Chemical Investigations in Kelussia odoratissima Mozaff. Leaves Based on Comprehensive Analytical Methods: LC-MS, SPME, and GC-MS Analyses
by
, , ,
Mehdi Rahimmalek
1,2,*,
Antoni Szumny
1,*
,
Shima Gharibi
3,
Natalia Pachura
1,
Mehran Miroliaei
4 and
Jacek Łyczko
1 1
Department of Food Chemistry and Biocatalysis, Wrocław University of Environmental and Life Sciences, 50-375 Wrocław, Poland
2
Department of Horticulture, College of Agriculture, Isfahan University of Technology, Isfahan 84156-83111, Iran
3
Core Research Facilities (CRF), Isfahan University of Medical Sciences, Isfahan 81746-73461, Iran
4
Faculty of Biological Science and Technology, Department of Cell and Molecular Biology and Microbiology, University of Isfahan, Isfahan 81746-73441, Iran
*
Authors to whom correspondence should be addressed.
Molecules 2023, 28(16), 6140; https://doi.org/10.3390/molecules28166140
Submission received: 25 July 2023
/
Revised: 11 August 2023
/
Accepted: 16 August 2023
/
Published: 19 August 2023
(This article belongs to the Special Issue Chemistry of Essential Oils: The Incredible Wealth of Plants)
Abstract
:Kelussia odoratissima Mozaff. is a species of Apiaceae endemic to the Zagros Mountains in Iran. In the present investigation, for the first time, the polyphenolic compounds and flavonoids of its leaves were determined by liquid chromatography-mass spectrometry (LC-MS). As a result, p-coumaric acid, ferulic acid, caffeic acid, chlorogenic acid, acetyl phloroglucinol, vanillic acid, m-coumaric acid, and 4-methylsiringol were determined as the main phenolic compounds, while 3-hydroxyflavone, flavone, quercetin, rutin, neohesperidin, polydatin, and diosmin were the main flavonoid components, of which chlorogenic acid (303.08 µL/gDW), neohesperidin (38.37 µL/gDw), and diosmin (28.62 µL/gDW) were the most abundant. Solid-phase microextraction (SPME) was also used to determine the chemical compounds. Based on SPME, (Z)-undec-6-en-2-one (17.48%) and (Z)-butylidenephthalide (4.348%) were the major components. Based on GC-MS analyses, (Z)-ligustilide was the main compound; however, some new compounds were also determined, including 3-ethylisobenzofuran-1 (3H)-one, (E)-ligugustilide, and E-n-butylidene phthalide. Also, for the first time, we have identified EOs ethyl and isobutyl phthalides on the basis of the obtained EI-MS spectra. Finally, the fragmentation of phthalides is also discussed in this research.
1. Introduction
Kelussia odoratissima Mozaff. belongs to the Apiaceae family and is an endemic plant of Iran. It grows mainly in the western part of the Zagros Mountains. This species is an aromatic medicinal plant that is mostly used as a spice as well as for some therapeutic purposes [1]. It is an endangered species because of rough harvesting of the plants in natural habitats. Kelussia dried herbs have been consumed as traditional spices by the local people. In addition, both the leaves and seeds have been used for food and pharmaceutical purposes [2,3]. For instance, the fresh parts have been used in preparation prickles products. For Kelussia herbs, different activities have been reported such as sedative and anxiolytic [4], cytotoxicity [5], antioxidant [6], analgesic, and anti-inflammatory activities [7].
The application of different analytical methods under one experimental condition and the same plant material can provide new information for further decision making about the studied plant’s use in different food or pharmaceutical industries. From this point of view, volatiles and non-volatiles are considered crucial components of the plant for further industry processes. Gas chromatography based on mass spectrophotometry (GC-MS) is used for determining the terpenoids, while the solid-phase microextraction (SPME) method is a valuable method for determining the aroma of the plants. Finally, liquid-chromatography-mass spectrometry (LC-MS) is a robust method for non-volatile identifications [8]. Since SPME data mostly apply to the determination of the aroma of plants, it can provide more detailed information regarding the aroma in spice plants like Kelussia. Furthermore, the combination of SPME and oil GC-MS analyses can provide new insights for further sensory analyses for use of the spice in some food products.
Most previous reports on the determination of Kelussia focused on essential oil components in different habitats [3], different organs [9], and different drying methods [10]. As predominated compounds such as alkyl-alkenyl phthalide derivatives were detected in Kelussia leaves, e.g., isomers of ligustilide, and cis-3-butyldene phthalide [10], they were affected by drying treatments but no isobutyl- or ethyl phthalides were detected in this report. Alkyl or alkenyl phthalides are found in plants from the Apiaceae family, e.g., Levisticum, Apium, Angelica, Cnidium, Ligusticum [11]. Moreover, there are previous studies on the composition of oil in Kelussia is reported; however, there are no reports regards the fragmentation of phthalides in this species.
