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Article

Application of Calcium Alginate Spheres Modified with 2,4-Dinitrophenylhydrazine During the Determination of Fatty Aldehydes in Edible Oils by HPLC-DAD

by
F. Esmeralda Santiago-Martinez
1,
Jose A. Rodriguez
1,
Eva M. Santos
1,
Alicia C. Mondragon-Portocarrero
2 and
Jorge Lopez-Tellez
1,*
1
Area Academica de Quimica, Universidad Autonoma del Estado de Hidalgo, Carr. Pachuca-Tulancingo Km. 4.5, Mineral de la Reforma 42184, Hidalgo, Mexico
2
Laboratorio de Higiene, Inspeccion y Control de Alimentos, Departamento de Quimica Analitica Nutricion y Bromatologia, Universidad de Santiago de Compostela, 27002 Lugo, Spain
*
Author to whom correspondence should be addressed.
Separations 2026, 13(2), 75; https://doi.org/10.3390/separations13020075
Submission received: 15 January 2026 / Revised: 13 February 2026 / Accepted: 14 February 2026 / Published: 21 February 2026
(This article belongs to the Special Issue Development of Materials for Separation and Analysis Applications)
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Versions Notes

Abstract

Saturated fatty aldehydes are products from lipid oxidation that negatively affect the organoleptic properties and nutritional quality of food and represent a risk to human health. For this reason, they are frequently used as indicators of oxidation in food safety. Usually, their determination is carried out by derivatization using an excess of 2,4-dinitrophenylhydrazine (DNPH), but the excessive use of derivatizing agents requires a high proportion compared to the analyte concentration to ensure a complete reaction, which causes interferences and limits the chromatographic separation of derivatized products. In this context, the encapsulation of DNPH in alginate spheres is proposed to determine aldehydes concentration in edible vegetable oil samples, allowing the gradual release of DNPH to form the corresponding hydrazones, which were subsequently separated and analyzed by HPLC-DAD. The proposed method was optimized by a Taguchi L9(34) experimental design, validated, and applied for the determination of aldehydes in edible oils. Limits of detection in the intervals of 0.77 to 1.41 mg L−1 were obtained with adequate precision (expressed as relative standard deviation < 10%), which are suitable values for monitoring lipid oxidation in foods The proposed methodology represents a viable alternative to apply in quality control studies and lipid degradation profiles.

Graphical Abstract

1. Introduction

Edible vegetable oils are obtained from several seeds and fruits [1]. These oils present a high content of unsaturated fatty acids, becoming an important source of energy apart from some of them being essential because of their participation in the regulation of physiological functions [2,3,4]. Nevertheless, fatty acids undergo degradation processes [5,6], with autooxidation being particularly relevant, causing deterioration of flavor, aroma, color, texture, and appearance and decreasing nutritional value [1]. The oxidation of fatty acids occurs during both storage and processing and is favored by exposure to oxygen, light, and high temperature [7,8]. This process leads to the formation of degradation products, such as hydroperoxides, ketones, organic acids, alcohols, and aldehydes [3,5,9]. The latter stand out as the most abundant compounds, and their formation is closely related to the original fatty acid profile.
The main aldehydes formed are aliphatic aldehydes, α, β-unsaturated aldehydes, and oxygenated aldehydes [2,8,10]. Although adverse health effects, including mutagenic [3], genotoxic [8,11] and carcinogenic effects [7], have been primarily associated with unsaturated aldehydes, saturated aliphatic aldehydes have also been attributed to toxic properties in the body, such as lung problems, and a relationship with diverse types of cancer [5,8]. In this sense, different methodologies have been proposed for the determination of aldehyde [8,12,13]. The use of gas chromatography (GC) and high-performance liquid chromatography (HPLC) are the preferred techniques [14], since they allow the coupling of different detection systems and are compatible with different derivatization methodologies [15,16]. Numerous compounds have been employed in the aldehydes’ derivatization, such as O-(2,3,4,5,6-pentafluorobenzyl) hydroxylamine [17], pentafluorophenylhydrazine [18], and 2,4,6-triclorophenlyhidrazine [19] for GC, as well as 4-hydrazinobenzoic acid [20], 1-naphthalenyl hydrazine [16], and N-propyl-4-hydrazine-1,8-naphthalimide [21] for HPLC. The 2,4-dinitrophenylhydrazine has been the most widely used compound [22,23,24]. Nonetheless, methods developed using DNPH have faced some disadvantages, such as a low selectivity, and when it is used in excess, a tendency to precipitate is shown, which limits the degree of preconcentration [25]. Furthermore, the residual presence of excess derivatizing agent can interfere with detection and instrumental separation, compromising the analytical precision and accuracy [26,27].
Different strategies have been explored to improve the derivatization process using DNPH combined with solid-phase and liquid-phase extraction steps [16,26,27,28,29]. Among these, the retention of a derivatizing agent in/on polymeric matrices stands out, as it improves stability, allows a controlled release, facilitates the derivatization process, and simultaneously reduces the amount of unreacted derivatizing agent, improving the chromatographic profile [29,30,31]. Materials such as polydimethylsiloxane [29], carrageenan, and chitosan [32] have been used for the derivatizing agent retention. Calcium alginate, widely used in the food, medical, and chemical industries for the immobilization of active compounds, proteins, and even microorganisms, could be an alternative to allow a gradual reagent release [33].
Therefore, this work proposes an alternative strategy for the derivatization and determination of pentanal, hexanal, heptanal, octanal, nonanal, and decanal aldehydes in edible vegetable oils, based on the encapsulation of DNPH in calcium alginate spheres, to allow a controlled release of the derivatizing agent, reducing the amount of free DNPH in the injection and improving the chromatographic profile.

