Skoči na glavni sadržaj

Izvorni znanstveni članak

https://doi.org/10.15567/mljekarstvo.2023.0304

Comparison of the nutritional quality and the fat globule size after six months of lactation of donkey and human milk

Jasmina Lazarević orcid id orcid.org/0000-0003-0538-3365 ; University of Novi Sad, Institute of Food Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Mirela Iličić orcid id orcid.org/0000-0003-4762-2897 ; University of Novi Sad, Faculty of Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Tatjana Peulić ; University of Novi Sad, Institute of Food Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Danka Dragojlović ; University of Novi Sad, Institute of Food Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Katarina Kanurić ; University of Novi Sad, Faculty of Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Ljiljana Popović ; University of Novi Sad, Faculty of Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Ivana Lončarević orcid id orcid.org/0000-0001-5028-8514 ; University of Novi Sad, Faculty of Technology, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia


Puni tekst: engleski pdf 314 Kb

str. 175-186

preuzimanja: 296

citiraj

Puni tekst: hrvatski pdf 314 Kb

str. 175-186

preuzimanja: 95

citiraj

Preuzmi JATS datoteku


Sažetak

Donkey milk is acknowledged as a valuable nutritional source in the human diet, well known for its bioactive and functional properties. Therefore, the main goal of this research was to investigate the similarities between donkey and human milk after six months of lactation with respect to the lipid composition, milk fat globule particle size distribution, antioxidant activity, and mineral content. These components are related to the nutritional properties of milk and they are important for the dairy industry as well to human health. The obtained results showed that the most dominant fatty acids in both types of milk were oleic, palmitic, and linoleic followed by lauric, capric, and alpha-linolenic acids. Donkey milk had a desirable fatty acid composition due to its high alpha-linolenic acid content and especially low omega-6/omega-3 ratio. After the fat globule distribution was analysed, it was found that fat globules smaller than 2 μm had the highest percentage in both human and donkey milk. The antioxidant activity of human milk was significantly higher at 42.95% compared to donkey milk at 35.83%. Predominant mineral in both types of milk was Ca, followed by P, Zn, Fe and Cu. Highlighting the similarity between donkey milk and human milk encourages the use of donkey milk as a potential substitute for human milk in the future.

Ključne riječi

donkey milk; human milk; nutritional quality; fat globule size distribution

Hrčak ID:

304329

URI

https://hrcak.srce.hr/304329

Datum izdavanja:

19.6.2023.

Podaci na drugim jezicima: hrvatski

Posjeta: 1.113 *




Introduction

Donkey milk (DM) is well known for its beneficial properties on human health (unique nutritional composition, functional and bioactive compounds). Therefore, currently, it takes high attention in the field of food science (Salimei and Fantuz, 2012;Altomonte et al., 2019;Martini et al., 2018). In terms of lactose, lipids, fatty acid, and protein profile, DM has a composition that is more comparable to human milk (HM) than cow milk (Gubić et al., 2015;Altomonte et al., 2019).

Some studies have shown that the absorption and metabolism of DM and HM in human digestion system are very much alike due to their similarities in bioactive compounds (Aspri, 2017;Prasad, 2020). Some studies have shown that the absorption and metabolism of DM and HM in the human digestive system are very similar due to their similarities in bioactive compounds (Aspri, 2017;Prasad, 2020). First, due to the low content of casein, which creates soft flocculation during digestion in infants, it additionally contributes to the faster digestibility of milk (Ragona et al., 2016). Clinical studies have shown that infants tolerate DM well (82.6-88%) (Ragona et al., 2016;Aspri, 2017). Fats contribute the major portion (45-55%) of the energy source in HM, with a total fat intake of approximately 5.5 kg in a fully breastfed infant during the first six months of life (Koletzko et al., 2011; Agostoni et al., 2005). Then, in the first 12 months of a child’s life, daily lipid intake represents 50%, and in the period between 12 and 24 months about 40% (Sarti et al., 2019;WHO, 2010). One of the major differences between DM and HM is related to fat yield. DM has low-fat content and hence it may represent a limitation in the children’s diet and needs to be enriched with lipids in order to fulfill the infant’s requirements. Generally, during lactation HM contains approximately 3.5 to 4.5% of fat content, while DM ranges between 0.45 to 1.15% with an increasing, nonlinear, trend from partum to the end of lactation (Szabo et al., 2010;Gubić et al., 2015). The uniqueness of DM is mainly attributed to the favourable composition of FA, especially to the high PUFA content with linoleic acid (18:2 n-6; LA) and alpha-linolenic acid (C18:3 n-3; ALA) ratio of 2:1 and a balanced ratio of omega-6/omega-3 (n-6/n-3) of 1.17:1 compared to that of HM of 12.45:1.37 (Martemucci and D’Alessandro, 2012;Gubić et al., 2015;Martini et al., 2018;Szabo et al., 2010). In particular, the high value of PUFA (52.2%), the low n-6/n-3 ratio, and the advantageous values of atherogenic (AI) and thrombogenic indices (TI) could represent a nutritional advantage of DM (Chiofalo et al., 2011;Gastaldi, 2010;Martemucci and D’Alessandro, 2012;Martini et al., 2015).

