Towards a Mexican School of General Analytical Chemistry

Rojas-Hernández, Alberto; Ramírez-Silva, María Teresa; Galano, Annia; Rojas-Hernández, Alberto; Ramírez-Silva, María Teresa; Galano, Annia

doi:10.29356/jmcs.v68i4.2315

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Journal of the Mexican Chemical Society

versión impresa ISSN 1870-249X

J. Mex. Chem. Soc vol.68 no.4 Ciudad de México oct./dic. 2024 Epub 03-Mar-2025

https://doi.org/10.29356/jmcs.v68i4.2315

Historical Review

Towards a Mexican School of General Analytical Chemistry

Alberto Rojas-Hernández^*¹

María Teresa Ramírez-Silva¹

Annia Galano¹
http://orcid.org/0000-0002-1470-3060

^¹ UAM-Iztapalapa. Departamento de Química. Av. Ferrocarril San Rafael Atlixco 186, Col. Leyes de Reforma 1era Sección, Iztapalapa, C.P. 09310, CDMX, México.

Abstract.

This year the 50th anniversary of the Metropolitan Autonomous University is celebrated. It is for this reason that the JMCS decided to publish a special issue with contributions from professors from the Department of Chemistry. We thank the Editorial Committee of the issue for the invitation to write an article about the academic work that has been done in the Analytical Chemistry Area of this Department. We hope that we have managed to give a good description of the achievements we have had since the Analytical Chemistry Area was founded in the Iztapalapa Unit of the Metropolitan Autonomous University.

Keywords: General Analytical Chemistry teaching; Generalized Species and Equilibria Method (GSEM); chemical equilibrium

Resumen.

En este año se celebra el 50 aniversario de la Universidad Autónoma Metropolitana. Es con ese motivo que el JMCS decidió publicar un número especial con contribuciones de profesores del Departamento de Química. Agradecemos al Comité Editorial del número la invitación para hacer una contribución acerca del trabajo académico que se ha hecho en el Área de Química Analítica. Esperamos que hayamos logrado dar una buena descripción de los logros que hemos tenido desde que se fundó el Área de Química Analítica en la Unidad Iztapalapa de la Universidad Autónoma Metropolitana.

Palabras clave: Enseñanza de Química Analítica General; Método de Especies y Equilibrios Generalizados (MEEG); equilibrio químico

Introduction

In mid-2000, the creation of the most recent Academic Area of the Department of Chemistry at the Metropolitan Autonomous University, Iztapalapa Unit (UAM-Iztapalapa), was authorized: the Analytical Chemistry Area.

This concluded a work of some 22 years that María Teresa Ramírez-Silva (Tere) and I had undertaken, beginning at the Faculty of Higher Studies-Cuautitlán of the National Autonomous University of Mexico (FESC-UNAM, by its acronym in Spanish), and which continued at the UAM-Iztapalapa to since 1985, within the Electrochemistry Area.

But at the same time, when the Area of Analytical Chemistry was founded at the UAM-Iztapalapa, the path towards the establishment of a Mexican School of General Analytical Chemistry began.

Our training within the Charlot’s School of General Analytical Chemistry

Gaston Charlot conceived the teaching of General Analytical Chemistry, which aims to describe chemical reactions and other physicochemical processes in an analytical manner and then apply this knowledge in a systematic and controlled way. This allows not only to develop methods of chemical analysis, but also to transcend the explanation and development of other physicochemical procedures that occur in chemical synthesis and industrial chemistry (among other parts of chemistry), which are applied in solving problems in many sectors of society. [¹]

As students at FESC-UNAM we learned this approach of General Analytical Chemistry thanks to Margarita Rosa Gómez-Moliné (Rosamar), Helmut Pitsch and Michel Cassir. [²,³]. But there we were also trained as teachers, and we were given the freedom to make innovations in the teaching of analytical chemistry [⁴].

When Tere and I were hired at the UAM-Iztapalapa (between 1985 and 1987) we were in charge of teaching Analytical Chemistry in the Undergraduate and Graduate Studies in Chemistry.

Approach to Analytical Chemistry at the UAM-Iztapalapa

This is how we were able to translate our approach to teaching the discipline in the study programs of the Analytical Chemistry subjects of the Bachelor's Degree. This approach is made up of four items: Chemical Analysis, Physicochemical Processes Analysis, Instrumental Analysis and Chemometric Analysis.

Of these four areas, the one that really characterizes Charlot's method is the Physicochemical Processes Analysis, since this is what makes this Analytical Chemistry transcend from typical problems of chemical analysis to other problems of application in the chemistry of materials or industrial chemistry. [⁵]

Today, teaching Analytical Chemistry in our undergraduate courses begins with the main tools of Charlot's method (such as reaction prediction scales, predominance-zone diagrams, parameters of force and stability of species, tables of variation of substance quantities, chemical separations for chemical analysis, among others) in Brønsted's acid-base chemistry. With this, it is possible to have a robust model to predict and interpret what happens in acid-base titrations and in the preparation and application of pH buffer solutions.

Charlot's tools developed for the study of Brønsted acid-base systems are so useful that they can be applied to other types of reactions, such as those that occur in the formation of coordination compounds and redox processes. However, in Charlot's approach this is done when it is assumed that the processes in these systems are two-components (or occur through the exchange of one particle) [⁶], which is actually a simplification. -somewhat crude- of the real behavior of these systems.

In the case of our teaching, after studying the topics from Brønsted acid-base to pH buffer systems and acid-base titrations, we proceed to learn the systems where coordination compounds and redox species are formed through the Generalized Species and Generalized Equilibria Method; or simpler: Generalized Species and Equilibria Method (GSEM) [⁷].

GSEM not only allows the study of the systems described above, but also many others, including separation processes such as selective precipitation, liquid-liquid extraction and ion exchange. This is why this topic is included in the mandatory Analytical Chemistry courses at the UAM-Iztapalapa

Finally, Analytical Chemistry curriculum in the Bachelor's Degree also considers aspects of Instrumental Analysis and Chemometrics in different courses.