As many health benefit compounds are categorized in the non-volatile group of compounds, determination of these components can be further beneficial for formulations of pharmaceutical or food products. However, there is no report regarding the determination of non-volatiles, especially phenolic and flavonoid compounds of this endemic species. Moreover, this is the first comprehensive report to use three different analytical methods for the determination of volatiles and non-volatiles in K. odoratissima.
The objective of this study is to determine the polyphenolic compounds of K. odoratissima based on LC-MS, as well as the oil components, and the aroma using GC-MS and SPME analyses.
2. Results and Discussion
2.1. Phenolic and Flavonoid Compounds
In the present research, phenolic and flavonoid compounds were determined using LC-MS analysis. Table 1 illustrates the details of the MRM mode analysis for the identified compounds. Accordingly, p-coumaric acid, ferulic acid, caffeic acid, chlorogenic acid, acetyl phloroglucinol, vanillic acid, m-coumaric acid, and 4-methylsiringol were determined as the main phenolic compounds. Among the phenolic acids, chlorogenic acid (303.08 µL/gDw of the sample) and 4-methylsiringol (57.03 µL/gDw) were revealed to be present in the highest amounts, while caffeic acid (1.94 µL/gDw) showed the lowest value (Table 2). In previous research, among polyphenolics, only ferulic acid was determined in Kelussia aerial parts based on vacuum- LC techniques [12]
Different types of flavonoids were also observed in the Kelussia sample. Based on LC-MS data, 3-hydroxyflavone, flavone, quercetin, rutin, neohesperidin, polydatin, and diosmin were the major flavonoid components in the Kelussia leaves. Consequently, neohesperidin (38.4 ± 0.87 µg/gDw) and diosmin (28.62 ± 0.76 µg/gDw) were the main flavonoid compounds (Table 3). Interestingly, neohesperidin was established for the first time in the leaves of Kelussia. However, hesperidin and diosmin were also reported in Crithmum maritimum, a halophyte plant of the Apiaceae family [13]. Diosmin was also reported in the seeds of Notopterygium franchetii from the Apiaceae family [14]. These flavonoids possess similar structures and activities such as hypolipidemic, diuretic, anticancer, and anti-hypertensive qualities [13]. Moreover, previous studies have revealed that diosmin can prevent fat accumulation and glucose intolerance with high anti-dyslipidemic effect [14]. Furthermore, Moieni et al. [15] also reported the anti-diabetic and anti-atherosclerotic properties of Kelussia which might be attributed to some groups of flavonoids like diosmin. Based on previous research, the flavonoid patterns of fruits and leaves are different, as Khanavi et al. [1] determined five flavonol glycosides including isorhamnetin 3-O-glucoside, quercetin 3-O-glucoside, isorhamnetin 3-O-rutinoside, isorhamnetin 3-O-glucuronide, and quercetin 3-O-glucuronide in Kelussia fruits. Finally, based on the literature, the polyphenolic and flavonoid pattern of Kelussia leaves is more similar to Ferula orientalis L. since in this species chlorogenic acid and diosmin were the main polyphenolic compounds [16].
2.2. GC-MS SPME-Arrow Results
Table 4 illustrates the results of SPME. For this analysis, according to the SPME data, 50 compounds were obtained in which different metabolites such as monoterpenes, sesquiterpenes, and different kinds of phthalides such as 3-butylphthalide, 3-butylidenephthalide, cis-butylidenephthalide, and (Z)-ligustilide were determined. Consequently, (Z)-undec-6-en-2-one (15.08%) and (Z)-butylidenephthalide (4.348%) were the main compounds. (Z)-undec-6-en-2-one has not been detected before in plants from Apiaceae family [17].
Hashemi et al. [18] also used SPME in aerial parts of Kelussia; however, the results of the present research included most of the compounds. Hashemi et al. [18] established butylphthalide as the most abundant in compound in the leaves, while in the present study, (Z)-undec-6-en-2-one was the most frequent compound. Furthermore, in our study, different types of phthalides were determined. Analysis of the spectra obtained by the SPME technique also revealed the presence of ethylphthalide (0.06%), hitherto unpresented in the NIST20 database. It is probably synthesized, such us other phthalides, by condensation of malonyl Co-A via 5-methylorsellinic acid [19]. Its structure was established on the basis of its EI-MS spectrum (Figure 1) according to the fragmentation of phthalidephthalides proposed by Diao et al. [20]. Appropriate cation-radicals with m/z 162, 133, and finally 105 are in the figure with a proposed structure.
Figure 1.
Proposed EI-MS fragmentation of ethylphthalide on the basis of https://doi.org/10.1124/dmd.112.049684, accessed on 1 July 2023.
Figure 1.
Proposed EI-MS fragmentation of ethylphthalide on the basis of https://doi.org/10.1124/dmd.112.049684, accessed on 1 July 2023.
Figure 2.
EI-MS of unknown compound (Table 1, SPME) 15.30 min.
Figure 2.
EI-MS of unknown compound (Table 1, SPME) 15.30 min.
Figure 3.
EI-MS of unknown compound (Table 1, SPME) 20.77 min.
Figure 3.
