Sage (
The most common sage extract preparations are those in ethanol, methanol, or essential oil, given the high efficiency of the extraction process (3). However, these extracts can contain organic solvents or high monoterpene concentrations that can be toxic (8) and cause adverse effects as reported for thujone and camphor (9, 10), or 1,8-cineole and pinene (11), despite their antimutagenic or neuroprotective effects.
Considering the growing interest in the development of environmentally friendly extraction procedures to prepare extracts with good antioxidant, geno- and neuroprotective, and immunomodulatory effects that do not entail adverse toxicities, the aim of our study was to analyse the properties of a lyophilised sage leave extract obtained by extraction with deionised water and to test its biological effects on primary human peripheral blood cells. Our hypothesis was that aqueous extraction could provide high concentrations of biologically active protective compounds and reduce the levels of compounds that could be toxic in high concentrations.
To that end we used a range of non-cytotoxic sage extract concentrations to assess their antioxidant, antigenotoxic, immunomodulatory, and neuroprotective effects. To the best of our knowledge, this is the first such investigation in primary human blood cells.
Dried sage leaves (serial number: 24100920) purchased from the Dr Josif Pančić Institute of Medicinal Plant Research, Belgrade, Serbia, were ground, poured over with boiling deionised water (10:1 water-to-sage ratio), left for 90 min at room temperature, and filtered through a 5–13 μm pore filter paper (Lab Logistic Group, Meckenheim, Germany). The obtained extract was frozen at −20 °C and freeze-dried under a vacuum pressure of 400 Pa to obtain a dry lyophilisate. The lyophilisate was then dissolved in deionised sterile water and filtered through a 0.2 μm Minisart® filter (Sartorius, Göttingen, Germany).
The total phenolic and flavonoid content (TPC and TFC, respectively) of the aqueous sage extracts was determined as described by Singleton et al. (14) and Chang et al. (15), respectively, with slight modifications adapted for 96-well microplates. Gallic acid (Sigma-Aldrich, St. Louis, MO, USA) was used to construct the calibration curve for TPC measurements, and its concentrations in water ranged from 0.625 μg/mL to 80 μg/mL, while the sage extract was analysed in concentrations of 0.125, 0.25, and 0.5 mg/mL. Quercetin (Sigma-Aldrich) was used to construct the calibration curve for TFC in concentrations ranging from 0.625 μg/mL to 80 μg/mL, while the sage extract was analysed in concentrations of 0.75, 1.25, and 1.75 mg/mL. The absorbance for TPC was read at 700 nm and for TFC at 415 nm on a microplate reader (Sunrise, Tecan Group Ltd, Männedorf, Switzerland). TPC is expressed as mg of gallic acid equivalents (GAE) per g of dried extract (de), and TFC as mg of quercetin equivalents (QE) per g of dried extract (de).
GC-MS was used to identify the most abundant compounds in the aqueous sage extract. To that end we dissolved the lyophilisate in 1 mL of deionised water, separated the organic aliquot by liquid-liquid extraction with n-hexane, and analysed it with an Agilent 7890B gas chromatograph coupled with a 5977 MSD mass detector and equipped with an HP-5 MS inert capillary column
To assess the biological effects of aqueous sage extracts, we collected 10 mL of peripheral blood from each of the three healthy male volunteers aged 30–40 years in Li-heparin vacutainers (Becton Dickinson, Plymouth, UK). All volunteers read and signed the informed consent. The study was conducted in accordance with the Declaration of Helsinki and was approved by the Ethics Committee of the Vinča Institute of Nuclear Sciences, Serbia (approval No. 116-5-2/2023-000).
In whole blood we ran the cytokinesis block micronucleus (CBMN) assay, and measured interleukin levels and glutathione reductase (GR) activity. In PBMCs isolated from whole blood we evaluated cell viability and ran the prooxidant-antioxidant balance (PAB) assay.
PBMCs were isolated in a lymphocyte separation medium (Capricorn Scientific, Ebsdorfergrund, Germany) and resuspended in a RPMI 1640 medium (Capricorn Scientific) supplemented with 10 % foetal bovine serum (FBS, Capricorn Scientific) and 1 % penicillin-streptomycin (Gibco, Thermo Fisher Scientific, Waltham, MA, USA). The seeding density was 1×106 viable cells/mL. All treatments with sage extracts in concentrations ranging from 0.075 to 2.25 mg/mL lasted 24 h.