In the following sections of the article, the different areas where it is thought that the greatest contributions have been made to teaching (with this approach) or to the knowledge of Analytical Chemistry will be considered.

Contributions to Analytical Electrochemistry and Supramolecular Chemistry

Perhaps the main contribution to electrochemical field has been the proposal to using carbon paste electrodes in multiple studies, modifying the electrode surface with substances such as conductive polymers, surfactants or cyclodextrins. [⁸-¹⁴]

Fig. 1. shows an example of this kind of research in neurotransmission field.

Fig 1 In 2009 Tere, with students and other professors of UAM-Azcapotzalco, received the research award of CBI Division of UAM, by the paper cited as [¹⁰], related with the effect of sodium dodecilsulfate (SDS) in the electrochemical behavior of dopamine over a carbon paste electrode.

Tere also proposed using composite graphite-epoxy electrodes to construct Flow Injection Electroanalytical systems. [¹⁵-¹⁷]

The Analytical Chemistry Area was one of the first groups in Mexico to use conductive polymers to develop highly selective ion sensors, by the collaboration of Tere with Dr. Salvador Allegret, form Barcelona. And with the aid of Dr. Manuel Palomar-Pardavé (from Materials Area of UAM-Azcapotzalco) it was possible to use theoretical current transients models (used at that time mainly to study the electrodeposition of metals) to fit the experimental data and obtain important information about the electropolymerization process, the diffusion of the ion through the polymer, and its correlation with the analytical performance. [¹⁸]

Taking about the contributions in the field of cyclodextrins and their polymers, and neurotransmitters, it is important to mention that in the comprehensive characterization of these systems, Charlot’s approach was used, and all of these led to the development of important quantitative methodologies for trace determination of lead, mercury, and cadmium. [¹⁹-²¹]

Contributions to Brønsted's acid-base teaching and research

From an educational point of view, possibly the greatest contribution has been the development of a robust calculation algorithm to predict and interpret titration curves, as well as their first derivative, which has also led to interesting interpretations of the concept of buffer capacity. [²²-²⁵]

Nevertheless, teaching Brønsted acid-base systems with this approach requires knowledge of the acidity constants, and this led to establishing a line of research to determine these parameters. Thus, in 1990 the SQUAD program [²⁶] was captured and compiled, as part of a master's thesis [²⁷]. SQUAD determines acidity constants by fitting absorption spectra of systems of different chemical composition by non-linear least squares.

Acidity constants of organic substances (such as curcumin, mangiferin, and neurotransmitters, among others) have been determined, in aqueous solution and in other solvents; confirming previously reported values, but also providing unreported values in some cases (see Fig. 2). [²⁸-³³]

Fig. 2 This spectrophotometric study of curcumin is consistent with three pKa values, and not with two as reported until 2004. Reference [²⁹] is one of our most cited papers. (Adapted from [²⁹].)

As it can be seen in these works, various experimental methods (such as NMR, capillary electrophoresis, potentiometry, conductimetry, voltammetry) are frequently used to confirm the values obtained experimentally. [³⁴,³⁵]

Since it is sometimes not possible to do experiments to confirm the information obtained by spectrophotometry or potentiometry, in 2008 Annia Galano joined the group, with the aim of complementing the experimental studies with the help of computational chemistry and providing some relevant information, generally structural, but also kinetic (see Fig. 3). [³⁶-⁴²]

Fig. 3 Manfigerin (H₄MGF) has antioxidant activity. In reference [⁴⁰] the overall rate constant was calculated by computational chemistry calculations, and pKa values were confirmed by NMR studies. The species contributing the more to this rate constant is H₂MGF²⁽ if 3.5 (pH ( 9.0, even though not always is the predominant species. This demonstrates that H₂MGF²⁽ is more labile to hydrogen abstraction than H₃MGF⁽ and H₄MGF. (Adapted from [⁴⁰].)

We were pioneers in carrying out this type of multidisciplinary theoretical-experimental studies in the same Analytical Chemistry group.

Contributions to the determination of equilibrium constants of coordination and inclusion compounds

Despite using SQUAD to refine acidity constants has been our most frequent work, formation constants of coordination and inclusion compounds have also been determined in systems with pharmacological properties and material precursors, mainly. [⁴³-⁵¹]

Contributions to systematize Charlot's method for teaching General Analytical Chemistry

There are several innovations that we have made to Charlot's approach during these forty-five years, which we have not collected in books nor articles. But some contributions are worth mentioning regarding the use of the reaction prediction scale and to the construction of the predominance zone diagrams, giving maximum importance to the role played by the dismutation equilibria of the ampholytes in their construction (from the reaction prediction scale). [⁵²,⁵³]

We have also studied the validity of the approximations of representative equilibria, insisting on the advantages of Charlot's method when using only the equilibrium with the greatest physical significance in the system, and not the complete set of independent equilibria. Generally, this description can give an approximate answer, within the error margin considered acceptable [⁵⁴].

It was also possible to demonstrate that Charlot's method is applicable to the study of systems in which polynuclear species are formed and, then the so-called thermodynamic mechanism of polymerization was established [⁵⁵].

Finally we must highlight a work where it is demonstrated that species distribution diagrams summarize the distributions of the species of a system, as discrete variable distributions. There the variables are the stoichiometric coefficients of the components in the species, and the interpretation of an intrinsic buffer capacity is given as the variance of those distributions [⁵⁶].

We think that this work may be the precursor of a statistical thermodynamics of substance quantity for particle polydonor systems and with polynuclear species.

The generalized species and equilibria method

The scheme shown in Fig. 4 describes the contributions of Brønsted's acid-base theory and Arrhenius's theory of electrolytic dissociation to the emergence of the donor/receptor/particle model proposed by Charlot in the 1940s in France.

Although in essence Charlot's method follows Brønsted's acid-base theory (when the exchanged particle is the proton), it generalizes it to the exchange of other particles [⁶]. This generalization can be done very well for two-components systems, but when there are more components and the simultaneous exchange of two or more particles appears, Charlot's generalization is not so good. In those cases, then, the same French professors introduce the definition of conditional constants and complexation coefficients made by Professor Anders Ringbom [⁵⁷,⁵⁸].