EI-MS of unknown compound (Table 1, SPME) 20.77 min.
Figure 4.
EI-MS of unknown compound (Table 1, SPME) 24.65 min.
Figure 4.
EI-MS of unknown compound (Table 1, SPME) 24.65 min.
2.3. Essential Oils Composition
The results obtained by GC-MS (liquid injection) were different in comparison to the SPME technique. This is due to the fact that some EOs are covered by glandular tissues [8]. In some families like Lamiaceae, the essential oils are mostly accumulated in secretory hairs, while in some other families like Apiaceae, the oils are mostly found in secretory sacs or sometimes canals. In Apiaceae leaves, the canals are mostly distributed near the main vein and occasionally in the mesophyll [21]. So, in Kelussia, an Apiaceae plant, the analyses based on the oil might lead to the determination of some compounds in secretory sacs or canals. However, in this research, the high quality and accuracy of the SPME-arrow technique provided a relatively a high number of new compounds.
Based on the GC-MS analysis of essential oils, (Z)-ligustilide was determined to be the major compound in the leaves (Table 5). The results are in the range (51.3–58.7%) of those reported in previous studies [3,10]. However, in the present research, new compounds were also determined that were not previously reported. The new components were 3-ethylisobenzofuran-1(3H)-one, (E)-ligustilide, and (E)-n-butylidene phthalide. Asuming et al. [22] also reported different types of phthalides in four Lomatium species from North America. Many alkenyl or alkyl phthalide derivatives possess strong antibacterial, antifungal, and cytotoxic activity. What makes these derivatives unique is that some monomeric phthalides have a positive impact on the central nervous system and possess a proven effect in slowing down Parkinson and Alzheimer disease [11].
The presence of phthalide compounds in Kelussia was previously proven by Pan et al. [23]. They also reported the hepatotoxicity of furan-containing components in the cortex Dictamni and the correlation with metabolic activation. The new reports also highlighted the importance of ligustillides as an antidepressant compound using bioinformatic methods to determine the mechanisms [24]. Furthermore, anti-inflammatory and antioxidant activities have also been reported for these compounds [25]. In addition, two never before described phthalide derivatives (ethyl and butenylphthalides, 0.06 and 0.09%, respectively) were found in Kelussia EO. Fragmentation of the mass of these compounds with RT 28.02 min revealed the characteristic butylphthalide pattern m/z: 190/148/133/105. Due to the high similarity (in comparison of the EI-MS spectrum presented in NIST20 n-buthylphthalide and the lower (about 50) retention index value), we assume the isobutyl isomer to be the only one possible. Also, the characteristic spectra (m/z: 160/145/119/119) with a pattern similar to valerophenone could suggest the presence of its unsaturated derivative. The proposed EI-MS fragmentation of ethylphthalide is illustrated in Figure 1. Furthermore, the EI-MS of unknown compounds (Table 1, SPME) at 20.77 min and (Table 1, SPME) 24.65 min are shown in Figure 2, Figure 3 and Figure 4, respectively. Finally, the proposed fragmentation of some compounds is also illustrated in Figure 5 and Figure 6.
3. Materials and Methods
3.1. Liquid Chromatography Mass Spectrometry
3.1.1. Sample Preparation
For this purpose, 1 g of Kelussia dried leaves was used for the extraction. Consequently, 15 mL of pure methanol (Sigma-Aldrich, Steinheim, Germany) was added to the ground samples. After shaking for 1 h on the shaker (120 rpm), the extracts were separated from the residues. This part was repeated three times. Then, rotary evaporator (Heidolph, Germany) was used to dry the extract. Finally, the dried samples were resolved in pure methanol. Then, after centrifuge (12,000 rpm, 5 min), the pure extract was diluted 1:10 and was used for the LC-MS injection.
3.1.2. Instrumental Analysis
The analysis of phenolic acids and flavonoids content was carried out with the LC-MS 8045 apparatus (Shimadzu, Kyoto, Japan) equipped with ESI type ion source. The separation of analytes was performed with a Prominence-I LC-2030C 3D Plus (Shimadzu, Kyoto, Japan) unit equipped with a Kinetex 2.6 µm C18 100A 100 × 3.0 mm column with a Security Guard ULTRA 3 mm (Phenomenex, Torrance, CA, USA).
We used 0.1% aqueous formic acid (A) and methanol with 0.1% of formic acid (B) (Sigma-Aldrich, Steinheim, Germany) as mobile phases. The gradient programme was as follows: from 10% to 20% B in 0–5 min; from 20% to 60% B in 5–10 min; from 60% to 10% B in 10–13 min; 10% B up to 17 min. The mobile phase flow was 0.35 mL·min−1 at 35 °C.
The screening of non-volatiles was carried out with polyphenols: standard mixture of phenolic acids and alcohols and polyphenols: standard flavonoids mixtures (MetaSci, Toronto, ON, Canada).
The identified compounds were quantified using the MRM mode (Table 1) referring to the calibration curve. The analyses were performed in three repetitions.
