P U B L I C A T I O N S CODON Italian Journal of Food Science, 2023; 35 (1): 41–48 ISSN 1120-1770 online, DOI 10.15586/ijfs.v35i1.2219 41 Qualitative characteristics of four Sicilian monofloral honeys from Apis mellifera ssp. sicula Paola Bambina1, Francesca Malvano2, Claudio Cinquanta2, Donatella Albanese2, Andrea Cirrito1, Francesca Mazza1, Onofrio Corona1* 1Department of Agricultural, Food and Forest Sciences University of Palermo, Viale delle Scienze, 90128 Palermo, Italy; 2Department of Industrial Engineering, University of Salerno, Via Giovanni Paolo II, 84084 Fisciano, Italy *Corresponding Author: Onofrio Corona, Department of Agricultural, Food and Forest Sciences University of Palermo, Viale delle Scienze, Palermo, Italy. Email: onofrio.corona@unipa.it Received: 29 April 2022; Accepted: 24 November 2022; Published: 2 February 2023 © 2023 Codon Publications OPEN ACCESS PAPER Abstract Four monofloral honeys, obtained from the Sicilian black bee by foraging on thistle, sulla, chestnut and eucalyp- tus, were studied. Results showed that the phenolic composition of chestnut honey was the highest (316 mg gallic acid equivalent GAE/kg), while that of sulla honey was the lowest (122 mg GAE/kg). Data confirmed a correla- tion between the total phenol content and colour intensity in chestnut honey, which was the darkest of the four samples. Sulla honey showed the highest antioxidant activity, while eucalyptus honey had the highest mineral content (K, Ca, Mg, and Na). Thistle honey showed the most intense floral and fruity aromas, as well as an intense yellow colour. Principal component analysis showed the potential to discriminate different honeys in three differ- ent quadrants. Keywords: colour; honey; sensory analysis; Sicilian black bee Introduction The composition of honey varies due to differences in botanical, geographical and entomological origins, and is also influenced by the seasonal, production and stor- age conditions (Wang et al., 2022). The European Union (EU, 2014) has imposed strict labelling rules on honey, requiring that the botanical and geographical origins of honey be correctly labelled before sale (Thrasyvoulou et  al., 2018). Based on their botanical origins, honey products can be classified as monofloral or multiflo- ral. The commercial value of monofloral honey is much higher than that of multifloral honey due to its unique aroma and taste, which are in greater demand by con- sumers (Marcazzan et al., 2014). To confirm the typical- ity of honey, it is necessary to identify its botanical origin, generally through melissopalynological analysis. Honey can also be classified according to its geographical origin, considering that, in addition to the influence of the flower species, the physico-chemical and sensory characteristics of honey may vary according to the subspecies of bees (Silva et al., 2016). The Sicilian black bee (Apis mellifera ssp. sicula) is an African subspecies of A. mellifera that has adapted to the warm lands of the Mediterranean, including Sicily (Italy) (Mannina et  al., 2015). It dif- fers from the more common A. mellifera ssp. ligustica in the colour and size of its wings, as well as in the fact that it is more resistant to high temperatures, allowing it to tolerate temperatures above 40°C, whereas other subspecies of bees do not produce honey under such extreme conditions (Attanzio et  al., 2016). A. mellifera ssp. sicula also possesses considerable immunological resistance, enabling it not to succumb to varroasis nor virosis (Franck et  al., 2000). A. mellifera ssp. sicula has a pronounced pollination capacity that ensures the con- tinuity of many plant species, including some that are in danger of extinction. This subspecies risked extinction in the 1970s, when beekeepers imported the Ligustica sub- species into Sicily. Following this massive introduction, a group of entomologists and beekeepers recovered the 42 Italian Journal of Food Science, 2023; 35 (1) Bambina P et al. meter. The ash content was determined according to official methods (AOAC, 1999): about 5 g of honey was placed in a combustion pot preheated in the dark with a gas flame to prevent the honey from foaming. Then, the sample was incinerated (burned) at a high temperature (550°C) in a burning muffle furnace for 5 h. After cooling to room temperature, the ash obtained was weighed. The total polyphenol content was determined spectrophotometrically using a Folin– Ciocalteu method as reported by Singleton et al. (1999), with some modification. The results were expressed as gallic acid equivalents (GAE) per 100/g honey. Colour measurements were performed using a Konica Minolta chroma meter CR-C2500 (Konica Minolta Sensing Singapore Pte Ltd, Singapore). Results were recorded as a*, b*, and L* values, where a* is an index of redness (+) or green (−), b* an index of yellow (+) or blue (−), and L* indicates brightness on a scale of 0–100 (Adiletta et  al., 2020). The overall colour difference (ΔE), chroma (C) and hue angle (H°) were also calculated, where chroma indicates the dullness or vividness and hue angle indicates how an object’s colour is perceived by the human eye (red, orange, green or blue). The samples were placed in an optical glass cell for measurement. Glucose and fructose were determined by the HPLC system using an Agilent 1100 chromatograph with a refractive index  detector (Agilent, Santa Clara, USA) equipped with a Eurokat, 300 × 8 mm, 10 μm column (Knauer, Berlin, Germany). The mobile phase was a water solution with a flow rate of 1 mL/min and a column temperature of 80°C. The results were expressed as “mg glucose/g honey.” The antioxidant activity of honey was evaluated using the DDPH radical scavenging activity (Larrauri et  al., 1998) and expressed as μmol Trolox equivalents (TE)/g honey. All measurements were repeated three times. All results represent the average of three measurements per sample. Mineral content The mineral content of each honey sample was determined according to the procedure of Chudzinska et al. (2011), with some modifications. Two grams of each sample were dispersed in 5 mL HNO3 (65 %) and 1 mL H2O and then digested in a microwave digestion system (MARS 6, CEM, Matthews, NC, USA) by increasing the temperature up to 210°C. At the end of the procedure, after appropriate dilutions with bi-distilled H2O, samples were analysed by inductively coupled plasma spectroscopy (iCAP 6200 DUO, Thermo Scientific, Waltham, MA, USA), and Ca, Fe, K, Mg, Na, Cu, Mn and Zn content were determined. Each sample was analysed in triplicate, and the reported results are the average of the three measurements. genetically pure Sicilian subspecies by transferring some old hives to the island of Ustica (PA), where the selected bees were bred without risk of contamination. A reinte- gration plan was then launched in western Sicily by the Slow Food Presidium founded in 2008. The plan included fertilization stations for pure repro- duction of A. mellifera ssp. sicula. Purity was periodically checked through genetic screening (Attanzio et al., 2016). The physico-chemical and sensorial properties of honey produced by A. mellifera ssp. sicula has thus been of sci- entific interest. The aim of this study was to evaluate, by means of sensory and physico-chemical analysis, the differences between four monofloral honeys obtained by A. mellifera ssp. sicula. Materials and Methods Honey samples Honey samples of thistle (Silybum marianum L.), sulla (Hedysarum coronarium L.), chestnut (Castanea sativa Mill.) and eucalyptus (Eucalyptus  globulus Labill.) were collected from Sicily from the 2019 production by Nettare di Sicilia, Caltavuturo (PA). Nettare di Sicilia is a company situated inside the Madonie Park and part of the Slow Food Presidium. The various monofloral honeys were produced by moving the bees to the most suitable environments in Sicily with the specific botanical spe- cies. Precisely, the honeys analysed were chestnut honey, produced in the Nebrodi Nature Park in the province of Messina at an altitude of over 1000 m above sea level; sulla honey, produced in a hilly area in the Madonie Park at around 700 m above sea level; eucalyptus honey, pro- duced in the province of Agrigento in a fairly arid area with small woods; and thistle honey, produced in the province of Palermo at sea level where this plant grows wild. All samples were classified by melissopalynological analysis (Soares et  al., 