Protective Action Mechanisms of Launaea mucronata Extract and Its Nano-Formulation against Nephrotoxicity in Rats as Revealed via Biochemical, Histopathological, and UPLC-QTOF–MS/MS Analyses
Abstract
:1. Introduction
2. Materials and Methods
2.1. Plant Material and Collection
2.2. Extract Preparation
2.3. High-Resolution Ultra-Performance Liquid Chromatography-Mass Spectrometry Analysis (UPLC-qTOF-MS)
2.4. Biosynthesis of the Silver Nanoparticles of LMNS
2.5. UV–Vis Spectra and Transmission Electron Microscopy (TEM) Measurements of LMNS
2.6. Bioassays
2.6.1. Drugs and Chemicals
2.6.2. Acute Toxicity
2.6.3. Experimental Animals and Ethical Treatments
2.6.4. Experimental Design
2.6.5. Blood Collection and Tissue Preparation
2.6.6. Assays for Kidney Function
2.6.7. Biochemical Assessment of Renal Tissue
2.6.8. Histopathological Assays
Light Microscopic Examination
Immunohistochemical Examination
2.6.9. Statistical Analysis
3. Results
3.1. LME’ Phytochemical Profiling Using UPLC-QTOF–MS/MS
3.2. Identification of Hydroxycinnamic and Hydroxy Benzoic Acids
3.2.1. Identification of Coumarins
3.2.2. Identification of Flavonoids
3.2.3. Identification of Fatty and Organic Acids
3.3. Chemical Biosynthesis of LMNS
3.3.1. UV–Vis Spectroscopic Analysis of LMNS
3.3.2. TEM Results of LMNS
3.4. Biological Results
3.4.1. LD50 Assay’ Result
3.4.2. Effect on Urea and Creatinine
3.4.3. Effect on Catalyzing Enzymes (Catalase and UGTs) and Nrf2
3.4.4. Effect on Inflammation Biomarkers (COX-2 and PGE2)
3.4.5. Effect on the MAPK/ERK Pathway
3.4.6. Histopathological Examination
Light Microscopic Observations
Immunohistochemical Examination of Cyclo-Oxygenase 2 (COX-2)
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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No. | Rt. | m/z | [M−H]−/[M+H]+ | MS/MS | Error (ppm) | Tentative Identification |
---|---|---|---|---|---|---|
1 | 0.951 | 191.0561 | C7H11O6− | 127 | −2.54 | Quinic acid |
2 | 1.003 | 133.0142 | C4H5O5− | 115 | 4.08 | Malic acid |
3 | 1.059 | 290.0881 | C11H16NO8− | 200, 128 | −8.11 | Deoxy-dehydro-N-acetyl neuraminic acid |
4 | 1.493 | 167.0197 | C4H7O7− | 124 | −8.18 | Tartaric acid |
5 | 2.569 | 163.0401 | C9H7O3− | 145, 119 | −1.42 | P-coumaric acid |
6 | 2.843 | 169.0142 | C7H5O5− | 125 | −2.05 | Gallic acid |
7 | 3.558 | 341.0878 | C15H17O9− | 179, 161 | −0.57 | Caffeoyl hexose |
8 | 7.426 | 315.0722 | C13H15O9− | 153 | −4.89 | Protocatechuic acid-O-hexoside |
9 | 7.565 | 137.0244 | C7H5O3− | 119 | −2.05 | p-hydroxy benzoic acid |
10 | 8.137 | 311.0409 | C13H11O9− | 179, 149 | −0.78 | Caffeoyl tartaric acid |
11 | 8.402 | 137.0244 | C7H6O3− | 93 | −0.6 | Salicylic acid |
12 | 8.537 | 353.0878 | C16H17O9− | 191 | −1.68 | Chlorogenic acid |
13 | 8.610 | 325.0929 | C15H17O8− | 191, 173 | −1.56 | Coumaroyl hexoside |
14 | 8.680 | 177.019 | C9H5O4− | 89 | −1.5 | Aesculetin |
15 | 8.710 | 339.0722 | C15H15O9− | 177 | −0.72 | Aesculin |
16 | 8.854 | 313.0929 | C14H17O8− | 179 | 0.35 | Unknown caffeic acid derivative |
17 | 9.353 | 179.035 | C9H7O4− | 135 | −1.76 | Caffeic acid |
18 | 9.722 | 515.0831 | C24H19O13− | 353 | −0.36 | Chlorogenic acid hexoside |
19 | 9.827 | 611.1607 | C27H31O16+ | 449, 287 | 2.56 | Luteolin- dihexoside |
20 | 10.134 | 595.1657 | C27H31O15+ | 449, 287 | 3.44 | Luteolin-O-rutinoside |
21 | 10.152 | 461.0725 | C21H17O12− | 285 | 0.11 | Luteolin-O-glucuronic acid |
22 | 10.277 | 447.0933 | C21H19O11− | 285 | 1.87 | Luteolin-O-hexoside |