After sage extract treatment we ran the trypan blue (TB) assay following the procedure described by Strober (19) to determine the range of non-cytotoxic concentrations. Equal volumes of PBMC suspension and 0.4 % trypan blue dye were mixed and applied to a haemocytometer (Cambridge Instruments Inc., Buffalo, NY, USA). Cell viability is expressed as a percentage of viable cells compared to untreated control (100 %).
Glutathione reductase (GR) is an intracellular enzyme that restores intracellular glutathione (GSH) by reducing glutathione disulphide (GSSG) in the presence of nicotinamide adenine dinucleotide phosphate (NADPH) and flavin adenine dinucleotide (FAD). GR activity (mU/mL) was measured in whole blood samples treated with aqueous sage extract as described by Mannervik (20) and calculated using the following Equation 2:
The effects of the aqueous sage extract on the oxidative status of PBMCs were assessed with the PAB assay as described by Alamdari et al. (21). The PBMCs were pre-treated with the extract 5 h prior to H2O2 treatment (200 μmol/L) to evaluate the ability of the extract to reduce the oxidative stress.
Optical density (OD) was measured at 450 nm (reference wavelength was 570 nm) on an absorbance microplate reader (Sunrise). PAB was expressed as percentage relative to control.
The genotoxicity of the aqueous sage extract and its antigenotoxic potential against H2O2-induced damage were assessed with the CBMN assay as described by Fenech (22). Aliquots of whole blood were grown in the RPMI 1640 medium supplemented with phytohaemagglutinin-M (PHA-M, Capricorn Scientific) to stimulate lymphocyte proliferation.
Cell cultures were treated with a range of non-cytotoxic sage extract concentrations to assess genotoxicity and pre-treated with the same concentrations 5 h before the addition of 200 μmol/L H2O2 to assess the extract's genoprotective potential. Untreated cells served as a negative and H2O2-treated cells as positive control. Micronuclei were scored on at least 1,000 binuclear cells using the AxioImager A1 (Carl Zeiss, Jena, Germany) microscope with magnifications of 400× and 1000×, according to the scoring criteria set by the International Human Micronucleus (HUMN) Project (23).
The cytokinesis-block proliferation index (CBPI) was calculated using the following Equation 3:
The effects of non-cytotoxic concentrations of sage extract on inflammation were determined by measuring the levels of interleukin 1β (IL-1β) and tumour necrosis factor α (TNF-α) in PHA-stimulated whole blood cell cultures. PHA is used to induce inflammation, as reported earlier (24, 25). IL-1β and TNF-α in cell culture supernatants were determined using the commercial LEGEND MAX™ Human IL-1β and TNF-α ELISA Kit (BioLegend, Inc., San Diego, CA, USA) according to the manufacturer's instructions. The OD values at 450 nm were measured using a microplate reader (Sunrise). The results are presented as pg/mL of IL-1β and TNF-α.
To determine the effect of the sage extract on AChE activity we used a modified Ellman method as described elsewhere (26, 27). Free AChE from electric eel (2 U/mL) was incubated with sage extract in 50 mmol/L of phosphate buffer (pH 8) at 37 °C for 15 min. After that, we started the reaction by adding 75 mmol/L of acetylthiocholine iodide as enzyme substrate and 0.1 mmol/L of 5,5′-dithio-bis (2-nitrobenzoic acid) (DTNB) as chromogenic reagent. The reaction went for 5 min and was stopped with 10 mmol/L of sodium dodecyl sulphate (SDS). The formed product, 5-thio-2-nitrobenzoic acid (TNB), was measured spectrophotometrically (Lambda 35 UV-Vis Spectrometer, Perkin Elmer) at 412 nm.
All experiments were performed in triplicate, and the results are presented as means ± standard deviations (mean±SD). We ran the analysis of variance ANOVA on the SPSS software for Windows 10, version 20 (IBM, Armonk, NY, USA). The level of significance is set to <0.05.
The total phenolic content of the sage extract investigated in this study was 162±3.51 mg GAE/g de, while the total flavonoid content was 39.47±4.31 mg QE/g de. Aqueous extraction yielded similar results as the methanol and ethanol extracts, which are considered the most efficient extraction agents (28, 29). To the best of our knowledge, there are but a few published papers describing water extraction of polyphenols and flavonoids from sage (30, 31, 32), and our extraction yield was higher.