2017), whereby the pollen grains of the different botanical species were distinguishable by microscopic observation. Three different samples of honey from different hives were analysed for each of the four botanical species, all processed in the same way. Honey samples were kept away from sunlight at room temperature before analysis. Physico-chemical parameters The moisture content of each honey sample was determined from its refractive index using a digital refractometer (NR 101 Spain) thermostated at 20°C and regularly calibrated with distilled water (Bogdanov, 2009). The pH was assessed by the Crison GLP 21 pH Italian Journal of Food Science, 2023; 35 (1) 43 Qualitative characteristics of Sicilian monofloral honeys was controlled during processing (Table 1). Moisture in each analysed honey sample was around 14–15%, which is the optimal level, ensuring stability and spoilage resis- tance against yeast fermentation (Bacandritsos et  al., 2006) while prolonging shelf life and limiting granula- tion (Singh and Kuar Bath, 1997). The four monovarietal honey samples were all acidic, with pH values ranging between 2.96 (sulla honey) and 5.21 (chestnut honey). All of these values fall within the standard limit (pH 3.40– 6.10) (Codex Alimentarius, 2001), ensuring the freshness of the honey samples (Table 1). The low pH of honey is related to the fermentation of the sugars, which results in two important characteristics of honey: flavour and stability against microbial spoilage (Bogdanov, 2009). The ash content of honey is often used to determine its botanical origin (floral, blend or honeydew). Ash con- centrations in the honey samples ranged from 0.10 (sulla honey) to 0.79% (chestnut honey), which are all values within the limits allowed for floral honeys (0.60%) except for chestnut honey, in which ashes were present in a higher percentage, showing that it belongs to the dark honeys (Oddo et  al., 1995). The high ash content could explain the high pH value of the chestnut honey samples, being that ash depends on the constituents of the flora type, geographical area, physiology of the plants and soil type on which the plants from which the bees collect nectar grow. The total phenol content (Figure 1) was highest in chest- nut honey (316.3 mg GAE/Kg), followed by eucalyptus (193.5 mg GAE/Kg), thistle and sulla honey; these results are in agreement with those reported by Preti and Tarola (2022). The phenolic content of monofloral honeys of A. mellifera ssp. sicula varied according to the botanical origin of the plants from which the nectar was collected (Al-Mamary et  al., 2002; Amiot et  al., 1989). In Sicilian environments characterised by a warm climate and a high level of exposure to sunlight, the plants may con- tain many more total phenols than the same plant vari- eties grown in colder environments (Spayd et  al., 2002). Phenolic compounds are responsible for the colour and taste characteristics of honey and for multiple biological Sensory analysis The different honeys were judged by a trained panel of nine tasters (7 males and 2 females, aged between 24 and 48 years), consisting of technical experts. Twenty grams of honey was weighed into 200 cc transparent glasses, sealed with foil and kept at 20°C for 2 h before tasting. Samples were presented to each taster in random order. A descriptive sensory profile test based on quantitative descriptive analysis was used for the evaluation. Based on the frequency of citation (>60%), 17 descriptors were identified: three visual (yellow intensity, amber intensity and crystallisation), nine olfactory (ripe fruit, herba- ceous, floral, caramel, liquorice, beeswax, hay, medicinal and off-flavour), three gustatory (sweet, sour and bitter), one taste persistence and one overall liking. Each of the descriptors was measured on a structured intensity scale of 1–9, with 1 denoting absence and 9 denoting maxi- mum perception. Because all types of honey were suitable for trade, the Council of Ethics exempted the authors to ask for a formal ethical approval. The panelists did, how- ever, give verbal informed consent prior to participation. Statistical analysis Analysis of variance (ANOVA) and Tukey’s honest signif- icant difference test at