2. Materials and Methods

Acetonitrile, methanol, and acetic acid were purchased from J.T. Baker (Phillipsburg, NJ, USA). Aldehydes pentanal, hexanal, heptanal, octanal, nonanal, decanal, 2-hydroxy-5-methoxybenzaldehyde, and DNPH were obtained from Sigma-Aldrich (St. Louis, MO, USA). Sodium alginate (food grade) and calcium chloride (food grade) were used. Commercial edible vegetable oil samples from soybean, canola, olive, and safflower were obtained from local supermarkets. Solutions were prepared using deionized water with a resistivity not lower than 18.0 MΩ cm, purified by a Milli-Q system (Millipore, Bedford, MA, USA). A stock solution of each aldehyde (pentanal, hexanal, heptanal, octanal, nonanal, and decanal) at a concentration of 1000 mg L−1 was prepared in methanol.
Chromatographic analysis was performed using an HPLC 1260 Infinity system (Agilent Technologies, Waldbronn, Germany). The system was controlled using Agilent OpenLAB CDS software (Agilent Technologies, ChemStation Edition, version A.01.05). Separation of the hydrazones was carried out using a ZORBAX Eclipse XDB-C8 column (150 × 4.6 mm, 5 µm) from Agilent Technologies. A mobile phase consisting of an aqueous solution of acetic acid at 1% v/v (A) and methanol (B) was employed using the following gradient: A/B (20/80) for 6 min, from 80 to 85% B from 6 to 9 min, 85% B from 9 to 15 min, from 85 to 80% B from 15 to 18 min, and A/B (20/80) from 18 to 20 min, at a flow rate of 1.0 mL min−1 and an injection volume of 20 μL. The mobile phase was filtered using a 0.45 μm membrane. Detection was performed using a diode array detector at 360 nm.
Hydrazones were characterized by infrared spectroscopy using a Perkin Elmer GX spectrometer (Waltham, MA, USA) in the range of 4000–400 cm−1. Nuclear magnetic resonance (NMR) spectra at 400 MHz were obtained using a Bruker spectrometer (Bruker, Billerica, MA, USA), using CDCl3 (Sigma-Aldrich) as solvent.
A solution containing sodium alginate at 2% w/v and DNPH at 1000 mg L−1 was prepared in a solution of deionized water and ACN at a 4:1 v/v ratio. This solution was prepared under constant stirring at 30 °C to promote the polymer dissolution. The resulting solution was dropwise added using a syringe into a calcium chloride solution at 10% w/v, remaining for 2 min. After that, the spheres were rinsed in deionized water and dried at 60 °C for 6 h. Finally, the spheres were stored in an amber flask at room temperature until their use.
Optimization of the procedure was carried out using a Taguchi L9(34) experimental design. The following variables were evaluated: sample volume (2, 3, and 4 mL), reaction time (60, 90, and 120 min), acetic acid concentration (86, 172, and 258 mM), and activation time (90, 120, and 150 min). Experiments were performed using mineral oil spiked with 15 mg L−1 of each aldehyde and 15 mg L−1 de 2-hydroxy-5-methoxybenzaldehyde as the internal standard. Statistical analysis was performed using Minitab 21 software, using the Σ aldehyde to internal standard area ratio as the response variable.
The representation of the derivatization methodology is shown in Figure 1. DNPH-alginate spheres were immersed in 1 mL of ACN for 120 min. Subsequently, a 2 mL aliquot of each oil was taken and doped with 15 mg L−1 of 2-hydroxy-5-methoxybenzaldehyde (dissolved in mineral oil) used as the internal standard. The sample was transferred to a polypropylene tube containing one DNPH-alginate sphere, and glacial acetic acid was added to achieve a concentration of 258 mM. The mixture was allowed to react for 90 min at 60 °C, 1.0 mL of ACN was added, and it was mixed and centrifuged at 2000 rpm, recovering the ACN phase. Liquid-liquid extraction was performed twice, both ACN portions were combined and evaporated under a continuous air flow, and finally the residue was reconstituted in 250 μL of methanol before its analysis by HPLC-DAD.