We have made some contributions to the donor/receptor/particle model to improve the understanding of Mexican students, as noted in the previous section. One of them consists of a more direct formalization within the Chemical Thermodynamics framework, closely following the approach of Professors Smith and Missen [⁵⁹], especially for the definition of components and the set of independent equilibria in a system.

Fig. 4 Brief timeline and conceptual relationship of several methods used in Solution Chemical Equilibria Theory. This theory is applied in different Chemistry branches and is very useful in many cases.

But something that we also sought during some time was to generalize the Charlot's method to systems where there are more than two components under buffer conditions.

Charlot's method for two-components systems (M-L), which are polydonors of the L particle: (ML _n /ML _(n-1) /.../ML _j /.../ML/M/L), has a complete set of n independent equilibria (containing all the chemical information of the system), which are selected from the collection of formation equilibria

MLi+j-iL⇄MLj with KMLjj-iL=MLjMLiLj-i , i<j

and the set of dismutation equilibria

k-iMLj⇄j-iMLk+k-jMLi with Kj-iMLkk-iMLj=MLkj-iMLik-jMLjk-i , i<j<k

From a set of n independent equilibria, Charlot's method selects the equilibrium with the greatest physical significance (given the initial conditions of the system) or representative equilibrium, as if it were the only one present in that system.

Thus, for three-components systems (M-L-X), where X is the buffered component (pX = constant), the generalization of the method leads to the proposal of a generalized species scheme that follows a model of polydonors of the L´ generalized particle: (ML _n ’/ML _(n-1) ’/.../ML _j ´/.../ML’/M’/L’), in agreement with de definitions of generalized species

L´≡L+LX+...+LXi+...+LXo

M´≡M+MX+...+MXi+...+MXp

MLj´≡MLj+MLjX+...+MLjXi+...+MLjXq

MLn´≡MLn+MLnX+...+MLnXi+...+MLnXr

with molarities

L´=L+LX+...+LXi+...+LXo=LαL(X)

M´=M+MX+...+MXi+...+MXp =MαM(X)

…

MLj´=MLj+MLjX+...+MLjXi+...+MLjXq=MLjαMLj(X)

…

MLn´=MLn+MLnX+...+MLnXi+...+MLnXr=MLnαMLn(X)

where αL(X), αMX, αL(X), …, αMLjX,… ,αMLn(X) are the complexation coefficients of L, M,…, ML_j, …, ML_n ,which depend of the molarity of the buffered component, [X], through polynomials (with exponents that are natural or integer numbers and coefficients that are global formation constants of the species involved in each case).

With these generalized species definitions, generalized formation equilibria can be defined

MLi´+j-iL´⇄MLj´ with KMLj´j-iL´=MLj´MLi´L´j-i=KMLjj-iLαMLj(X)αMLi(X)αL(X)j-i

as well as the generalized dismutation equilibria

k-iMLj´⇄j-iMLk´+k-jMLi´ with Kj-iMLk´k-iMLj´=MLk´j-iMLi´k-jMLj´k-i=Kj-iMLkk-iMLjαMLk(X)j-iαMLi(X)k-jαMLj(X)k-i

KMLj´j-iL´ representing the conditional formation constant of the generalized species ML_j´ from the generalized species ML_i´, while Kj-iMLk´k-iMLj´ represents the conditional dismutation constant of the generalized species ML_j' that gives rise to the generalized species ML_k' and ML_i'. Substituting subscripts i, j, k properly, all generalized equilibria of each type in the system are obtained.

From these two sets of generalized equilibria, n independent generalized equilibria are selected.

It can be shown that if the value of pX is imposed on the system, the complexation coefficients and the conditional constants are constant [⁶⁰], so under these conditions everything that was done with simple chemical equilibria in the system, with Charlot´s Method, can be done with generalized equilibria, namely: diagrams of predominance zones, reaction prediction scales, tables of variation of substance quantities, reaction schemes for complexation or redox titrations, separation conditions of different chemical species, etc.

GSEM is different from the Ringbom´s method, because in the latter only one equilibrium of “primed species” is handled, which in the case of particle polydonor systems will have a conditional constant that does not depend only on the buffered pX.

GSEM is generalizable to systems of four or more components with double or multiple buffering, since the multiconditional constants, of the second-order or higher-order generalized equilibria, only depend on the conditions imposed for the buffered components. [⁶⁰]

Finally, GSEM can be handled approximately with representative equilibria, constructed with the predominant species for each generalized species. This can make it very intuitive. [⁶¹-⁶³]. Fig. 5. shows the different approaches to the description of complexation titration of Cu(II) with EDTA at imposed pH = 5.0 with a buffer of acetic acid/acetate 0.25 M.

Although GSEM has been documented by us in a doctoral thesis [⁶⁰] and different articles [⁶⁴-⁷²], where its potential is shown to make graphical representations in multi-component and multi-reacting systems (considering the formation of coordination compounds, polynuclear species, redox equilibria, condensed phases, liquid-liquid extraction or ionic exchange), its full potential has not been shown in books and articles, generalizing Charlot's method in calculations, which could make it more popular. We teach Analytical Chemistry using GSEM from 1985 to this date.

It is necessary to mention the contributions provided by Dr. Ignacio González (who agreed to direct my doctoral thesis [⁶⁰]) and Dr. Jorge Ibáñez to the GSEM, established in some publications [⁶⁴-⁷⁰].

Fig. 5 Several models that could be considered to explain the complexation reaction of Cu(II) wth EDTA. (a) Approximated definitions of generalized species Cu´, Y´ and CuY´ at buffered pH = 5.0, without considering the effect of acetates buffer. (b) Approximated definitions of generalized species AcO´, Cu´´, Y´´ and CuY´´ at buffered pH = 5.0 and imposed pAcO´ = 0.6 ([AcO´ = 0.25 M). (c) Approximated definitions of generalized equilibria used to explain the complexation reaction. The last approach is the best. Data have been taken from [⁵⁷] and HYDRA database from MEDUSA software. [⁷³]

Conclusions

A summary of the contributions that we have made to the development of General Analytical Chemistry has been presented, both from a teaching and research point of view.