a 5% level were used to compare analytical differences between samples. Principal compo- nent analysis (PCA) was performed to reduce the multi- dimensionality of the dataset, generating new principal components that accounted for most of the total variation. All statistical analyses were done using the SPSS software package, Version 20.0 (SPSS Inc., Chicago, IL, USA). Results and Discussion Physico-chemical traits The moisture content did not differ significantly (P  <  0.05) among the honey samples, as this parameter Table 1. Physico-chemical traits of different monofloroal honeys. Parameters Thistle Sulla Chestnut Eucalypt Water % 85.5 ± 0.501a 85.1 ± 0.47a 84.90 ± 0.50a 85.5 ± 0.48a Ash (g/100 g) 0.32 ± 0.02b 0.10 ± 0.01a 0.79 ± 0.06c 0.10 ± 0.01a pH 3.26 ± 0.04b 2.96 ± 0.04 a 5.21 ± 0.04c 3.30 ± 0.04b Sucrose (mg/g) 62.16 ± 4.51b 61.79 ± 5.63b 53.60 ± 6.87a 57.14 ± 7.85a Glucose (mg/g) 287.31 ± 16.22b 287.03 ± 17.51b 232.10 ± 19.58a 312.36 ± 28.11c Fructose (mg/g) 293.87 ± 22.76a 392.52 ± 34.26b 356.81 ± 41.85b 391.23 ± 49.27b DPPH (μmol TE/100g) 16.57 ± 0.05a 17.19 ± 0.01b 16.27 ± 0.04a 17.01 ± 0.03a,b Mean ± SD (n = 3) (different letters in the same row indicate significant differences for P ≤ 0.05, ANOVA, Tukey’s test). 44 Italian Journal of Food Science, 2023; 35 (1) Bambina P et al. but lowest for the sulla sample. The colour saturation (C) was highest for chestnut honey and was lowest for the sulla sample. For the parameter indicating colour hue, no significant variations were found in the three samples of thistle, sulla and eucalyptus, while chestnut had a slightly lower value than these three. Sucrose was highest in this- tle and sulla honey, and lowest in the chestnut sample. Glucose was present in concentrations of 232–312 mg/g of honey in chestnut and eucalyptus, while fructose was present in concentrations of 293–393  mg/g of honey in thistle and sulla. The antioxidant activity of honey mea- sured by DPPH protocol showed values between 16.27 and 17.19 μmol TE/100g, with sulla honey showing the highest activity. properties, such as antioxidant, antibacterial and radical- scavenging activities. Results reported by Karabagias et al. (2014) and Preti and Tarola (2022) confirmed the correlation between the total phenol content and colour intensity, with darker honeys having a higher phenolic content and antioxidant capac- ity. In this regard, it should be noted that the average value of the parameter a* (index of red) was about 9.3 for chestnut honey (Rodríguez-Flores et al., 2019), compared to values below 1.0 for the other three samples (Figure 2). The value of b* (yellow index) was also highest for chest- nut honey, while sulla honey showed the lowest value. The L* (lightness) value was highest for chestnut honey, b a d c a a c b b a c bb a c b c c a b 0 5 10 15 20 25 30 35 40 Thistle Sulla Chestnut Eucalyptus Mono�oral Honeys L* a* b* C HUE Figure 2. Colour traits of different monofloral honeys. Different letters indicate significant differences for P ≤ 0.05, ANOVA, Tukey’s test. Figure 1. Total phenol content (mg gallic acid equivalent/kg) in different monofloral honeys. Different letters indicate signifi- cant differences for P ≤ 0.05, ANOVA, Tukey’s test. 0 50 100 150 200 250 300 350 400 T o ta l p h e n o l c o n te n t (m g a c id g a lli c /K g ) Thistle ab a b c Sulla Chestnut Eucalyptus Mono�oral Honeys Italian Journal of Food Science, 2023; 35 (1) 45 Qualitative characteristics of Sicilian monofloral honeys thistle samples showed no significant (P < 0.05) differ- ences in the content of all analysed macro- and microele- ments except for K, which was higher in sulla honey. All the other elements, such as Fe, Cu, Mn and Zn, were present in traces in all samples. Sensory analysis Honey from different floral sources may have distinct aromas and flavours due to differences in volatile com- position, which in turn may depend on the geograph- ical origins (Manyi-Loh et  al., 2011). Sensory analysis of the sulla honey showed a high yellow intensity, with an advanced state of crystallisation (Figure 3). For the sense of smell, this honey registered the highest flo- ral value, while ripe fruitiness, beeswax and hay were less marked, owing to the