3. Results and Discussion

3.1. Characterization of Alginate-DNPH Spheres

Calcium alginate spheres were prepared by ionic gelation using sodium alginate as a polymeric matrix. When DNPH-sodium alginate solution was dropwise added into a calcium chloride solution, the Ca(II) ions replaced the Na(I) ions, leading to the formation of a crosslinked three-dimensional network. The effectiveness of sphere formation was ensured by controlling alginate and calcium chloride concentrations, as well as the gelation time, resulting in homogeneous and spherical beads, which allowed for the prolonged and adequate release of the derivatizing agent.
The derivatization process using the spheres was evaluated using two strategies: (1) hydrated spheres (after their formation in the calcium chloride solution) and (2) spheres that were dried at 60 °C for 4 h. Figure S1a shows a bead in its hydrated state with a spherical shape, with an average diameter of 0.54 ± 0.03 mm, while the sphere obtained after the drying process presented an irregular shape and an average diameter of 0.19 ± 0.02 cm (Figure S1b).
The release of DNPH from both spheres was compared, showing that the dried spheres allowed a more controlled release of the derivatizing agent. Furthermore, the dried DNPH-calcium alginate spheres were stable in edible oils, and the hydrazones formed were solubilized in the oil phase allowing the liquid-liquid extraction with ACN. The calcium alginate phase remained stable, and therefore the viscosity was not affected. In contrast, the non-dried spheres tended to break, releasing the DNPH and water contained inside them, which negatively affected the derivatization reaction. Therefore, the dried spheres were selected for the experiment design.
The infrared spectra obtained for sodium alginate, DNPH, and alginate-DNPH spheres are presented in Figure S2. FTIR spectrum of sodium alginate (Figure S2a) showed a characteristic band around 3250 cm−1 corresponding to the stretching vibration of -OH groups, bands at 1600 cm−1 and 1400 cm−1 corresponding to the asymmetric and symmetric stretching vibrations of the carboxylate group [34], and a band at 1000 cm−1, attributed to C-O-C stretching vibrations [35]. Meanwhile, the DNPH spectrum (Figure S2b) showed a band at 3330 cm−1 corresponding to N-H stretching of the hydrazine group, signals in the 3000–3100 cm−1 intervals associated with C-H stretching, a band at 1600 cm−1 attributed to C=C stretching vibration of the aromatic ring, and bands around 1500–1300 cm−1, characteristic of the asymmetric and symmetric stretching vibrations of NO2 groups [36,37]. The DNPH-alginate spectrum (Figure S2c) showed representative bands of both the polysaccharide and DNPH, highlighting the presence of the band at 3330 cm−1 corresponding to N-H stretching and signals in the 3090–3110 cm−1 interval, characteristic of aromatic C-H stretching. The FTIR of alginate-DNPH sphere confirmed the preservation of the characteristic absorption bands of both components, without the appearance of new bands indicative of covalent bond formation. The spectral variations could be attributed to weak interactions such as hydrogen interaction or van der Waals forces. The spectral similarity supported the absence of chemical modification of DNPH in the alginate matrix. Additionally, the effective release of DNPH from the alginate spheres and the subsequent formation of aldehyde-DNPH hydrazones confirmed that the interactions inside the structure were non-covalent.