GC-MS analysis identified 12 compounds, representing 98.06 % of the total sage leaf composition (Table 1). The main terpenoids in the extract were oxygenated monoterpenes camphor (15.47 %), α-terpineol (0.93 %), and β-thujone (0.89 %). The results for camphor content are within the published range from 5.08–25 % for different types of extracts (33, 34). The reported α- and β-thujone content, ranging from 7.07 to 21.85 % (35), is higher than in our aqueous extract. In fact, the content of β-thujone in our extract is very low. The literature data quite vary in this respect (33, 36, 37), as thujone content varies with drying conditions, harvesting time, seasonal variations, and geographic and climatic conditions. What may also influence sage extract composition are the temperature, time, solvent type, and particle size (38). Our extract was prepared by grinding and pouring it over with boiling deionised water, so we assume that the low thujone content and undetected 1,8-cineole and pinene are owed to grinding and high temperature, which increases evaporation of volatile components (3). In any case, given the reported toxicity (12, 13), low concentrations of monoterpenes found in our aqueous sage extract could be an advantage, as this lowers the risk of adverse effects.
Relative percentage of identified compounds in the aqueous sage extract
1 | α-terpineol | 1196 | 5.14 | 0.93 |
2 | β-thujone | 1103 | 5.93 | 0.89 |
3 | Camphor | 1143 | 6.36 | 15.47 |
4 | endo-Borneol | 1167 | 6.57 | 2.89 |
5 | α-Bornyl acetate | 1288 | 10.00 | 7.58 |
6 | Acetophenone | 1065 | 10.30 | 7.37 |
7 | 2,4 Di-tert butyl phenol | 1519 | 11.13 | 7.05 |
8 | Palmitic acid | 1968 | 15.71 | 18.71 |
9 | Linoleic acid | 2172 | 17.10 | 8.16 |
10 | Monopalmitin | 2498 | 17.65 | 3.74 |
11 | 3-hydroxypropyl palmitate | 2361 | 18.96 | 11.89 |
12 | α-glycerol monostearate | 2806 | 20.00 | 13.39 |
RRI – relative retention indices; RT – retention time
In turn, we determined high concentrations of palmitic (18.71 %) and linoleic acid (8.16 %), similar to other reported data (39).
Figure 1 shows that our aqueous sage extract inhibited the DPPH• radical in a concentration-dependent manner, reaching the highest inhibition of 90 % with the concentration of 0.07 mg/mL. The calculated IC50 value was 0.032 mg/mL. The literature reports that the radical-scavenging activity of different sage extracts and essential oils varies greatly, from 116.5 μg/mL to 6.7 mg/mL, and that aqueous extract is the most potent (40, 41, 42). Our results are within the reported range but lower than those reported for the aqueous extract.
Scavenging properties of aqueous sage extract determined with the DPPH• (A) and ABTS•+ assay (B) and expressed as a percentage of inhibition compared to control
The IC50 value of ABTS•+ radical scavenging activity was 7 μg/mL. The maximum inhibition of 60 % was achieved with the concentration of 0.02 mg/mL (Figure 1B). IC50 values reported in other studies range from 50.79 μg/mL to 88.2±2.3 μg/mL (40, 41). Stronger ABTS•+ radical inhibition by our aqueous extract compared to other studies is in line with the DPPH• scavenging results and reveals potent antioxidant activity, most likely owed to the high phenolic and flavonoid content (30, 31).
Figure 2 shows concentration-dependent extract cytotoxicity measured with the TB assay, which was significant at 0.625 mg/mL (69.47 % of viable cells,
Viability of peripheral blood mononuclear cells treated with different concentrations (0.075–2.25 mg/mL) of aqueous sage extract for 24 h compared to untreated control. **
There are several reports of sage cytotoxicity as mostly concentration-dependent but also dependent on the extraction procedure and cell type used in the experiments. Vieira et al. (40) reported cell-type-specific cytotoxicity of ethanol and aqueous extracts, which was lower with the aqueous extract. Similarly, other studies (41, 43) reported concentration-dependent cytotoxicity of methanol extracts ranging from 50 μg/mL in malignant cell lines to more than 800 μg/mL in the control HUVEC cell line, or to 5.7 mg/mL for an ethanol extract in the HepG2 cell line. To the best of our knowledge, no study has yet reported the viability of PBMCs exposed to sage extracts. Lower IC50 values obtained in our study are probably owed to the physiological characteristics of PBMCs, as we speak of terminally differentiated cells that cannot progress through the cell cycle and divide without phytohaemagglutinin (PHA) stimulation. This is why we had to further evaluate the effects of non-cytotoxic aqueous sage extract concentrations on the cell proliferation of PHA-stimulated PBMCs with the CBMN assay (see below).