Milk fat occurs in a form of native milk fat globules (MFG) surrounded by the milk fat globule membrane (MFGM), with a size distribution ranging from 0.2 to 20 μm, which may affect FA composition and additionally provide 40 to 55% of total energy intake (Martini et al., 2012,2013a,2014;Altomonte et al., 2019). The lipid fraction of milk is a "natural solvent" for macronutrients and micronutrients such as minerals (Manoni et al., 2021). The main minerals in the milk lipid fraction MFG are iron, zinc, copper, calcium, and phosphate (soluble and colloidal), which balances are fundamental to the structure and function of the micelles (Lucey and Horne, 2009). Information about the MFG of DM is significant from a nutritional and technological point of view and only a few studies have focused on the morphometric characteristics of MFG in the milk obtained from Italian donkeys (Martini et al., 2012,2015,2018). In previous studies, the authors discovered that the size and composition of lipid globules have a significant influence on lipid digestion and metabolization by infants (Mizuno et al., 2009;Martini et al., 2014;Duan et al., 2021). In addition to very small MFG, DM is characterized as a rich source of short-chain FA, which improves fat digestibility and intestinal absorption (Martemucci and D’Alessandro., 2012;Altomonte et al., 2019).

The best milk for an infant is HM, which insures healthy and harmonious child development. About 75% of mothers choose to breastfeed their infants in the first six months of life, while only 13% continue to breastfeed after this period (WHO, 2008). Globally, only 36-38% of infants are exclusively breastfed (WHO-Breastfeeding, 2008). Besides being nutritionally valuable and essential for nutrition, HM improves the performance of the immune system because it has immunomodulatory potential and contains numerous antimicrobial agents (Szabo et al., 2010; Lubetzki et al., 2012). When breastfeeding is not possible, it is very important that infant nutrition fulfills the antioxidant requirements to resemble natural feeding as much as possible (Beghelli et al., 2016). The antioxidant activity (AA) of milk is the result of a complex interaction between antioxidant components such as proteins, carotenoids, flavonoids, and vitamins E and C (Faustini et al., 2014;Simos et al., 2011). AA is related to the prevention of lipid peroxidation, providing that way oxidative stability in milk (Salimei and Fantuz, 2012;Beghelli et al., 2016). Some studies were focused on investigating the antioxidant potential of HM (Zarban et al., 2009). On contrary, there is still a lack of scientific results based on the AA and the influence of the lactation period of DM.

Previous research has highlighted the similarities between DM and HM for infant nutrition (Altomonte et al., 2019;Szabo et al., 2010;Prasad, 2020). In a comprehensive literature review, only a few scientific studies investigated DM and HM obtained during prolonged lactation (Czosnykowska-Łukacka et al., 2018;Szabo et al., 2010). DM has been increasingly investigated as a promising alternative food for infants and children, so this study aimed to improve research data on the nutritional similarities between DM and HM for infant nutrition after six months of lactation.

Material and methods

Animals and nutritional management

DM was supplied from a farm located in the Special Nature Reserve Zasavica (Serbia) within the native area of the Balkan donkey, an autochthonous breed. The donkey was reared outdoors and the diet consisted of ad libitum pasture, traditional pasturing practices. In the pasture, the species consumed by the donkeys were Lolium perenne, Agropyrum, Alopecurus, Festuca pratensis, Trifolium, Trifolium repens, Medicago sativa, Achillea, Matricaria and Plantago media. In the winter, when there was insufficient pasture to meet the herd's nutritional requirements, donkeys were fed with meadow hay and maize. During milking, the animals were fed corn twice a day, pasture hay and fresh water available ad libitum.

Milk samples

The study was performed on 20 donkeys, which were routinely machine milked twice a day. During the 2 hours prior to milking, foals were physically separated from their mother in an adjacent box to allow visual contact. The mature milk samples were taken from each individual animal after the 6th month of lactation. The samples were stored in sterile plastic bottles at 4 °C until further analysis and samples used for FA determination were freeze-dried and stored at -20 °C until analysis.