3.2. HS-SPME Arrow GC/MS Analysis
Sample Preparation
First, 50 mg of dried sample (not ground) were used for the SPME analysis. The samples were placed in special glasses for SPME along with the internal standard (2-undecaneone). Prior to the analysis, the lack of internal standard was proven.
Volatile extraction was carried out with 1.10 mm DVB/C-WR/PDMS SPME Arrow fibre (Shimadzu, Kyoto, Japan). Before the analysis, the samples were preconditioned at 45 °C and then the volatiles were extracted for 30 min at the same temperature. After the extraction, the analytes were desorbed under GC/MS injector conditions.
Volatile analysis was performed with Shimadzu GCMS QP 2020 Plus (Shimadzu, Kyoto, Japan) equipped with a Zebron ZB-5 MSi capillary chamber (30 m × 0.25 mm × 0.25 μm; Phenomenex, Torrance, CA, USA). The injection was carried out at 250 °C and split 40; helium with a column flow of 1.0 nL·min−1 was used as a carrier gas. The analytes separation was performed with the following temperature program: 50 °C, then to 130 °C at a rate of 4 °C·min−1, then to 180 °C at a rate of 10 °C·min−1, then to 280 °C at a rate of 20 °C·min−1. The MS operational conditions were as follows: interface temperature 250 °C; ion source temperature 250 °C; scan mode 40–400 m/z.
The identification of analytes was performed by comparison of the experimentally obtained mass spectra and linear retention indices (±10) with those available in the library of Flavours and Fragrances of Natural and Synthetic Compounds 3.0 (FFNSC 3.0) and the NIST/EPA/NIH EI Mass Spectral Library (NIST 20), Gaithersburg, MD, USA.
The quantification of volatiles was based on GC-MS signals. The quantification was carried out with the peak area normalization method calculated against the peak area of the internal standard. The analyses were performed in three repetitions.
Authentic standards of volatiles were bought from MetaSci (Toronto, ON, Canada), Aldrich and UQF (Wroclaw, Poland).
3.3. Essential Oil Isolation
The distillation was carried out on Kelussia leaves using a Deryng-type apparatus based on the method described by Pachura et al. [8]. Accordingly, 100 g of dried Kelussia leaves, along with 1 mg of undecan-2-one (Sigma-Aldrich, Steinheim, Germany) as an internal standard, were applied. The distillation was carried out in a round bottom flask containing 400 mL of distilled water. Hydro-distillation was carried out for 1.5 h after reaching the boiling point and then the essential oils were transferred to a container and stored at −18 °C. The distillations were run in triplicate.
3.4. GC-MS Analysis
Essential oils were analyzed using a gas chromatograph coupled to a mass spectrometer (Shimadzu GC-MS QP 2020, Shimadzu, Kyoto, Japan). Compounds separation was carried out using a Zebron ZB-5 MSi capillary column (30 m × 0.25 mm × 0.25 µm; Phenomenex, Torrance, CA, USA). GC-MS analysis parameters were as follows: scan range 35–320 m/z in mode of 3 scans·s−1. Helium was used as the carrier gas at a flow rate of 1.01 mL·min−1, with a split ratio of 1:30. The temperature for GC was as follows: from 45 °C as initial temperature to 150 °C at a rate of 2 °C·min−1, then to 270 °C at a rate of 15 °C for 5 min. The injection volume was 1 µL. The mass unit was set at an ion source temperature of 240 °C and an ionization voltage of 70 eV. The oil retention indices were calculated using the retention time of the n-alkane series (C7–C24) (Adams, 2007) as well as NIST as was described in section HS-SPME Arrow analyses. The amount of oils was obtained from the GC/MS peak using Spectrus software.
4. Conclusions
In the present investigation, comprehensive research was carried out to assess most of the volatile and non-volatile compounds in Kelussia odoratissima, an endangered endemic species of Iran. Accordingly, for the first time, the phenolic and flavonoid compounds were determined based on the LC-MS analysis in which chlorogenic acid, neohesperidin, and diosmin were the most abundant compounds for phenolics and flavonoids. Furthermore, based on a thorough analysis of SPME, 78 compounds that belonged to different groups of terpenes and phthalides were determined. Furthermore, the GC-MS analysis also supported the SPME data in most cases. Finally, the introduction of new volatiles and non-volatiles in this valuable endemic plant can provide an insight for further research into pharmaceutical and food science in the future.
Author Contributions
M.R. contributed to the extractions and analysis, data interpretation, and manuscript editing. J.Ł. performed the LC-MS, analyzed the data, and wrote the initial draft of the article. S.G. did the extractions and GC-MS and prepared the data. N.P. did the SPME results interpretation A.S. helped with GC-MS, SPME interpretation as well as editing of the final version of the manuscript. M.M. helps us to interpret the data. All authors have read and agreed to the published version of the manuscript.
Funding
We thank the Polish National Agency for Academic Exchange (NAWA) Ulam 2021 program under grant number BPN.ULM.2021.1.00250.U.00001 for supporting this study. The APC is financed by Wrocław University of Environmental and Life Sciences.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
The data are available upon request.
