Simple, Rapid, and Reliable Titrimetric Method for the Determination of Glycerol at Low Concentration

Abstract

Introduction

Experimental

Apparatus

Reagents and materials

Preparation of reference and standard solutions

Standardization of sodium thiosulfate solutions

Proposed method for the determination of the glycerol content

Monitoring the solutions of NaIO4

Results and Discussion

Monitoring the solutions of NaIO4

Glycerol content in the reference solutions

Biodiesel analysis and recovery tests

Conclusions

Acknowledgments

References

Edited by

Publication Dates

History

Monitoring the solutions of NaIO₄

Monitoring the solutions of NaIO₄