3.2. Characterization of Aldehyde-DNPH

To obtain the corresponding hydrazones between DNPH and the fatty aldehydes pentanal, hexanal, heptanal, octanal, nonanal, and decanal, 5 mL ACN containing 1000 mg L−1 of DNPH was placed with the respective aldehyde in excess for 90 min. After the reaction time, the solvent and the excess aldehyde were evaporated until a powder was obtained.
The hydrazones were characterized by FTIR spectroscopy. Figure S3b corresponds to the spectrum of hexanal, which showed bands around 3000–2900 cm−1 corresponding to the symmetric and asymmetric stretching vibrations of methylene and methyl groups of the aliphatic chain. In the 2800–2600 cm−1 interval, bands corresponding to the O=C-H bond of the aldehyde (Fermi resonance) were observed, while at 1717 cm−1, the characteristic stretching vibration band of the aldehyde C=O group was visible, and at 1400 cm−1, the C-H bending vibration band appeared [38,39,40]. The analyzed aldehydes showed only changes in the length of the aliphatic chain, exhibiting a similar profile in the FTIR spectra.
In the FTIR spectrum of the hexanal-DNPH hydrazone (Figure S3c), a shift and increase in intensity of the signal at 3295 cm−1 corresponding to the N-H stretching vibration was noticed. Also, bands at 3000–2900 cm−1 corresponding to the symmetric and asymmetric stretching vibrations of methylene and methyl groups of the aliphatic chain and the appearance of a band in the 1600–1500 cm−1 range corresponding to C=N stretching were observed. Meanwhile, the vibration bands corresponding to the aldehyde OC-H bond and the C=O stretching vibration (2800–2600 cm−1 and 1717 cm−1 respectively) disappeared compared to the starting materials, indicating the hydrazone formation. All hydrazones showed only changes in the length of the aliphatic chain, exhibiting a similar profile in the obtained FTIR spectra [41].
Additionally, 1H NMR spectra allowed the structural analysis of the reagents (DNPH and aldehydes) and the obtained hydrazones. For hexanal 1H NMR: (CDCl3, T = 25 °C) δ ppm: 9.75 (s, -CHO, 1H), 2.40 (m, -OHCCH2, 2H), 1.62 (m, -CH2, 2H), 1.30 (m, -CH2, 4H) 0.89 (t, -CH3, 3H). For DNPH 1H NMR (CDCl3, T = 25 °C) δ ppm: 9.44 (s, -NH-N, 1H) 9.10 (d, DNPH aromatic protons, 1H), 8.29 (d, DNPH aromatic protons, 1H), 7.84 (d, DNPH aromatic protons, 1H), 3.99 (s, -NH, 2H). For hexanal-DNPH 1H NMR: (CDCl3, T = 25 °C) δ ppm: 11.03 (s-NH-N, 1H), 9.15 (d, DNPH aromatic protons, 1H), 8.31 (d, DNPH aromatic protons, 1H), 7.94 (d, DNPH aromatic protons, 1H) 7.55 (t-CHN, 1H), 2.44 (m, -NHCCH2, 2H), 1.66 (m, -CH2, 2H), 1.40 (m, -CH2, 4H) 0.95 (t, -CH3, 3H). Figure S4 shows the spectra of hexanal, DNPH, and the corresponding hexanal-DNPH hydrazone. Comparing the spectra, when the hydrazones were formed, the aldehyde signal, a characteristic shift of approximately 9.7 ppm, disappeared [42]. However, the signals corresponding to the aliphatic chain and the aromatic ring of DNPH were observed [43]. In addition, a signal associated with the H-C=N group was visible around 7.55 ppm, while the NH proton showed a chemical shift to 11.03 ppm [37]. These signals confirmed the formation of the respective hydrazone. The spectra of the other hydrazones formed are shown in Figure S5, exhibiting the following shifts in the signals:
For pentanal-DNPH 1H NMR: (CDCl3, T = 25 °C) δ ppm: 11.07 (s-NH-N, 1H), 9.13 (d, DNPH aromatic protons, 1H), 8.33 (d, DNPH aromatic protons, 1H), 7.92 (d, DNPH aromatic protons, 1H) 7.52 (t-CHN, 1H), 2.43 (m, -NHCCH2, 2H), 1.59 (m, -CH2, 2H), 1.33 (m, -CH2, 2H) 0.94 (t, -CH3, 3H). For heptanal-DNPH 1H NMR: (CDCl3, T = 25 °C) δ ppm: 11.00 (s-NH-N, 1H), 9.11 (d, DNPH aromatic protons, 1H), 8.27 (d, DNPH aromatic protons, 1H), 7.90 (d, DNPH aromatic protons, 1H) 7.52 (t-CHN, 1H), 2.39 (m, -NHCCH2, 2H), 1.55 (m, -CH2, 2H), 1.31 (m, -CH2, 6H) 0.89 (t, -CH3, 3H). For octanal-DNPH 1H NMR: (CDCl3, T = 25 °C) δ ppm: 10.98 (s-NH-N, 1H), 9.07 (d, DNPH aromatic protons, 1H), 8.24 (d, DNPH aromatic protons, 1H), 7.88 (d, DNPH aromatic protons, 1H) 7.51 (t-CHN, 1H), 2.38 (m, -NHCCH2, 2H), 1.57 (m, -CH2, 2H), 1.26 (m, -CH2, 8H) 0.85 (t, -CH3, 3H). For nonanal-DNPH 1H NMR: (CDCl3, T = 25 °C) δ ppm: 10.95 (s-NH-N, 1H), 9.05 (d, DNPH aromatic protons, 1H), 8.21 (d, DNPH aromatic protons, 1H), 7.85 (d, DNPH aromatic protons, 1H) 7.47 (t-CHN, 1H), 2.35 (m, -NHCCH2, 2H), 1.57 (m, -CH2, 2H), 1.21 (m, -CH2, 10H) 0.82 (t, -CH3, 3H). For decanal-DNPH 1H NMR: (CDCl3, T = 25 °C) δ ppm: 10.95 (s-NH-N, 1H), 9.04 (d, DNPH aromatic protons, 1H), 8.21 (d, DNPH aromatic protons, 1H), 7.85 (d, DNPH aromatic protons, 1H) 7.47 (t-CHN, 1H), 2.35 (m, -NHCCH2, 2H), 1.58 (m, -CH2, 2H), 1.24 (m, -CH2, 12H) 0.81 (t, -CH3, 3H).