Human milk samples

The samples of HM have been collected from 20 healthy women between the ages of 28 to 36 years, after the 6th month postpartum. All samples were delivered from mothers who agreed to participate in the study. Milk samples were removed from the mammary gland with a mechanical breast pump. HM samples were treated similarly to DM samples. The HM samples have been stored at 4 °C and analyzed after 24 h after their collection.

Chemical composition

The contents of total solids were determined according to IDF 21:2010 methods. The concentrations of total nitrogen (TN) were determined according to IDF 20-1:2001. A nitrogen conversion factor of 6.38 was used to calculate protein concentrations of milk samples. The concentration of fat was determined according to IDF 105:2008. Ash content was determined after mineralization of milk at 550 °C for 4 h according to IDF 258, 2001.

Lipid composition

Fatty acid composition from lipid extracts was determined by gas chromatography-flame ionization detection (GC Agilent 7890A system). Supercritical fluid extraction with CO2 was used for the preparation of fat extracts, described byIvanov et al., (2012). Extractions were performed on a fat analyzer (LECO TFA 2000) according to procedures (Leco Corporation, 2003). FA methyl esters were prepared by transmethylation method using a 14 wt% boron trifluoride/methanol solution (Sigma Aldrich, MO, USA) described byFolch et al., (1957) with the slight modification described byGubić et al. (2015). Results were expressed as the ratio of individual FA or FA group in total identified FA (%, w/w).

Indexes of lipid quality

The atherogenicity (AI) and thrombogenicity (TI) indices were calculated according to the equations [1] and [2] (Senso, 2007), by using data on the FA composition.

Index of atherogenicity (AI) indicates the relationship between the sum of the main saturated FA (SFA) and that of the main classes of unsaturated, the former being considered pro-atherogenic and the latter anti-atherogenic:

AI = [(4 × C14:0) + C16:0 + C18:0]/ ΣMUFA +ΣPUFA − n6 +ΣPUFA − n3 [1]

Index of thrombogenicity (TI) shows the tendency to form clots in the blood vessels. This is defined as the relationship between the pro-thrombogenetic (saturated) and the anti-thrombogenetic FAs (MUFAs, PUFAs – n6 and PUFAs – n3) (Senso, 2007).

The following equation was applied:

TI=(C14:0+C16:0+C18:0)/(0.5MUFA+0.5PUFA-n6+3PUFAn3+ PUFA-n3/PUFA-n6 [2]

The particle size distribution (PSD) of MFG

The particle size distribution of MFG in milk samples was determined by Mastersizer 2000 (Malvern Instruments, England) laser diffraction particle size analyzer using a Hydro 2000G dispersion unit. The samples were added at ambient temperature in water until an adequate obscuration was obtained (10-20%). The results were quantified as the volume-based particle size distribution by means of the Mastersizer 2000 software. The obtained particle size distribution parameters included following parameters: D[4.3]-volume mean diameter; d(0.5)-mass median diameter of the volume of distribution, indicating that 50% of the sample volume has a particles with sizes smaller than that value, whereas 50% has a larger size; d(0.1)- indicating that that 10% of the sample volume are particles with sizes smaller than that value and 90% are larger than that value; and parameter d(0.9)-indicates that 90% of sample volume has a particles with sizes smaller than that value and 10% are larger than that value and dsr-mean diameter (µm) (Stojanović et al., 2010).

Antioxidant activity

The antioxidant activity (AA) was determined by a 2.2- diphenyl-1-picrylhydrazyl (DPPH) scavenging system described by Alyaqoubi et al. (2014). To prepare the stock solution, 40 mg DPPH was dissolved in 100 mL methanol. By mixing 350 mL of the stock solution with 350 mL methanol, an absorbance of 1.0±0.01 units was obtained using a spectrophotometer (Jenway 6405 UV/Vis) at 517 nm wavelengths. 100 μL of fresh milk extract was mixed with 1 mL methanol DPPH solution and kept in the dark for 2 h to allow the reaction to occur. The percentage of DPPH activity was calculated as follows: DPPH (%) = [(A blank - A sample) / A blank] × 100. A is the absorbance.

Minerals content

Milk samples were mineralized by dry ashing (AOAC method 999.11 B) and content of minerals calcium (Ca), copper (Cu), zinc (Zn), and iron (Fe) was determined by flame atomic absorption spectrometry VARIAN SpectrAA-10, with background correction system (D2-(deuterium lamp) and appropriate cathode lamps. Standard solutions of minerals were prepared immediately before use by dilution (with 0.1 M HNO3, Merck, Germany) of standards at the concentration of 1 mg/cm (Baker, The Netherlands). Phosphorus content was determined by molecular absorption spectrometry (IDF 42:2006).