presence of norisoprenoids Mineral content Chemical evaluation of the most common minerals pres- ent in honey samples was performed. According to the literature (Alves et al., 2013; Bontempo et al., 2017; Lobos et al., 2022), for all types of honey, the most abundant elements were, in decreasing order of con- centration, K, Ca, Mg and Na (Table 2). Eucalyptus honey contained the highest amount of potassium (884.55 mg/kg), which was significantly different (P  <  0.05) from thistle (527.93 mg/kg), chestnut (518.08 mg/kg) and sulla (422.38 mg/kg) samples. Ca and Mg were the most abundant macroelements in eucalyptus and chestnut honey, with respective values of 113.90 mg/kg and 14.46 mg/kg for eucalyptus and 120.38  mg/kg and 31.28 mg/kg for chestnut. Moreover, eucalyptus honey was also very rich in Na. Sulla and Table 2. Mineral content of different monofloroal honeys. Sample Ca (mg/kg) Fe (mg/kg) K (mg/kg) Mg (mg/kg) Na (mg/kg) Cu (mg/kg) Mn (mg/kg) Zn (mg/kg) Sulla 80.36 ± 4.56a 0.28 ± 0.02a 422.38 ± 23.24a 8.47 ± 1.02a 5.50 ± 0.95a 0.10 ± 0.02a 0.50 ± 0.10a 0.50 ± 0.08a Eucalyptus 113.90 ± 8.49b 1.47 ± 0.09c 884.55 ± 52.57c 14.46 ± 1.12b 84.10 ± 10.66b 0.20 ± 0.07b 1.00 ± 0.09b 0.80 ± 0.13b Thistle 90.19 ± 7.34a 0.27 ± 0.04a 527.93 ± 34.36b 9.50 ± 1.04a 6.30 ± 1.29a 0.10 ± 0.04a 0.40 ± 0.03a 0.60 ± 0.09a Chestnut 120.38 ± 10.12c 0.83 ± 0.11b 518.08 ± 42.31b 31.28 ± 3.12c 7.47 ± 0.84a 0.30 ± 0.06b 2.00 ± 0.24c 0.90 ± 0.16b Mean ± SD (n = 3) (different letters in the same row indicate significant differences for P ≤ 0.05, ANOVA, Tukey’s test). Figure 3. Sensory analysis of different monofloral honeys. Different letters indicate significant differences for P ≤ 0.05, ANOVA, Tukey’s test. Amber intensity (a-a-c-b) Crystallization (b-b-a-b) Ripe fruit (a-a-b-a) Herbal (b-b-a-ab) Floral (c-c-a-b) Caramel (a-a-b-b) Licorice (a-a-b-b) Beeswax (a-b-a-a)Hay (a-b-a-b) Medicinal (a-a-c-b) Off-Flavor Sweet (c-c-a-b) Acid (ab-bc-c-a) Bitter (ab-a-c-b) Gustatory persistence (ab-a-b-ab) Overall satisfaction (b-ab-a-ab) Yellow intensity (b-b-a-ab) Thistle Sulla Chestnut Eucalyptus 8 7 6 5 4 3 2 1 0 46 Italian Journal of Food Science, 2023; 35 (1) Bambina P et al. The thistle sample was characterised by the following sensory parameters: yellow intensity, crystallization, and ripe fruit odour. Conclusion The analysed Sicilian honeys, produced using the same techniques and obtained from black bees, showed differ- ent sensory and quality profiles. These differences reflect the botanical species and environmental characteristics in which the bees developed. The phenolic composition of honey, which is important from taste and health points of view, was the highest in chestnut honey and lowest in sulla honey. Ca and Mg were the most abundant macro- nutrients in chestnut and eucalyptus honey, with the lat- ter also containing the highest amount of potassium. The sensory analysis, which considered 17 descriptors (visual, olfactory, taste and persistence), showed that the over- all liking was higher for thistle honey, followed by sulla, eucalyptus and finally chestnut. References Adiletta, G., Di Matteo, M., Albanese, D., Farina V., Cinquanta, L., Corona, O., Magri, A. and Petriccione, M., 2020. Changes in physico-chemical traits and enzymes oxidative system during cold storage of “Formosa” papaya fresh cut fruits grown in the mediterranean area (Sicily). Italian Journal of Food Science. 32: 845–857. (Jerković et  al., 2010). 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The taste profile showed higher levels of sweetness with no acidity and bitterness. Principal component analysis The first two principal components explained 77.33 and 13.54% of the total variance, respectively (Figure 4). PCA showed the potential to discriminate different honeys in three different quadrants: the second quadrant showed thistle and eucalyptus honey, the third quadrant showed sulla honey, and the fourth quadrant showed chestnut honey. The PCA bi-plot showed a positive correlation between pH, a*, polyphenols and ash in chestnut honey. Figure 4. Principal component analysis of the physico-chemical and sensory traits in different monofloral honeys. 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