3.3. Optimization of Reaction Conditions

The derivatization with DNPH applied in the aldehyde determination is based on the hydrazone synthesis through a condensation reaction influenced by diverse variables, such as sample volume, reaction time, acid concentration, and activation time. Therefore, optimization was carried out using a Taguchi L9(34) experiment design where the intervals for each variable were defined based on a prior evaluation of the selected intervals [9,44], generating the orthogonal matrix of the Taguchi experimental design shown in Table 1. Each experiment was performed in a doped mineral for method optimization and validation due to its stability against oxidation because of its high saturated hydrocarbon content, which allows a clear evaluation of the effect of the studied variables. For the analysis, a sphere was used that contains an estimated concentration of 0.06 ± 0.01 mg of DNPH.
Multiple aliphatic, α, β-unsaturated aldehydes, and hydroxyaldehydes generated from lipid oxidation have been described [10], so 2-hydroxy-5-methoxybenzaldehyde was selected as an internal standard since it is not an aldehyde usually described in the analytical matrix or generated from lipid oxidation. Although this aldehyde is structurally different from the evaluated ones, no interference was observed in the formation of the corresponding hydrazone, making it suitable for the monitoring of the technique. The optimization of derivatization conditions using the Taguchi design allowed identification of the levels of each variable, which offered the highest analytical response in terms of the ΣAldehyde-to-IS peak area ratio. According to the results (Figure 2), a sample volume of 2.0 mL was the value of the variable with the greatest contribution among the evaluated factors. On the other hand, increasing the oil volume provoked a decrease on the response variable related to the equilibrium in mass transfer governed by the dependence between sample volume and extractant volume, as the distribution decreases with increasing sample volume [45,46]. The highest acetic acid concentration (258 mM) also favored an increase in the response signal, since the hydrazone formation occurs through a nucleophilic addition to the carbonyl group followed by a dehydration step. However, the addition of an acidic medium is required to protonate the oxygen and enable nucleophilic addition, with this step being crucial [47]. Finally, sphere conditioning time showed an improvement in derivatization capacity when longer activation periods were employed. This increase in analytical response can be attributed to structural changes in the alginate matrix that modifies DNPH availability. After spheres dry, porosity decreases, and the polymer network becomes denser, limiting internal diffusion of the encapsulated compound. However, the immersion in ACN reduces the polymer rigidity and improves internal mobility, facilitating the diffusion of the derivatizing reagent. Thus, a longer conditioning period facilitates DNPH diffusion toward the sphere surface [48,49,50,51]. Related to the reaction time variable, results indicated that this factor influenced the process performance, since sufficient reaction time is required for its completion. In short times, the reaction cannot go on quantitatively, whereas excessively long reaction times could lead to the formation of other species or product decomposition. The optimal values obtained from the experiment design were a sample volume of 2.0 mL, [acetic acid] of 258 mM, 150 min of sphere activation, and 90 min of reaction. These conditions were used for subsequent experiments.
Under optimal conditions, the calibration curves were constructed, obtaining linear intervals from 2.34 to 50.0 mg L−1. Analytical parameters are presented in Table 2. The limits of detection (LOD) ranged from 0.77 to 1.41 mg L−1, calculated at a signal-to-noise ratio of 3.29, and the limits of quantification (LOQ) ranged from 2.34 to 4.28 mg L−1, calculated at a signal-to-noise ratio of 10, according to IUPAC criteria. It has been reported that aldehyde concentrations above 40 mg L−1 generate perceptible rancid odors and flavors in foods, whereas levels below 5 mg L−1 do not modify the sensory profile [52], indicating that the achieved LODs allow the aldehyde detection within a relevant range to evaluate oxidative spoilage.
The method precision was estimated as repeatability and reproducibility in terms of relative standard deviation (% RSD, n = 3) at three concentration levels (20, 30, and 40 mg L−1) (Table 3). The repeatability and reproducibility values were below 10% in all cases, indicating adequate precision. The method accuracy was evaluated by recovery assays at three concentration levels (25, 35, and 45 mg L−1). In this case, the results ranged from 91.18 to 109.34%, with %RSD values below 10% at all evaluated levels. These results indicate that the proposed methodology for aldehyde determination is adequate in terms of precision and accuracy.
The aldehyde content was determined in four fresh edible vegetable oils subjected to a thermal oxidation process by continuously heating at 100 °C for 7 days. Under these conditions, safflower oil exhibited the highest degradation, with quantifiable concentrations of the six aldehydes evaluated (Figure 3), whereas soybean and canola oils showed lower concentrations and no detection of decanal. In safflower oil, nonanal was the predominant aldehyde, followed by hexanal, which can be attributed to the high proportion of oleic and linoleic acids, respectively, whose oxidative degradation favors the formation of these compounds. This behavior is consistent with the fatty acid profile reported in the literature, where oleic and linoleic acids account for approximately 93.27% of the total fatty acids. Similarly, in canola and soybean oils, where hexanal and nonanal were the predominant, respectively, oleic and linoleic acids represent approximately 77.04% of the total fatty acids in canola oil and 86.02% in soybean oil [16,53]. On the contrary, olive oil showed the lowest aldehyde formation among the samples studied, possibly due to the added natural antioxidant compounds, such as phenols and tocopherols, which can delay oxidative degradation [54].
Conventional methodologies for aldehyde derivatization using DNPH are based on the direct addition of the derivatizing agent and the use of high concentrations compared to aldehydes to ensure a complete reaction. However, this excess can provoke interference in the chromatographic profiles. The proposed methodology represents an advantage because the use of DNPH encapsulated in alginate allows the gradual release of the reagent and reduces the presence of unreacted DNPH in the injection. This behavior is reflected in the chromatograms of the blank (Figure 4a) and the enriched mineral oil standard (Figure 4b), where the signal corresponding to free derivatizing agent is not observed. Likewise, the chromatogram of the sample subjected to thermal oxidation (Figure 4c) besides the six aldehydes evaluated multiple peaks at shorter retention times were observed, not appreciated in the blank or in the standard samples. This suggests that the derivatization of other carbonyl compounds could be resolved in the absence of interferences caused by excess of DNPH (Figure S6). These results indicate that the proposed methodology has potential to broaden its application to oxidation products other than those analyzed in this study and to obtain more comprehensive lipid degradation profiles in complex matrices.
Generally, other conventional methodologies described in the literature (Table 4) present different limitations. For example, some of them employ derivatizing agents that require complex synthesis [55], or they use solid-phase extraction protocols that require extensive adsorbent preparation [56]. In contrast, the proposed based on DNPH-alginate spheres allows direct derivatization inside the sample matrix, reducing sample handling. Furthermore, the preparation of the spheres is quite simple and not expensive. Additionally, different studies determining comparable aldehyde concentrations in oxidized edible vegetable oil samples confirm that extremely low LODs are not required for lipid oxidation assessment [11,57]. In this sense, a DAD detection system should be enough compared to a system coupled to mass spectrometry, which would exceed the analytical requirements of these oil samples.