Statistical analysis

All analyses were performed in duplicate and results were expressed as mean ± standard deviation. The data were processed statistically using the software package STATISTICA 10.0 (StatSoft Inc., Tulsa, OK, USA). Analysis of variance (ANOVA) and Tukey's HSD test for comparison of sample means were used to analyze variations for significance (p<0.05). In the milk samples frequency distribution of the total counted and measured MFG (Fig. 1) was performed according toMartini et al. (2012), where their size were divided into three size categories of fat globules: small globules (SG) with a diameter <2 μm, medium-sized globules (MG) with a diameter from 2 to 5 μm and large globules (LG) with a diameter >5μm.

Figure 1 Particle size distribution of DM and HM
mlj-73-175-f1

Results and discussion

The basic compositions of DM and HM are presented inTable 1. Donkey milk showed lower values of total solids and fat, while it had the highest values for protein and ash. Although the variation in protein and ash percentages between milk types was greater, p<0.05 did not indicate that there was a statistically significant difference. In the present study, the main difference between the types of milk was the fat content. Similar results were obtained for composition of mature HM according to Czosnikovska-Łukacka et al. (2018). The results of showed that HM produced above 1 year of lactation is extremely rich in fat and has a higher energy content than HM produced during the first 6 months of lactation Lubetzki et al. (2012). Fat content of DM show decreasing tendency especially after 6th month of lactation (Massouras et al., 2017;Martemucci and D’Alessandro, 2012).

Table 1 Chemical composition during the follow-up period of DM and HM Data are expressed as mean ± SEM. Mean values of the observed parameters are written as the result of three measurements (n=3). Values with different superscripts (a,b) are significantly different (p<0.05)
CompositionDMHM
Total solids, %9.28±0.57a11.22±0.43b
Protein, %1.46±0.04a1.30±0.10a
Fat, %0.66±0.13a3.35±0.23b
Ash,%0.54±0.11a0.40±0.20a

The FA composition of the observed DM and HM milk samples is presented inTable 2. Accordingly, the total SFA content was higher in HM, while the concentrations of MUFA and PUFA were found to be higher in DM (Mesias et al., 2021). Previous studies (Chiofalo et al., 2011;Salimei and Fantuz, 2012) already indicated that DM and HM have different FA compositions, but the SFA are those that are present in the highest concentration in both kinds of milk. The SFA were the most prevalent in the milk of Nordestina donkeys (48.9%) after 120 days of lactation compared to MUFA (31.1%) or PUFA (19.7%), which had lower concentrations than the milk under study here. However, a similar trend was obtained in another study of SFA where donkey milk up to 210 days of lactation was examined (Massouras et al., 2017; Lazarević et al., 2017;Martemucci and D’Alessandro, 2012). The results showed that the most dominant FA in both types of milk was oleic acid (C18:1), palmitic acid (C16:0), LA, followed by lauric acid (C12:0), capric acid (C10:0) and ALA. The FA composition obtained in this study is in agreement with the results of human mature milk (Lubetzky, 2012).

Table 2 Fatty acid composition during the follow-up period of DM and HM
Fatty acidContent (% of total fatty acids)
DMHM
SFA48.72±0.01a51.17±0.02b
C4:00.22±0.01a0.20±0.01a
C6:01.35±0.02a1.81±0.01b
C8:04.06±0.01a5.92±0.08b
C10:08.95±0.01a9.90±0.18a
C11:02.69±0.02a3.47±0.04b
C12:09.26±0.01a9.28±0.08b
C14:00.30±0.02a0.35±0.03a
C16:019.77±0.03a18.61±0.19a
C18:01.85±0.03a1.33±0.04a
C20:00.22±0.01a0.20±0.05a
C22:00.05±0.01b0.10±0.03a
MUFA27.38±0.06b23.83±0.18a
C10:10.08±0.01a0.05±0.01a
C12:10.18±0.01a0.16±0.02a
C14:10.34±0.02a0.44±0.02b
C16:14.06±0.03a3.35±0.06a
C17:10.12±0.02a0.12±0.1b
C18:121.59±0.1b18.43±1.1a
C20:10.28±0.02b0.38±0.01a
C22:1 n-90.54±0.02a0.60±0.02b
C24:1 n-90.19±0.01b0.30±0.01b
PUFA21.63±0.05a18.75±0.04b
PUFA n-37.33±0.03b6.41±0.03b
C18:3 n-36.44±0.02b5.57±0.07a
C18:4 n-30.20±0.01a0.26±0.01a
C20:3 n-30.10±0.01a0.08±0.01a
C20:4 n-30.07±0.01a0.12±0.01b
C20:5 n-30.25±0.02b0.19±0.02a
C22:5 n-30.07±0.01a0.06±0.01a
C22:6 n-30.20±0.01a0.13±0.01a
PUFA n-614.30±0.02a12.34±0.02b
C18:2 n-611.57±0.06b9.53±0.05a
C18:3 n-60.58±0.02a0.52±0.02b
C20:2 n-61.10±0.01b1.20±0.01a
C20:4 n-61.05±0.01a1.09±0.02a
n6/n3 ratio1.95±0.02a1.92±0.02b
AI0.62±0.01a0.69±0.02b
TI0.51±0.02b0.54±0.01a