The starting point was the approach of Professor Gaston Charlot's method to Analytical Chemistry, particularly his view that individuals trained in it are expected to be creative and approach the solution of problems in a reasoned manner, involving all knowledge and experimentation that may be available.

In our approach to the study of Analytical Chemistry problems, it is always important to consider the chemical species that may be present in the system. We think that this way of approaching knowledge should not be lost, but should be enriched, along with the physicochemical processes analysis that can be present in chemical analysis, industrial chemistry, materials chemistry, etc.

Other groups in Mexico are making other developments, but it is necessary that we communicate and join forces so that a consolidation of a Mexican School of General Analytical Chemistry can be achieved.

Acknowledgements

We acknowledge all students that have participated in Bachelor’s thesis or Thesis performed in our Analytical Chemistry Area. Without their work we could have not go forward in our research. Also our acknowledge to those students that followed any Analytical Chemistry course we offer in UAM-Iztapalapa. We are in debt with Dr. Ignacio González (Nacho) by giving us access to reference [¹]. Finally, we want to dedicate this paper to the memory of Bernard Trémillon and Rosamar, unfortunately passed away in 2023; and José Franco Pérez-Arévalo, recently passed away too.

References

1. Trémillon, B. Recueil de Textes Scientifiques Rédigés entre 1998 et 2009. 2009. Bulletin de l’Association des Anciens Elèves de l’ENSCP (École Nationale Supérieure de Chimie de Paris-Chimie Paris Tech-PSL). p. 84. [ Links ]

2. Morales-Galicia, L. M.; Rojas-Hernández, A. Obituario. Dra. Margarita Gómez Moliné (Rosamar). Bol. Soc. Quím. Mex. 2023, 17, 4-5. http://bsqm.org.mx/pdf-boletines/V17/V17N2/BSQM231702_cRosamar.pdf [ Links ]

3. Ramírez-Silva, M. T. Semblanza del doctor Alberto Rojas Hernández, acreedor del Premio Nacional de Química Andrés Manuel del Río 2011 de la Sociedad Química de México, en Docencia. Bol. Soc. Quím. Mex . 2011, 5, 50-51. http://bsqm.org.mx/pdf-boletines/V5/N1-3/13.-%20Semblanza%20Alberto%20Rojas.pdf [ Links ]

4. Rojas-Hernández, A.; Ramírez-Silva, M. T. La investigación en Química Analítica en México en los albores del Siglo XXI: Una visión desde el Área de Química Analítica de la Universidad Autónoma Metropolitana, Unidad Iztapalapa. Bol. Soc. Quím. Mex . 2011, 3, 58-68. http://bsqm.org.mx/pdf-boletines/V3/N1/10-Alberto%20Rojas%20Hdez.pdf [ Links ]

5. Trémillon, B. Homenaje a Gaston Charlot. Educ. quím. 1998. 9. 67-72. DOI: https://doi.org/10.22201/fq.18708404e.1998.2.66569 [ Links ]

6. Charlot, G. Chimie Analytique Générale. Vol. 1. Masson. Paris. 1969. [ Links ]

7. Rojas-Hernández, A. Representaciones gráficas de sistemas multicomponentes y multirreaccionantes: el Método de Especies y Equilibrios Generalizados. Bol. Soc. Quím. Mex . 2014, 8, 23-29. https://bsqm.org.mx/pdf-boletines/V8/V8N3/V8N3_Art5.pdf [ Links ]

8. Ramírez, M. T.; Palomar, M. E.; González, I.; Rojas-Hernández, A. Carbon Paste Electrodes with Electrolytic Binder: Influence of the Preparation Method. Electroanalysis 1995. 7. 184-188. DOI: https://doi.org/10.1002/elan.1140070215 [ Links ]

9. Morales-Pérez, A.; Roa-Morales, G.; Bernabé-Pineda, M.; Sánchez-Rivera, A. E.; Rojas-Hernández, A. ; Ramírez, M. T.. Electrochemical Study of Lead Species in Acetate Media: In Situ Formation of Alkyl and Lead Species on Carbon Paste Electrode. Electroanalysis 2001. 13. 541-548. DOI: https://doi.org/10.1002/1521-4109(200105)13:7%3C541::AID-ELAN541%3E3.0.CO;2-5 [ Links ]

10. Corona-Avendaño, S.; Alarcón-Ángeles, G.; Ramírez-Silva, M. T.; Rosquete-Pina, G.; Romero-Romo, M.; Palomar-Pardavé, M. ; On the electrochemistry of dopamine in aqueous solution. Part I: The role of [SDS] on the voltammetric behavior of dopamine on a carbon paste electrode. J. Electroanal. Chem. 2007. 609. 17-26. DOI: https://doi.org/10.1016/j.jelechem.2007.05.021 [ Links ]

11. Palomar-Pardavé, M.; Alarcón-Ángeles, G.; Ramírez-Silva, M. T.; Romero-Romo, M.; Rojas-Hernández, A. ; Corona-Avendaño, S. Electrochemical and spectrophotometric determination of the formation constants of the ascorbic acid-(-cyclodextrin and dopamine-(-cyclodextrin inclusion complexes. J. Incl. Phenom. Macrocycl. Chem. 2011. 69, 91-99. DOI: https://doi.org/10.1007/s10847-010-9818-0 [ Links ]

12. Guzmán-Hernández, D. S.; Ramírez-Silva, M. T.; Palomar-Pardavé, M.; Corona-Avendaño, S.; Galano, A.; Rojas-Hernández, A. ; Romero-Romo, M. Electrochemical characterization of tenoxicam using a bare carbon paste electrode under stagnant and forced convection conditions. Electrochim. Acta 2012. 59. 150-155. DOI: https://doi.org/10.1016/j.electacta.2011.10.046 [ Links ]

13. Corona-Avendaño, S.; Ramírez-Silva, M. T.; Romero-Romo, M.; Rojas-Hernández, A. ; Palomar-Pardavé, M. Influence Of The HClO₄ Concentration On The (-Cd Electropolimerization Over A Carbon Paste Electrode And On Dopamine’s Electrochemical Response. Electrochim. Acta 2013. 89. 854-860. DOI: https://doi.org/10.1016/j.electacta.2012.10.165 [ Links ]