4. Conclusions

A methodology was developed for the derivatization and determination of six saturated fatty aldehydes in oxidized vegetable edible oils using DNPH encapsulated in calcium alginate spheres. The gradual release of the derivatizing agent allowed the acquisition of cleaner chromatographic profiles, highlighting the absence of the chromatographic signal corresponding to unreacted DNPH in the blank sample and in the spiked standard. This confirms its adequate interaction with the analytes for their separation and detection by HPLC-DAD, with limits of detection from 0.77 to 1.41 mg L−1, suitable to follow oxidative degradation in fatty foods. Furthermore, the absence of interferences derived from free DNPH, far from being limited exclusively to the aldehydes analyzed in this study, could allow the evaluation of other lower molecular aldehydes.

Supplementary Materials

The following supporting information can be downloaded at https://www.mdpi.com/article/10.3390/separations13020075/s1. Figure S1. DNPH-alginate spheres (a) hydrated form (b) after drying process; Figure S2. FTIR spectra of (a) sodium alginate (b) DNPH (c) DNPH-alginate; Figure S3. FTIR spectra of (a) DNPH (b) hexanal (c) hexanal dinitrophenylhydrazone; Figure S4. 1H NMR spectra of (a) hexanal (b) DNPH (c) hexanal-DNPH; Figure S5. 1H NMR spectra of (a) pentanal-DNPH (b) heptanal-DNPH (c) octanal-DNPH (d) nonanal-DNPH (e) decanal-DNPH; Figure S6. Chromatograms of (a) derivatization of aldehydes using DNPH in solution (b) derivatization of aldehydes using DNPH encapsulated in calcium alginate spheres.

Author Contributions

Conceptualization, J.A.R.; methodology, F.E.S.-M.; validation, J.L.-T. and F.E.S.-M.; formal analysis, E.M.S. and F.E.S.-M.; investigation, F.E.S.-M. and A.C.M.-P.; resources, J.A.R.; data curation, J.L.-T. and A.C.M.-P.; writing-original draft preparation, F.E.S.-M. and E.M.S.; writing—review and editing, J.L.-T. and J.A.R.; visualization, F.E.S.-M. and E.M.S.; supervision, A.C.M.-P. and J.A.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The authors confirm that the data supporting the findings of this study are available within the article.

Acknowledgments

The authors thank the financial support from Secretaria de Ciencia, Humanidades, Tecnologia e Innovacion (SECIHTI) (SNI distinction as research membership, scholarship and program “Ayudante de investigador SNI”).