Conflicts of Interest
The authors declare no conflict of interest.
Sample Availability
Not applicable.
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Figure 5.
Proposed fragmentation of compound 20.44 min, 3-penten-1-one, 1-phenyl- and EI-MS spectrum of compound.
Figure 5.
Proposed fragmentation of compound 20.44 min, 3-penten-1-one, 1-phenyl- and EI-MS spectrum of compound.
Figure 6.
Proposed fragmentation of compound 28.04 min, isobuthylphthalide and EI-MS spectrum of compound.
Figure 6.
Proposed fragmentation of compound 28.04 min, isobuthylphthalide and EI-MS spectrum of compound.
Table 1.
Details of the MRM mode analysis for identified compounds.
| Compound | Precursor m/z [M−H]− | Product m/z | Relative Product Ions Abundance [%] | Q1 Pre Bias 1 (V) | CE 2 | Q3 Pre Bias 3 (V) |
|---|---|---|---|---|---|---|
| 3-Hydroxyflavone * | 238.9 | 164.9 | 100 | −12.0 | −33.0 | −25.0 |
| 120.95 | 51 | −26.0 | −29.0 | −18.0 | ||
| 104.95 | 25 | −12.0 | −30.0 | −15.0 | ||
| Flavone * | 222.9 | 76.8 | 100 | −11.0 | −38.0 | −29.0 |
| 120.95 | 7 | −11.0 | −29.0 | −18.0 | ||
| 64.8 | 9 | −11.0 | −46.0 | −24.0 | ||
| Quercetin | 300.9 | 150.9 | 100 | 14.0 | 24.0 | 28.0 |
| 178.95 | 48 | 14.0 | 17.0 | 11.0 | ||
| 106.9 | 25 | 14.0 | 29.0 | 20.0 | ||
| Neohespederin dihydrohalcone | 611.1 | 303.0 | 100 | 28.0 | 35.0 | 20.0 |
| 125.0 | 27 | 28.0 | 45.0 | 24.0 | ||
| 165.9 | 5 | 28.0 | 55.0 | 16.0 | ||
| Rutin | 609.0 | 301.0 | 57 | 30.0 | 27.0 | 19.0 |
| 285.9 | 6 | 30.0 | 44.0 | 17.0 | ||
| 299.05 | 100 | 28.0 | 28.0 | 19.0 | ||
| Neohesperidin | 609.0 | 300.95 | 100 | 28.0 | 27.0 | 20.0 |
| 286.0 | 30 | 30.0 | 43.0 | 17.0 | ||
| 164.0 | 11 | 28.0 | 54.0 | 16.0 | ||
| Polydatin | 389.0 | 321.0 | 50 | 19.0 | 12.0 | 23.0 |
| 343.1 | 100 | 20.0 | 14.0 | 24.0 | ||
| Diosmin | 607.0 | 299.2 | 100 | 30.0 | 30.0 | 20.0 |
| 283.7 | 29 | 30.0 | 49.0 | 18.0 | ||
| p-Coumaric acid | 163.0 | 119.05 | 100 | 15.0 | 16.0 | 22.0 |
| 92.95 | 7 | 16.0 | 31.0 | 17.0 | ||
| 91.05 | 14 | 15.0 | 29.0 | 13.0 | ||
| Ferullic acid | 193.4 | 134.0 | 100 | 12.0 | 14.0 | 26.0 |
| 177.95 | 61 | 12.0 | 15.0 | 30.0 | ||
| 149.05 | 19 | 12.0 | 13.0 | 14.0 | ||
| Caffeic acid | 179.5 | 134.95 | 100 | 11.0 | 16.0 | 25.0 |
| 134.65 | 27 | 11.0 | 30.0 | 23.0 | ||
| 106.95 | 3 | 11.0 | 22.0 | 19.0 | ||
| Chlorogenic acid | 353.0 | 191.0 | 100 | 16 | 17.0 | 20.0 |
| 84.95 | 21 | 16 | 43.0 | 16.0 | ||
| 92.95 | 5 | 16 | 46.0 | 17.0 | ||
| Acetylphloroglucinol | 167.5 | 123.0 | 100 | 11.0 | 17.0 | 24.0 |
| 80.95 | 29 | 10.0 | 22.0 | 15.0 | ||
| 83.0 | 31 | 11.0 | 24.0 | 16.0 | ||
| m-Coumaric acid | 163.4 | 119.0 | 100 | 10.0 | 15.0 | 23.0 |
| 4-Methylsiringol | 167.3 | 123.0 | 100 | 26.0 | 13.0 | 26.0 |
| 108.0 | 64 | 10.0 | 15.0 | 11.0 |
* Compounds analysed with a positive ionization mode [M + H]+; 1 voltage promotes the ionization of the precursor ion; 2 collision energy; 3 voltage promotes the ionization of the product ion.
Table 2.