The antioxidant potential of the sage extract was determined by measuring GR activity in the whole blood samples treated for 24 h. GR activity was significantly elevated at the concentrations ranging from 0.075 to 0.625 mg/mL (Figure 3). On the contrary, the highest tested concentration decreased GR activity, probably due to lower cell viability (Figure 2), limited cellular uptake capacity and/or the ability of sage extract components to activate the enzyme (41).
Glutathione reductase activity (mU/mL) in untreated control whole blood samples and those treated with increasing concentrations of aqueous sage extract. **
So far, we demonstrated that our sage extract had an antioxidant effect through a strong radical-scavenging activity and activation of GR, and yet it did not induce oxidative stress. In the experiments that followed we examined the effect of extract pre-treatment on H2O2-induced genomic damage and oxidative balance. As expected, PBMC treatment with 200 μmol/L of H2O2 led to a significant increase in PAB values compared to control (
Prooxidant-antioxidant balance in untreated (control) peripheral blood mononuclear cells vs those treated with H2O2, aqueous sage extract, and their combination (presented as a percentage of untreated control). *
As for the genotoxic effects, the frequency of micronuclei (MN) in PHA-stimulated PBMCs treated with the sage extract did not differ significantly from untreated control (Figure 5). In the cells treated with H2O2 (200 μmol/L) it increased significantly, but pre-treatment with the sage extract countered this effect even at the lowest tested concentration, while the higher concentrations lowered MN frequency to near control values.
Micronucleus frequency in peripheral blood cells: untreated controls, H2O2-treated, sage extract-treated, and pre-treated with sage extract followed by H2O2 (presented as a percentage of untreated control). *
Figure 6 shows that the proliferation of PBMCs treated with H2O2 (200 μmol/L) or sage extract (regardless of the concentration) does not significantly differ from control. However, sage extract pre-treatment significantly lowered proliferation at the highest tested concentrations compared to control or H2O2 treatment. A possible explanation of this phenomenon might be in the pro-apoptotic activity of sage through the mitochondrial/caspase pathway (44, 45), which could only be achieved at higher extract concentrations.
Cytokinesis-block proliferation indices (CBPI) of peripheral blood cells: untreated controls, H2O2-treated, sage extract-treated, and pre-treated with sage extract followed by H2O2 (presented as a percentage of untreated control). *
Figure 7 shows the anti-inflammatory effects of the aqueous sage extract in PHA-stimulated peripheral blood cells. There is a concentration-dependent decrease in TNF-α levels, significant at all tested concentrations (
Pro-inflammatory cytokine levels, IL-1β (A) and TNF-α (B), in PHA-stimulated peripheral blood cells treated with aqueous sage extract in different concentrations. *
Earlier studies reported the neuroprotective effects of sage through cholinergic binding properties
AChE inhibition expressed as percentage of inhibited control activity
0.075 | 0 |
0.125 | 0 |
0.625 | 16 |
1.25 | 31 |
10 | 41 |
The advantages of aqueous extraction and lyophilisation of sage leaves are numerous. Aqueous extraction removes the environmental and cytotoxic risks pertinent to organic solvents used as extraction agents, yet yields high concentrations of beneficial bioactive compounds and lowers the concentration of those potentially toxic. High phenolic and flavonoid content provides strong anti-oxidative defence and genoprotection to human peripheral blood cells, which, combined with immunomodulatory properties, might contribute to the prevention of oxidative stress and inflammatory-related diseases. Additionally, AChE inhibition is mild, which points to the extract's neuroprotective role. However, caution is advised with doses used in medicinal preparations, as concentrations higher than 0.625 mg/mL could annul its benefits and cause adverse effects on cells.