Conflicts of Interest

The authors declare no conflicts of interest.

Abbreviations

The following abbreviations are used in this manuscript:
ACNAcetonitrile
AcOHAcetic acid
DCBI-MS/MSDesorption Corona Beam Ionization tandem mass spectrometry
DMMIPsDual-template magnetic molecularly imprinted polymers
DNPH2,4-dinitrophenylhydrazine
ExpExperiment
Fe3O4/SiO2/P(MAA-co-EGDMAMagnetite/silica/poly(methacrylic acid-co-ethylene glycol dimethacrylate)
FTIRFourier transform infrared spectroscopy
GCGas chromatography
HPLCHigh-performance liquid chromatography
HPLC-DADHigh-performance liquid chromatography with diode-array detection
HPLC-UVHigh-performance liquid chromatography with ultra-violet detection
ISInternal standard
LC-MS/MSLiquid chromatography with tandem mass spectrometry
LHMTsLevofloxacin-hydrazide-based mass tags
LLELiquid-liquid extraction
LODLimit of detection
LOQLimit of quantification
MSPE-ISDMagnetic solid phase extraction coupled with in situ derivatization
NMRNuclear magnetic resonance
REFReference
RSDRelative standard deviation
UHPLC-MS/MSUltra-high performance liquid chromatography-mass spectrometry/mass spectrometry
UFLC-DAD-ESI-MSUltra-Fast liquid chromatography coupled with diode array and electrospray ionization mass spectrometry
μ-SPE-DMicro solid-phase extraction and derivatization