14. Martínez‐Guerra, J.; Palomar‐Pardavé, M.; Romero‐Romo, M.; Corona‐Avendaño, S.; Guzmán‐Hernández, D. S.; Rojas‐Hernández, A.; Ramírez‐Silva, M. T. On the Curcumin and β‐Cyclodextrin Interaction in Aqueous Media. Spectrophotometric and Electrochemical Study. Chem. ElectroChem. 2022. 9. DOI: https://doi.org/10.1002/celc.202101534 [ Links ]

15. Álvarez-Romero, G. A.; Rojas-Hernández, A. ; Morales-Pérez, A.; Ramírez-Silva, M. T. Determination of β-D-glucose using flow injection analysis and composite-type amperometric tubular biosensors. Biosens. Bioelectron. 2004. 19. 1057-1065. DOI: https://doi.org/10.1016/j.bios.2003.10.001 [ Links ]

16. García-Dávila, V.; Alarcón-Ángeles, G.; Rojas-Hernández, A. ; Ramírez-Silva, M. T.; Palomar-Pardavé, M.; Romero-Romo, M. Electrochemical and Spectrophotometric Detection of the Chromo-Diphenylcarbazide Complex using FIA. ECS Transactions. 2007. 3. 87-92. DOI: https://doi.org/10.1149/1.2806954 [ Links ]

17. Valdés-Ramírez, G.; Álvarez-Romero, G. A.; Galán-Vidal, C. A.; Hernández-Rodríguez, P. R.; Ramírez-Silva, M. T. Composites: A novel alternative to construct solid state Ag/AgCl reference electrodes. Sens. Actuators, B 2005. 14. 264-270. DOI: https://doi.org/10.1016/j.snb.2005.02.013 [ Links ]

18. Álvarez-Romero, G. A.; Morales-Pérez, A.; Rojas-Hernández, A. ; Palomar-Pardavé, M.; Ramírez-Silva, M. T. Development of a Tubular Sensor Based on a Polypyrrole-Doped Membrane for the Potentiometric Determination of the Dodecylsulfate Anion in a FIA System. Electroanal. 2004. 16. 1236-1243. DOI: https://doi.org/10.1002/elan.200302935 [ Links ]

19. Álvarez-Romero, G. A.; Palomar-Pardavé, M. E.; Ramírez-Silva, M. T. Development of a novel nitrate-selective composite sensor based on doped polypyrrole. Anal. Bioanal. Chem. 2007. 387. 1533-1541. DOI: https://doi.org/10.1007/s00216-006-1021-1 [ Links ]

20. Álvarez-Romero, G. A.; Garfias-García, E.; Ramírez-Silva, M. T.; Galán-Vidal, C.; Romero-Romo, M.; Palomar-Pardavé, M. Electrochemical and AFM characterization of the electropolimerization of pyrrole over a graphite-epoxy resin solid composite electrode, in the presence of different anions. App. Surf. Sci. 2006. 252. 5783-5792. DOI: https://doi.org/10.1016/j.apsusc.2005.07.060 [ Links ]

21. Cobos-Murcia, J. A.; Galicia, L.; Rojas-Hernández, A. ; Ramírez-Silva, M. T.; Álvarez-Bustamante, R. A.; Romero-Romo, M.; Rosquete-Pina, G.; Palomar-Pardavé, M. Electrochemical polymerisation of 5-amino-1,10-phenanthroline onto different substrates. Experimental and theoretical study. Polymer. 2005. 46. 9053-9063. DOI: https://doi.org/10.1016/j.polymer.2005.07.026 [ Links ]

22. Rojas-Hernández, A. ; Ramírez Silva, M. T. Modelo Termodinámico General para Curvas de Valoración Ácido-Base de Mezclas de Sistemas Poliácidos o Polibásicos (sin Polinucleación) con Ácido o Base Fuertes. Primera Semana de la Química Inorgánica. Vol. 1. Notas de curso. 2002. Academia Mexicana de Química Inorgánica. 133-158. ISBN-02-A-970-31-0149-6 [ Links ]

23. Rodríguez-Laguna, N.; Rojas-Hernández, A. ; Ramírez-Silva, M. T. Estudio y comportamiento de la capacidad buffer de mezclas de especies de un mismo sistema polidonador de protones. Educ. quím . 2014. 25. 210-222. DOI: https://doi.org/10.1016/S0187-893X(14)70560-9 [ Links ]

24. Rojas-Hernández, A. ; Rodríguez-Laguna, N.; Ramírez-Silva, M. T.; Moya-Hernández, R. Distribution Diagrams and Graphical Methods to Determine or to Use the Stoichiometric Coefficients of Acid-Base and Complexation Reactions. Chap. 13. 287-310. In: Innocenti, A. Ed. Stoichiometry and Research-The Importance of Quantity in Biomedicine. 2012. InTech. DOI: https://doi.org/10.5772/34640 [ Links ]

25. Rodríguez-Laguna, N.; Rojas-Hernández, A. ; Moya-Hernández, R.; Gómez-Balderas, R.; Romero-Romo, M. A. The Conditions Needed for a Buffer to Set the pH in a System. Chap. 1. 3-21. In: Hoang, V. D. Ed. Advances in Titration Techniques. 2017. InTech. DOI: https://doi.org/10.5772/intechopen.69003 [ Links ]

26. Leggett, D.J. SQUAD. In: Leggett, D.J. Ed. Computational Methods for the Determination of Formation Constants. Modern Inorganic Chemistry. Chap. 6. Springer, Boston, MA. DOI: https://doi.org/10.1007/978-1-4684-4934-1_6 [ Links ]

27. Morales-Pérez, A. Estudio de sistemas químicos multirreaccionantes en soluciones acuosas por métodos espectrofotométricos con el programa SQUAD y otros métodos computacionales. Tesis de Maestría. 1993. Facultad de Estudios Superiores-Cuautitlán. UNAM. 117 páginas. [ Links ]