23 | 10.291 | 443.1042 | C15H23O15− | 285 | 4.15 | Unknown luteolin derivative |
24 | 10.349 | 195.0652 | C10H11O4+ | 179 | 0.95 | Ferulic acid |
25 | 10.451 | 515.1195 | C25H23O12− | 353, 191 | 0.97 | Di-caffeoylquinic acid |
26 | 10.464 | 197.1172 | C11H16O3+ | 179, 133 | 1.64 | Unknown phenolic acid |
27 | 10.745 | 433.1129 | C21H21O10+ | 271 | 2.37 | Apigenin-O-hexoside |
28 | 10.670 | 445.0776 | C21H17O11− | 269 | −1.04 | Unknown apigenin derivative |
29 | 10.758 | 447.0922 | C21H19O11+ | 271 | 2.44 | Apigenin-O-glucuronic acid |
30 | 10.934 | 187.0976 | C9H15O4− | 143 | −0.09 | Nonanedioic acid |
31 | 11.004 | 211.0965 | C11H15O4+ | 179 | 8.02 | Unknown caffeic acid derivative |
32 | 11.129 | 227.1278 | C12H19O4+ | 209 | 1.26 | Hydroxy jasmonic acid |
33 | 11.618 | 461.1078 | C22H21O11+ | 271 | 1.6 | Unknown apigenin derivative |
34 | 11.823 | 285.0405 | C15H9O6− | 257, 199 | −2.58 | Luteolin |
35 | 11.889 | 571.0882 | C30H19O12− | 285 | −1.57 | Unknown Luteolin derivative |
36 | 12.182 | 209.1536 | C13H21O2+ | 173 | 1.47 | Tridecatrienoic acid |
37 | 12.515 | 269.0455 | C15H9O5− | 117 | −2.42 | Apigenin |
38 | 12.540 | 331.2479 | C18H35O5+ | 313 | 2.42 | Trihydroxy-octadecenoic acid |
39 | 12.549 | 337.0354 | C18H9O7− | 269 | 5.85 | Unknown apigenin derivative |
40 | 13.087 | 301.202 | C16H29O5− | 283 | 0.49 | Hydroxy hexadecanedioic acid |
41 | 13.22 | 287.2228 | C16H31O4− | 269 | −1.79 | Dihydroxy hexadecanoic acid |
42 | 13.782 | 941.5162 | C45H83O16P2− | - | 7.3 | Phosphatidylinositol phosphate (18:0/18:2) |
43 | 14.648 | 318.3003 | C18H40NO3+ | 303 | 1.8 | Amino octadecanetriol |
44 | 17.273 | 295.2268 | C18H31O3− | 277 | 1.6 | Hydroxy octadecdienoic acid |
45 | 19.08 | 271.2279 | C16H31O3− | 225 | −1.22 | Hydroxy-palmitic acid |
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El-Fadaly, A.A.; Younis, I.Y.; Abdelhameed, M.F.; Ahmed, Y.H.; Ragab, T.I.M.; El Gendy, A.E.-N.G.; Farag, M.A.; Elshamy, A.I.; Elgamal, A.M. Protective Action Mechanisms of Launaea mucronata Extract and Its Nano-Formulation against Nephrotoxicity in Rats as Revealed via Biochemical, Histopathological, and UPLC-QTOF–MS/MS Analyses. Metabolites 2023, 13, 786. https://doi.org/10.3390/metabo13070786
El-Fadaly AA, Younis IY, Abdelhameed MF, Ahmed YH, Ragab TIM, El Gendy AE-NG, Farag MA, Elshamy AI, Elgamal AM. Protective Action Mechanisms of Launaea mucronata Extract and Its Nano-Formulation against Nephrotoxicity in Rats as Revealed via Biochemical, Histopathological, and UPLC-QTOF–MS/MS Analyses. Metabolites. 2023; 13(7):786. https://doi.org/10.3390/metabo13070786
Chicago/Turabian StyleEl-Fadaly, Amany A., Inas Y. Younis, Mohamed F. Abdelhameed, Yasmine H. Ahmed, Tamer I. M. Ragab, Abd El-Nasser G. El Gendy, Mohamed A. Farag, Abdelsamed I. Elshamy, and Abdelbaset M. Elgamal. 2023. "Protective Action Mechanisms of Launaea mucronata Extract and Its Nano-Formulation against Nephrotoxicity in Rats as Revealed via Biochemical, Histopathological, and UPLC-QTOF–MS/MS Analyses" Metabolites 13, no. 7: 786. https://doi.org/10.3390/metabo13070786
APA StyleEl-Fadaly, A. A., Younis, I. Y., Abdelhameed, M. F., Ahmed, Y. H., Ragab, T. I. M., El Gendy, A. E. -N. G., Farag, M. A., Elshamy, A. I., & Elgamal, A. M. (2023). Protective Action Mechanisms of Launaea mucronata Extract and Its Nano-Formulation against Nephrotoxicity in Rats as Revealed via Biochemical, Histopathological, and UPLC-QTOF–MS/MS Analyses. Metabolites, 13(7), 786. https://doi.org/10.3390/metabo13070786