The amount of phenolic acids in the studied Kelussia leaves.
| Compounds | RT [min] | Concentration (µg/gDw) |
|---|---|---|
| Chlorogenic acid | 4.65 | 303.08 ± 1.9 |
| Vanillic acid | 4.97 | 28.02 ± 0.9 |
| 4-Methylsiringol | 4.97 | 57.03 ± 0.85 |
| Acetylphloroglucinol | 4.98 | 21.66 ± 0.64 |
| Caffeic acid | 5.20 | 1.94 ± 0.44 |
| p-Coumaric acid | 6.42 | 2.14 ± 0.53 |
| m-Coumaric acid | 6.42 | 2.93 ± 0.25 |
| Ferullic acid | 6.84 | 62.60 ± 1.2 |
Table 3.
The flavonoids amount in the studied Kelussia leaves.
| Compounds | RT [min] | Concentration (µg/gDw) |
|---|---|---|
| Polydatin | 1.40 | 1.15 ± 0.34 |
| Neohesperidin dihydrochalcone | 6.46 | 0.09 ± 0.12 |
| Neohesperidin | 6.46 | 38.37 ± 0.87 |
| Rutin | 6.48 | 23.08 ± 0.11 |
| Flavone | 8.76 | 1.07 ± 0.86 |
| 3-Hydroxyflavone | 8.85 | 0.20 ± 0.09 |
| Diosmin | 9.84 | 28.62 ± 0.76 |
| Quercetin | 9.88 | 0.87 ± 0.08 |
Table 4.
SPME profile of the Kelussia leaves.
| Nr | Peak Name | tR (min) | KI Exp. | KI Lit. | Area (%) e | Identification | Similarity d |
|---|---|---|---|---|---|---|---|
| 1 | Isobutyric acid | 3.19 | 770 | 756 | 1.22 | S, KI, MS | 95 |
| 2 | Butanoic acid | 3.63 | 801 | 802 | 13.75 | S, KI, MS | 92 |
| 3 | n-Hexanal | 3.95 | 803 | 801 | 2.10 | S, KI, MS | 90 |
| 4 | Isovaleric acid | 4.61 | 845 | 850 | 1.96 | S, KI, MS | 92 |
| 6 | Butanoic acid, 2-methyl- | 4.87 | 855 | 861 | 2.26 | S, KI, MS | 89 |
| 7 | 2-(E)-Hexenal | 5.08 | 862 | 864 | 0.01 | S, KI, MS | 86 |
| 8 | Pentanoic acid | 5.55 | 899 | 901 | 1.17 | S, KI, MS | 84 |
| 9 | trans-2-Pentenoic acid | 5.83 | 905 | 909 | 1.37 | S, KI, MS | 85 |
| 11 | Hexanal, 3-methyl- | 6.17 | 908 | 910 | 0.72 | S, KI, MS | 90 |
| 12 | Acetylfuran | 6.47 | 926 | 911 | 0.26 | KI, MS | 89 |
| 13 | Benzene, propyl- | 6.57 | 926 | 953 | 0.21 | KI, MS | 91 |
| 14 | 2-Heptenal, (E)- | 7.75 | 960 | 958 | 0.16 | KI, MS | 93 |
| 15 | Benzaldehyde | 7.92 | 970 | 962 | 0.23 | S, KI, MS | 95 |
| 16 | 1-Heptanol | 8.12 | 976 | 970 | 0.18 | S, KI, MS | 90 |
| 17 | 4-Octanone | 8.24 | 979 | 975 | 0.61 | KI, MS | 92 |
| 18 | Hexanoic acid | 8.34 | 982 | 990 | 1.41 | S, KI, MS | 87 |
| 19 | 5-Hepten-2-one, 6-methyl- | 8.67 | 991 | 986 | 0.23 | KI, MS | 96 |
| 20 | Furan, 2-pentyl- | 8.81 | 997 | 993 | 0.12 | KI, MS | 91 |
| 21 | 2-Ethylhexenal | 9.11 | 1004 | 999 | 0.062 | KI, MS | 93 |
| 22 | Octanal | 9.17 | 1006 | 1003 | 1.96 | S, KI, MS | 94 |
| 23 | 3-Hexenoic acid, (E)- | 9.42 | 1014 | 1021 | 0.70 | KI, MS | 91 |
| 24 | p-Cymene | 9.90 | 1031 | 1025 | 0.09 | S, KI, MS | 94 |
| 25 | Limonene | 10.03 | 1035 | 1031 | 0.21 | S, KI, MS | 90 |
| 26 | Benzyl alcohol | 10.23 | 1041 | 1036 | 0.31 | S, KI, MS | 93 |
| 28 | Phenylethanal | 10.59 | 1052 | 1045 | 0.68 | KI, MS | 89 |