28. Sánchez-Rivera, A. E.; Corona-Avendaño, S.; Alarcón-Angeles, G.; Rojas-Hernández, A. ; Ramírez-Silva, M. T.; Romero-Romo, M. A. Spectrophotometric study on the stability of dopamine and the determination of its acidity constants. Spectrochim. Acta A Mol. Biomol. Spectrosc. 2003. 59. 3193-3203. DOI: https://doi.org/10.1016/S1386-1425(03)00138-0 [ Links ]

29. Bernabé-Pineda, M.; Ramírez-Silva, M. R.; Romero-Romo, M.; González-Vergara, E.; Rojas-Hernández, A. Determination of acidity constants of curcumin in aqueous solution and apparent rate constant of its decomposition. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2004. 60. 1091-1097. DOI: https://doi.org/10.1016/S1386-1425(03)00342-1 [ Links ]

30. Corona-Avendaño, S.; Alarcón-Angeles, G.; Rojas-Hernández, A. ; Romero-Romo, M. A.; Ramírez-Silva, M. T. Study on the stability of adrenaline and on the determination of its acidity constants. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2004. 61. 305-311. DOI: https://doi.org/10.1016/j.saa.2004.03.023 [ Links ]

31. Corona-Avendaño, S.; Romero-Romo, M. A.; Rojas-Hernández, A. ; Ramírez-Silva, M. T. Study on the stability of the serotonin and on the determination of its acidity constants. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2005. 61. 621-627. DOI: https://doi.org/10.1016/j.saa.2004.05.016 [ Links ]

32. Corona-Avendaño, S.; Rojas-Hernández, A. ; Romero-Romo, M. A.; Palomar-Pardavé, M.; Ramírez-Silva, M. T. Study on the stability of noradrenaline and on the determination of its acidity constants. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2005. 61. 3139-3134. DOI: https://doi.org/10.1016/j.saa.2004.11.047 [ Links ]

33. Gómez-Zaleta, B.; Ramírez-Silva, M. T.; Gutiérrez, A.; González-Vergara, E.; Güizado-Rodríguez, M.; Rojas-Hernández, A. UV/vis, ¹H, and ¹³C NMR spectroscopic studies to determine mangiferin pKa values. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2006. 64. 1002-1009. DOI: https://doi.org/10.1016/j.saa.2005.09.009 [ Links ]

34. Rodríguez-Barrientos, D.; Rojas-Hernández, A. ; Gutiérrez, A.; Moya-Hernández, R.; Gómez-Balderas, R.; Ramírez-Silva, M. T. Determination of pKa values of tenoxicam from ¹H NMR chemical shifts and of oxicams from electrophoretic mobilities (CZE) with the aid of programs SQUAD and HYPNMR. Talanta. 2009. 80. 754-762. DOI: https://doi.org/10.1016/j.talanta.2009.07.058 [ Links ]

35. Ibarra-Montaño, E. L.; Rodríguez-Laguna, N.; Sánchez-Hernández, A.; Rojas-Hernández, A. Determination of pKa Values for Acrylic, Methacrylic and Itaconic Acids by 1H and 13C NMR in Deuterated Water. JASCM. 2015. 4. 7-18. DOI: http://dx.doi.org/10.6000/1929-5030.2015.04.01.2 [ Links ]

36. Islas-Martínez, J. M.; Rodríguez-Barrientos, D.; Galano, A.; Ángeles, e.; Torres, L. A.; Olvera, F.; Ramírez-Silva, M. T.; Rojas-Hernández, A. Deprotonation Mechanism of New Antihypertensive Piperidinylmethylphenols: A Combined Experimental and Theoretical Study. J. Phys. Chem. B 2009. 113. 11765-11774. DOI: https://doi.org/10.1021/jp904474m [ Links ]

37. Galano, A.; Álvarez-Diduk, R.; Ramírez-Silva, M. T.; Alarcón-Ángeles, G.; Rojas-Hernández, A. Role of the reacting free radicals on the antioxidant mechanism of curcumin Chem. Phys. 2009. 363. 13-23. DOI: https://doi.org/10.1016/j.chemphys.2009.07.003 [ Links ]

38. Sanpedro-Montoya, K.; Martínez-Pérez, B.; Galano, A.; Ángeles, E.; Abrego, V. H.; Ramírez-Silva, M. T.; Rojas-Hernández, A. Deprotonation Mechanism and log P Values of New Antihypertensive Thiomorpholinylmethylphenols: A Combined Experimental and Theoretical Study. J. Chem. Eng. Data 2010. 55. 4323-4331. DOI: https://doi.org/10.1021/je100470g [ Links ]

39. Rebollar-Zepeda, A. M.; Campos-Hernández, T.; Ramírez-Silva, M. T.; Rojas-Hernández, A. ; Galano, A. Searching for Computational Strategies to Accurately Predict pKas of Large Phenolic Derivatives. J. Chem. Theory Comp. 2011. 7. 2528-2538. DOI: https://doi.org/10.1021/ct2001864 [ Links ]

40. Mendoza-Sarmiento, G.; Rojas-Hernández, A. ; Galano, A.; Gutiérrez, A. A combined experimental-theoretical study of the acid-base behavior of mangiferin: implications for its antioxidant activity. RSC Advances. 2016. 6. 51171-51182. DOI: https://doi.org/10.1039/C6RA06328D [ Links ]

41. Ibarra-Escutia, A.; Rojas-Hernández, A. ; Galano, A.; Ángeles, E.; Martínez-Mendoza, D.; Moya-Hernández, R. Determination of Acidity Constants, Partition Coefficients Between Water and 1-Octanol, and Deprotonation Route of 4-tert-buthyl-bis-(2,6-thiomorpholin-4-ylmethyl)-1-phenol and 4-hydroxy-3,5-bis(morpholin-1-ylmethyl)benzonitrile; Compounds with Antihypertensive Properties. J. Mex. Chem. Soc. 2016. 60. 152-162. https://www.jmcs.org.mx/index.php/jmcs/article/view/98/97 [ Links ]