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Separations 13 00075 g001
Figure 1. Schematic representation of the methodology for aldehyde determination using DNPH-alginate spheres.
Figure 1. Schematic representation of the methodology for aldehyde determination using DNPH-alginate spheres.
Separations 13 00075 g001
Separations 13 00075 g002
Figure 2. Main effect plot for mean of Taguchi design.
Figure 2. Main effect plot for mean of Taguchi design.
Separations 13 00075 g002
Separations 13 00075 g003
Figure 3. Concentrations of aldehydes in edible vegetable oils after thermal oxidation.
Figure 3. Concentrations of aldehydes in edible vegetable oils after thermal oxidation.
Separations 13 00075 g003
Separations 13 00075 g004
Figure 4. Chromatograms of (a) blank (b) mineral oil enriched with 40 mg L−1 of each aldehyde (c) safflower oil sample heated to 100 °C for 7 days. Peak assignments: IS: internal standard 15 mg L−1, 1: pentanal, 2: hexanal, 3: heptanal, 4: octanal, 5: nonanal, 6: decanal.
Figure 4. Chromatograms of (a) blank (b) mineral oil enriched with 40 mg L−1 of each aldehyde (c) safflower oil sample heated to 100 °C for 7 days. Peak assignments: IS: internal standard 15 mg L−1, 1: pentanal, 2: hexanal, 3: heptanal, 4: octanal, 5: nonanal, 6: decanal.
Separations 13 00075 g004
Table 1. Taguchi orthogonal array L9(34).
Table 1. Taguchi orthogonal array L9(34).
ExpSample Volume (mL)Reaction Time (min)Activation Time (min)[AcOH] (mM)∑ (RCHOs/IS)
126090861.31
22901201721.41
321201502581.51
4360150861.17
5390901720.90
631201202581.10
7460120860.58
84901501720.70
94120902580.68
Table 2. Regression parameters of the calibration curves for the aldehydes.
Table 2. Regression parameters of the calibration curves for the aldehydes.
Aldehyder2b1 ± δb1b0 ± δb0LOD (mg L−1)LOQ (mg L−1)
Pentanal0.9990.391 ± 0.0170.001 ± 0.0351.344.07
Hexanal0.9990.949 ± 0.0340.118 ± 0.0581.093.30
Heptanal0.9990.362 ± 0.0200.036 ± 0.0391.414.28
Octanal0.9990.314 ± 0.0090.064 ± 0.0160.772.34
Nonanal0.9990.191 ± 0.0060.055 ± 0.0130.822.51
Decanal0.9990.116 ± 0.0030.037 ± 0.0060.792.40
Table 3. Repeatability, reproducibility, and recovery values at different concentration levels.
Table 3. Repeatability, reproducibility, and recovery values at different concentration levels.
AldehydeRepeatability
(%RSD, n = 3)		Reproducibility
(%RSD, n = 3)		% Recovery
(%RSD, n = 3)
20 mg L−130 mg L−140 mg L−120 mg L−130 mg L−140 mg L−125 mg L−135 mg L−145 mg L−1
Pentanal3.403.754.927.615.793.8091.18
(7.22)		102.24
(7.93)		96.79
(4.72)
Hexanal4.223.915.187.454.015.1892.15
(9.66)		97.84
(8.20)		99.02
(5.98)
Heptanal3.183.365.227.606.184.0793.33
(8.16)		109.34
(7.76)		100.65
(8.86)
Octanal3.583.146.738.134.893.8193.35
(9.64)		108.75
(8.40)		104.46
(8.23)
Nonanal3.652.535.634.856.899.4298.21
(8.85)		109.34
(7.42)		106.14
(7.66)
Decanal1.362.564.846.635.476.96101.43
(3.88)		108.51
(4.60)		103.60
(6.02)
Table 4. Comparative table of analytical methodologies reported for aldehyde determination.
Table 4. Comparative table of analytical methodologies reported for aldehyde determination.
AldehydesMethodologySample TreatmentReagentAnalytical MethodLODREF
Malondialdehyde, 4-hydroxy-2-hexenal, 4-hydroxy-2-nonenal, 2,4-decadienalLLE followed by derivatizationLLEDNPHLC-MS/MS0.02–0.14 mg kg−1[11]
4-Hydroxy-nonenalLLE followed by derivatizationLLEPentafluorophenylhydrazineUHPLC-MS/MS10.9 nM[58]
Hexanal and HeptanalSynthesized levofloxacin-hydrazide-based mass tags (LHMTs) combined with dummy magnetic molecularly imprinted polymers.Magnetic dispersive solid-phase extraction using dummy molecularly imprinted polymers (DMMIPs)Levofloxacin-hydrazide-based mass tags (LHMTs, laboratory-synthesized)UHPLC–MS/MS0.5 pM[55]
Formaldehyde, acetaldehyde, propanal, butanal, pentanal, hexanal, heptanalMicro solid-phase extraction using a custom-prepared cyclodextrin-based polymer sorbentμ-SPE-DDNPHμ-SPE-D-HPLC.0.024–2.5 μg L−1[56]
Hexanal and heptanalDNPH adsorbed onto the surface of magnetite/silica/poly(methacrylic acid-co-ethylene glycol dimethacrylate) (Fe3O4/SiO2/P(MAA-co-EGDMAMagnetic solid-phase extraction coupled with in situ derivatization (MSPE-ISD)DNPHMSPE-ISD-HPLC-UV1.7–2.5 nmol L−1[28]
4-hydroxy-2-nonenal, 2,4-decadienal, 2,4-heptadienal, 4-hydroxy-2-hexenal, acrolein, 2-heptenal, 2-octenal, 4,5-epoxy-2decadal, 2-decenal, and 2-undecenal.LLE followed by derivatizationLLEDNPHUFLC-DAD-ESI-MS0.03–0.1 mg L−1[59]
trans-2-butenal, trans-2-pentenal, trans-2-hexenal, trans-2-heptenal, trans-2-octenal, trans-2-nonenal, trans-2-decenal and trans-2-undecenal LLE2-hydrazinopyridine and 2-hydrazino-5-methylpyridineDCBI-MS/MS0.03–0.18 mg L−1[57]
Pentanal, hexanal, heptanal, octanal, nonanal and decanalDNPH-alginate sphere-based derivatizationLLEDNPHHPLC-DAD0.77–1.41 mg L−1This work
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Santiago-Martinez, F.E.; Rodriguez, J.A.; Santos, E.M.; Mondragon-Portocarrero, A.C.; Lopez-Tellez, J. Application of Calcium Alginate Spheres Modified with 2,4-Dinitrophenylhydrazine During the Determination of Fatty Aldehydes in Edible Oils by HPLC-DAD. Separations 2026, 13, 75. https://doi.org/10.3390/separations13020075

AMA Style

Santiago-Martinez FE, Rodriguez JA, Santos EM, Mondragon-Portocarrero AC, Lopez-Tellez J. Application of Calcium Alginate Spheres Modified with 2,4-Dinitrophenylhydrazine During the Determination of Fatty Aldehydes in Edible Oils by HPLC-DAD. Separations. 2026; 13(2):75. https://doi.org/10.3390/separations13020075

Chicago/Turabian Style

Santiago-Martinez, F. Esmeralda, Jose A. Rodriguez, Eva M. Santos, Alicia C. Mondragon-Portocarrero, and Jorge Lopez-Tellez. 2026. "Application of Calcium Alginate Spheres Modified with 2,4-Dinitrophenylhydrazine During the Determination of Fatty Aldehydes in Edible Oils by HPLC-DAD" Separations 13, no. 2: 75. https://doi.org/10.3390/separations13020075

APA Style

Santiago-Martinez, F. E., Rodriguez, J. A., Santos, E. M., Mondragon-Portocarrero, A. C., & Lopez-Tellez, J. (2026). Application of Calcium Alginate Spheres Modified with 2,4-Dinitrophenylhydrazine During the Determination of Fatty Aldehydes in Edible Oils by HPLC-DAD. Separations, 13(2), 75. https://doi.org/10.3390/separations13020075

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