| 29 | 4-Hexanolide | 10.95 | 1062 | 1057 | 0.06 | KI, MS | 87 |
| 30 | 2-Octenal, (E)- | 11.02 | 1062 | 1060 | 0.16 | S, KI, MS | 91 |
| 31 | 2-Acetylpyrrole | 11.105 | 1068 | 1663 | 0.41 | KI, MS | 88 |
| 32 | Octanol | 11.44 | 1075 | 1071 | 0.48 | S, KI, MS | 90 |
| 33 | 3,5-Octadien-2-one | 12.24 | 1097 | 1091 | 0.57 | KI, MS | 91 |
| 34 | Linalool | 12.44 | 1099 | 1099 | 0.08 | S, KI, MS | 95 |
| 35 | Nonanal | 12.59 | 1099 | 1104 | 4.95 | S, KI, MS | 94 |
| 36 | Octadienol <(2E,4E)-> | 12.79 | 1114 | 1116 | 0.28 | S, KI, MS | 92 |
| 37 | Phenylethyl Alcohol | 12.96 | 1119 | 1116 | 0.67 | S, KI, MS | 90 |
| 38 | Camphor | 14.09 | 1150 | 1142 | 0.18 | S, KI, MS | 94 |
| 39 | Benzene, pentyl- | 14.46 | 1163 | 1157 | 0.55 | KI, MS | 90 |
| 40 | Octanoic acid | 14.85 | 1174 | 1180 | 0.68 | S, KI, MS | 89 |
| 41 | Menthol | 15.02 | 1178 | 1174 | 0.38 | S, KI, MS | 91 |
| 42 | Unknown a | 15.30 | 1186 | n.d. | 0.18 | - | - |
| 43 | p-Cymen-8-ol | 15.47 | 1190 | 1183 | 0.18 | S, KI, MS | 93 |
| 44 | Estragole | 15.94 | 1203 | 1196 | 0.10 | S, KI, MS | 91 |
| 45 | Decanal | 16.13 | 1207 | 1206 | 0.38 | S, KI, MS | 89 |
| 46 | Carvone | 17.52 | 1253 | 1246 | 1.19 | S, KI, MS | 92 |
| 47 | Piperitone oxide | 17.91 | 1263 | 1256 | 0.70 | S, KI, MS | 93 |
| 48 | 2-Decenal, (E)- | 18.06 | 1271 | 1263 | 0.49 | KI, MS | 92 |
| 49 | n-Nonanoic acid | 18.20 | 1271 | 1273 | 0.67 | S, KI, MS | 88 |
| 50 | (Z)-6-Undecen-2-one | 18.59 | 1282 | 1274 | 15.09 | KI, MS | 92 |
| 51 | 1-Tridecyne | 18.70 | 1286 | 1297 | 0.55 | KI, MS | 90 |
| 52 | IS | 19.13 | 1297 | 1294 | 15.41 | S, KI, MS | 95 |
| 53 | unknown b | 20.77 | 1352 | n.d. | 0.26 | - | - |
| 54 | Ylangene | 20.98 | 1365 | 1372 | 0.25 | KI, MS | 92 |
| 55 | Valerophenone | 21.15 | 1368 | 1373 | 2.17 | KI, MS | 91 |
| 56 | 2-Undecenal, (Z)- | 21.30 | 1373 | n.d. | 0.60 | KI, MS | 93 |
| 57 | Copaene | 21.69 | 1387 | 1376 | 1.28 | KI, MS | 90 |
| 58 | Hexanoic acid, hexyl ester | 21.85 | 1391 | 1384 | 0.13 | KI, MS | 89 |
| 59 | Tetradecane | 22.14 | 1400 | 1400 | 0.26 | S, KI, MS | 85 |
| 60 | Dodecanal | 22.38 | 1411 | 1408 | 0.30 | S, KI, MS | 92 |
| 61 | α-Barbatene | 22.73 | 1435 | 1435 | 0.27 | KI, MS | 90 |
| 62 | Ethylphthalide * | 23.38 | 1464 | n.d. | 1.26 | MS | - |
| 63 | Acoradien | 23.66 | 1480 | 1471 | 0.87 | KI, MS | 93 |
| 64 | 4-epi-α-Acoradiene | 23.81 | 1486 | 1475 | 0.81 | KI, MS | 91 |
| 65 | α-Curcumene | 23.90 | 1491 | 1483 | 0.59 | S, KI, MS | 95 |
| 66 | Cuparene | 24.39 | 1521 | 1505 | 2.19 | KI, MS | 93 |
| 67 | Cubebol | 24.54 | 1532 | 1515 | 0.36 | KI, MS | 89 |
| 68 | unknown c | 24.65 | 1538 | n.d. | 1.20 | - | - |
| 69 | Kessane | 24.78 | 1548 | 1537 | 2.24 | KI, MS | 90 |
| 70 | Actinidiolide, dihydro- | 24.84 | 1551 | 1534 | 1.04 | KI, MS | 93 |
Table 5.