42. Hernández-Olivares, M. A.; Ibarra-Escutia, A.; Mendoza-Sarmiento, G.; Rojas-Hernández, A. ; Galano, A. Elucidation of the complex deprotonation routes of Changrolin, the antihypertensives LQM-303 and LQM-303b, and their derivatives. Comput. Theor. Chem. 2017. 1115. 229-238. DOI: https://doi.org/10.1016/j.comptc.2017.06.023 [ Links ]

43. Botello, J. C.; Morales-Domínguez, e.; Domínguez, J. M.; Gutiérrez, A.; Rojas-Hernández, A. ; Ramírez, M. T. A New Nuclear Magnetic Resonance Algorithm to Determine Equilibrium Constants of the Species in the B(III)-H₂O System. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2003. 59. 1477-1486. DOI: https://doi.org/10.1016/S1386-1425(02)00394-3 [ Links ]

44. Moya-Hernández, M. R.; Mederos, A.; Dominguez, S.; Orlandini, A.; Ghilardi, C.; Cecconi, F.; González-Vergara, E.; Rojas-Hernández, A. Speciation Study of the Anti-Inflammatory Drug Tenoxicam (HTenox) with Cu(II). X-Ray Structure of [Cu(Tenox)₂(Py)₂](EtOH. J. Inorg. Biochem. 2003. 95. 131-140. DOI: https://doi.org/10.1016/S0162-0134(03)00095-3 [ Links ]

45. Bernabé-Pineda, M.; Ramírez-Silva, M. T.; Romero-Romo, M. A.; González-Vergara, E.; Rojas-Hernández, A. Spectrophotometric and electrochemical determination of the formation constants of the complexes Curcumin-Fe(III)-water and Curcumin-Fe(II)-water. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2004. 60. 1105-1113. DOI: https://doi.org/10.1016/S1386-1425(03)00344-5 [ Links ]

46. Lozano-Camargo, M. L.; Rojas-Hernández, A. ; Gómez-Hernández, M.; Pacheco-Hernández, M. L.; Galicia, L.; Ramírez-Silva, M. T. UV-visible spectroscopic and electrochemical study of the complex formation between Fe(II) and 5-amino-1,10-phenantroline (5-Aphen) in aqueous solution. Talanta 2007. 72. 1458-1468. DOI: https://doi.org/10.1016/j.talanta.2007.01.065 [ Links ]

47. Botello, J. C.; Pacheco-Hernández, M. L.; Gutiérrez, A.; Domínguez, J. M.; Espinosa, G.; Ramírez-Silva, M. T.; Rojas-Hernández, A. Equilibrium Constants Determination of the Species Formation in the Al(III)-H2O System by Integration of 27Al-NMR Signals and Fitting with Species Fractions. J. Mex. Chem. Soc . 2008. 52. 47-53. DOI: https://doi.org/10.29356/jmcs.v52i1.1045 [ Links ]

48. Moya-Hernández, R.; Gómez-Balderas, R.; Mederos, A.; Domínguez, S.; Ramírez-Silva, M. T.; Rojas-Hernández, A. Complex formation of the anti-inflammatory drugs tenoxicam and piroxicam with Fe(III) in methanol and acetone. J. Coord. Chem. 2009. 10. 40-51. DOI: https://doi.org/10.1080/00958970802474870 [ Links ]

49. Moya-Hernández, R.; Gómez-Balderas, R.; Rojas-Hernández, A. Chemical Speciation of the Fe(III)-piroxicam and Fe(III)-tenoxicam Systems in Aqueous Solution. J. Mex. Chem. Soc . 2011. 55. 94-100. DOI: https://doi.org/10.29356/jmcs.v55i2.838 [ Links ]

50. Verastegui-Omaña, B.; Palomar-Pardavé, M.; Rojas-Hernández, A. ; Corona Avendaño, S.; Romero-Romo, M.; Ramírez-Silva, M. T. Spectrophotometric quantification of the thermodynamic constants of the complexes formed by dopamine and Cu(II) in aqueous media. Spectrochim. Acta A Mol. Biomol. Spectrosc . 2015. 143. 187-191. DOI: https://doi.org/10.1016/j.saa.2015.01.067 [ Links ]

51. Hernández-García, L., Rojas-Hernández, A. ; Galano, A. Mangiferin/β-cyclodextrin complex: determination of the Inclusion constant in aqueous solution by Higuchi-Connors method and molecular absorption and photoluminescence UV spectroscopies at pH 3.4. Chem. Pap. 2022. 76. 7123-7132. DOI: https://doi.org/10.1007/s11696-022-02381-z [ Links ]

52. Rojas-Hernández, A. ; Ramírez, M. T.; González, I. Predominance-zone Diagrams in Solution Chemistry. Dismutation Processes in Two Component Systems (M-L).J. Chem. Educ. 1995, 72, 1099-1105. DOI: https://doi.org/10.1021/ed072p1099 [ Links ]

53. Rojas-Hernández, A. ; Martínez-Guerra, J.; Ramírez-Silva, M. T. Cálculos de pH en mezclas de sistemas poliácidos y polibásicos y algoritmo de cálculo robusto con un conjunto completo de equilibrios independientes. Colección Memorias de los Congresos de la Sociedad Química de México, 2do Congreso Internacional de Educación Química-en línea. 2021, CIEQ-IED-10, 219-224. https://sqm.org.mx/wp-content/uploads/2022/05/CIEQ2021_interactivo.pdf [ Links ]

54. Rojas-Hernández, A. ; Ramírez-Silva, M. T.; Galano, A.; Córdova-Frunz, J. L.; Pérez-Arévalo, J.F. La ecuación de Charlot, la gráfica de Flood y la gráfica de Gordus. Educ. quím . 2010, 21, 306-313. DOI: https://doi.org/10.1016/S0187-893X(18)30100-9 [ Links ]

55. Rojas-Hernández, A. ; Moya-Hernández, R.; Rueda-Jackson, J. C.; Ramírez-Silva, M. T. Thermodynamic Study of Component and Species Distributions in a One Component System as a First Step of Sol-Gel Processes: The Thermodynamic Mechanism of Polymerization. 364-380. In: Lopez, T. M.; Avnir, D.; Aegerter, M. (Eds.) Emerging Fields of Sol-Gel Science and Technology. Kluwer. Boston. 2003. https://springerlink.uam.elogim.com/book/10.1007/978-1-4615-0449-8 [ Links ]