The essential oil composition of Kelussia based on GC-MS on distilled essential oil.
| Peak Name | tR (min) | KI Exp. | KI Lit. | Area (%) | Identification | Similarity a |
|---|---|---|---|---|---|---|
| Isocumene * | 7.217 | 956 | 953 | 0.087 | KI, MS | 94 |
| Heptenol (3-Z) | 7.286 | 959 | 954 | 0.039 | KI, MS | 92 |
| 4-Octanone | 7.734 | 974 | 976 | 0.042 | KI, MS | 95 |
| 2-Ethyl-2-hexenal | 8.576 | 1001 | 990 | 0.097 | KI, MS | 91 |
| Limonene | 9.491 | 1033 | 1031 | 0.073 | S, KI, MS | 95 |
| Terpinolene | 11.45 | 1090 | 1088 | 0.068 | S, KI, MS | 97 |
| 5-Pentylcyclohexa-1,3-diene | 13.802 | 1162 | 1161 | 0.854 | KI, MS | 91 |
| Carvone | 16.729 | 1248 | 1242 | 0.09 | S, KI, MS | 93 |
| (Z)-Undec-6-en-2-one | 17.802 | 1279 | 1279 | 2.233 | KI, MS | 90 |
| 2-Undecanone (IS) | 18.381 | 1295 | 1294 | 7.489 | S, KI, MS | 93 |
| 2-Methoxy-4-vinylphenol | 19.116 | 1318 | 1318 | 0.508 | KI, MS | 89 |
| 3-Penten-1-one, 1-phenyl- * | 20.433 | 1360 | n.d. | 0.383 | MS | 92 |
| Copaene | 21.108 | 1380 | 1376 | 0.209 | KI, MS | 94 |
| trans-β-Caryophyllene | 22.504 | 1424 | 1419 | 0.069 | S, KI, MS | 94 |
| β-Barbatene | 23.245 | 1449 | 1451 | 0.062 | KI, MS | 92 |
| Ethylphthalide * | 23.459 | 1455 | n.d. | 0.064 | MS | 92 |
| Acoradien | 23.984 | 1472 | 1471 | 0.134 | KI, MS | - |
| α-Curcumene | 24.405 | 1485 | 1483 | 0.085 | S, KI, MS | 91 |
| β-Ionone | 24.816 | 1498 | 1491 | 0.12 | S, KI, MS | 96 |
| Cuparene | 25.14 | 1509 | 1505 | 0.329 | KI, MS | 93 |
| Cubebol | 25.478 | 1521 | 1515 | 0.119 | KI, MS | 91 |
| δ-Cadinene | 25.644 | 1527 | 1524 | 0.234 | KI, MS | 89 |
| Kessane | 25.8 | 1533 | 1537 | 0.587 | KI, MS | 92 |
| Caryophyllene oxide | 27.42 | 1587 | 1581 | 0.181 | S, KI, MS | 92 |
| Isobutylphthalide | 28.025 | 1608 | n.d. | 0.098 | MS | - |
| Humulene epoxide II | 28.164 | 1613 | 1608 | 0.127 | KI, MS | 94 |
| γ-Eudesmol | 28.489 | 1626 | 1630 | 0.042 | KI, MS | 92 |
| Cubenol | 28.686 | 1633 | 1642 | 0.077 | KI, MS | 88 |
| Gossonorol | 28.926 | 1642 | 1640 | 0.085 | KI, MS | 92 |
| 3-n-Butylphthalide | 29.337 | 1656 | 1656 | 0.682 | S, KI, MS | 93 |
| (Z)-n-Butylidene phthalide | 29.97 | 1678 | 1675 | 11.57 | S, KI, MS | 95 |
| unknown | 30.096 | 1683 | n.d. | 0.463 | - | - |
| (E)-n-Butylidene phthalide | 31.16 | 1723 | 1722 | 2.092 | KI, MS | 93 |
| (Z)-Ligustilide | 31.797 | 1748 | 1740 | 50.479 | S, KI, MS | 92 |
| (E)-Ligustilide | 33.195 | 1802 | 1810 | 1.455 | S, KI, MS | 93 |
S: authentical standard, KI: Kovat’s index, MS: mass spectrum; a similarity match according to LabSolution v. 4.45. * The new identified compounds.
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Rahimmalek, M.; Szumny, A.; Gharibi, S.; Pachura, N.; Miroliaei, M.; Łyczko, J. Chemical Investigations in Kelussia odoratissima Mozaff. Leaves Based on Comprehensive Analytical Methods: LC-MS, SPME, and GC-MS Analyses. Molecules 2023, 28, 6140. https://doi.org/10.3390/molecules28166140
AMA Style
Rahimmalek M, Szumny A, Gharibi S, Pachura N, Miroliaei M, Łyczko J. Chemical Investigations in Kelussia odoratissima Mozaff. Leaves Based on Comprehensive Analytical Methods: LC-MS, SPME, and GC-MS Analyses. Molecules. 2023; 28(16):6140. https://doi.org/10.3390/molecules28166140
Chicago/Turabian StyleRahimmalek, Mehdi, Antoni Szumny, Shima Gharibi, Natalia Pachura, Mehran Miroliaei, and Jacek Łyczko. 2023. "Chemical Investigations in Kelussia odoratissima Mozaff. Leaves Based on Comprehensive Analytical Methods: LC-MS, SPME, and GC-MS Analyses" Molecules 28, no. 16: 6140. https://doi.org/10.3390/molecules28166140