56. Moya-Hernández, R.; Rueda-Jackson, J. C.; Ramírez-Silva, M. T.; Vázquez, G. A.; Havel, J.; Rojas-Hernández, A. Statistical Study of Distribution Diagrams for Two-Component Systems: Relationships of Means and Variances of the Discrete Variable Distributions with Average Ligand Number and Intrinsic Buffer Capacity. J. Chem. Educ . 2002. 9. 389-392. DOI: https://doi.org/10.1021/ed079p389 [ Links ]

57. Ringbom, A. Complexation in Analytical Chemistry. Interscience. New York. 1963. ISSN 0069-2883 [ Links ]

58. Trémillon, B. Électrochimie Analytique et Réactions en Solution. Vol. 1. Masson. Paris. 1993. 519 páginas. ISBN: 2-225-84177-2 [ Links ]

59. Smith, W. R.; Missen, R. W. Chemical Reaction Equilibrium Analysis: Theory and Algorithms. Wiley. New Jersey. 1983. ISBN 10:0471093475. [ Links ]

60. Rojas-Hernández, A. El Método de Especies y Equilibrios Generalizados para el Estudio de Sistemas Químicos en Equilibrio bajo Condiciones de Amortiguamiento: Teoría y Algoritmos de los Diagramas de Zonas de Predominio. 1995. Tesis de Doctorado. UAM-Iztapalapa. 347 páginas.http://tesiuami.izt.uam.mx/uam/aspuam/presentatesis.php?recno=1867&docs=UAM1867.PDF [ Links ]

61. Trejo-Córdova, G.; Rojas-Hernández, A. ; Ramírez-Silva, M. T. Diagramas de Zonas de Predominio Aplicados al Análisis Químico. UAM-Iztapalapa. CDMX. 1993. ISBN: 970-620-260-9 [ Links ]

62. Rojas-Hernández, A. ; Ramírez-Silva, M. T. Solución al Reactivo: Primer Examen Parcial de un Curso de Química Analítica II. Educ. quím . 1992. 3. 312-314. DOI: https://doi.org/10.22201/fq.18708404e.1992.4.66867 [ Links ]

63. Class recorded to show the prediction of PAR as indicator and spectrophotometric curve of complexometric tittration of Cu(II) with EDTA at pH imposed of 5.0 with acetic acid/acetate buffer 0.25 M. Accessed in may 2024. https://youtu.be/0rYJt_n3dCE?feature=shared [ Links ]

64. Rojas, A.; González, I. Relationship of Two-dimensional Predominance-Zone Diagrams with Conditional Constants for Complexation Equilibria. Anal. Chim. Acta 1986. 187. 279-285. DOI: https://doi.org/10.1016/S0003-2670(00)82919-0 [ Links ]

65. Rojas-Hernández, A. ; Ramírez, M. T.; González, I.; Ibanez, J. G. Relationship of Multidimensional Predominance-Zone Diagrams with Multiconditional Constants for Complexation Equilibria. Anal. Chim. Acta 1991. 246, 435-442. DOI: https://doi.org/10.1016/S0003-2670(00)80983-6 [ Links ]

66. Rojas-Hernández, A. ; Ramírez, M. T.; González, I.; Ibanez, J. G. Construction of Multicomponent Pourbaix Diagrams Using Generalized Species. J. Electrochem. Soc. 1991. 138. 365-371. https://iopscience.iop.org/article/10.1149/1.2085590 [ Links ]

67. Rojas-Hernández, A. ; Ramírez, M. T.; González, I.; Ibanez, J. G. Multi-dimensional Predominance-zone Diagrams for Polynuclear Chemical Species. Anal. Chim. Acta 1992. 259. 95-104. DOI: https://doi.org/10.1016/0003-2670(92)85080-P [ Links ]

68. Rojas-Hernández, A. ; Ramírez, M. T.; González, I. Equilibria among condensed phases and a multi-component solution using the concept of generalized species. I. Systems with mixed complexes. Anal. Chim. Acta 1993. 278, 321-333. DOI: https://doi.org/10.1016/0003-2670(93)85116-2 [ Links ]

69. Rojas-Hernández, A. ; Ramírez, M. T.; González, I. Equilibria among condensed phases and a multi-component solution using the concept of generalized species. II. Systems with polynuclear species. Anal. Chim. Acta 1993. 278. 335-347. DOI: https://doi.org/10.1016/0003-2670(93)85117-3 [ Links ]

70. Rojas-Hernández, A. ; Ramírez, M. T.; González, I. Distribution of Mononuclear Chemical Species in Two-Phase Multicomponent Systems Using Generalized Species and Equilibria. Química Analítica. 1996. 15 . [ Suppl.1]. S4-S8. [ Links ]

71. Páez-Hernández, M. E.; Ramírez, M. T.; Rojas-Hernández, A. Predominance-Zone Diagrams and Their Application to Solvent Extraction Techniques. Talanta. 2000. 51. 107-121. DOI: https://doi.org/10.1016/S0039-9140(99)00276-3 [ Links ]

72. Páez-Hernández, M. E.; Ramírez, M. T.; Rojas-Hernández, A. Uso del Método de Especies y Equilibrios Generalizados para Abordar Problemas de Separación por Extracción Líquido-Líquido. Actualidad Analítica 2023. 83. 12-15. https://seqa.es/wp-content/uploads/2023/09/INVESTIGACION-Ma.-Elena-Paez-Hernandez.pdf [ Links ]

73. Puigdomenech, Ignasi. Making Equilibrium Diagrams Using Sophisticated Algorithms (MEDUSA). KTH. Sweden. Accessed in May 2024. https://www.kth.se/che/medusa/downloads-1.386254 . [ Links ]

Received: May 31, 2024; Accepted: August 14, 2024; Published: September 30, 2024

^*Corresponding author: Alberto Rojas-Hernández, email: suemi918@xanum.uam.mx

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