Data are expressed as mean ± SEM. Mean values of the observed parameters are written as the result of three measurements (n=3). Values with different superscripts (a,b) are significantly different (p<0.05)

Among the PUFA group, ALA and LA fatty acid dominated in both types of milk, with the fact that compared with HM, DM contained larger amounts of ALA and LA which is in keeping with the previous research (Massouras et al., 2017; Nayak et al., 2017). Also, a higher content of PUFA n-3, PUFA n-6, and n-6/n-3 ratio was found in DM. The results reported byMassouras et al. (2017) revealed that during late lactation period n-6/n-3 ratio shows an increasing tendency in DM. According toO’Connell et al. (2017) the high PUFA n-3 content and low n-6/n-3 ratio in HM are more beneficial to human health, which PUFA n-3 and n-6 and their proportions are correlated with human diseases.

Furthermore, a low amount of ALA resulted in higher AI and TI in the HM rather than in DM. Regarding the FA composition, with a sufficient amount of LA, ALA, PUFA n-3, and PUFA n-6 FA, such as DHA, AA as well as MUFA, DM showed to be suitable to meet childs’ growth and metabolic needs. This observation was in agreement with results obtained by Bobinski and Bobinska (2020), who found that the first six months of a child’s life is one of the most dynamic developments of a nervous system and the above-mentioned FA play a mandatory role in its development (Bobinski and Bobinska, 2020). Some studies have also demonstrated that the diet of breastfeeding mothers and donkeys greatly influences the FA composition of milk (Agostoni, 2005). However, it is found that only small parts of FA originate from the direct resorption of food while the greater part originates from the body's stock which is partially compensated by oscillations in food intake (Agostoni, 2005). Furthermore, poor levels of PUFA n-3 in HM have been correlated with the development of symptoms of allergic disease in children followed up to 18 months of age (Chiofalo et al., 2011; Gastaldi et al., 2010). DM with higher PUFA n-3 levels and a more favorable FA profile are adequate for children's nutrition, given that, following the nutritional guidelines of various international organizations, a child's fat intake should be gradually decreased from 60% to 35% after age 6 months (Sarti et al., 2019; Martini et al., 2021). In particular, despite major concerns regarding the use of DM as the sole source of nutrition (if not adequately supplemented), the results of the research bySarti et al. (2019) indicate that it could be considered a valid alternative in weaning infants (older than 5-6 months), considering that solid food should be introduced at the latest at the age of six months (Kostecka and Kostecka-Jarecka, 2021). Results obtained byMartemucci and D'Alessandro (2012) showed that n-6/n-3 ratio was approximately 2:1 in DM, with values <1 during the last period of lactation. Additionally, they suggested application of DM, as a functional food, in human nutrition, especially for the elderly and with potential utilization in infant nutrition (Martemucci and D'Alessandro, 2012;Prasad, 2020). Results obtained in this study showed that the ratio of AI and TI values in DM and HM are very similar. However, a statistical differences and higher values were detected for AI and TI in HM (Table 2). Increasing the value of AI and TI may be due to the reduction of MUFA, PUFA n-3 and PUFA n-6 as antithrombogenic acids (Ulbricht and Southgate, 1991). Previous studies in mares' milk have shown that the high and equilibrate essential FA content together with low AI and TI indicate the immune modulatory properties of milk (Chifalo et al., 2011;Pikul and Wójtowski, 2008).

The PSD of MFG and minerals content in DM and HM

Laser diffraction was used to analyse the PSD of MFG in DM and HM. Milk fat is present in a form of globules with a diameter in the range of 0.1-15 μm (average diameter ~ 4 μm) (Wiking et al., 2004). Regarding the results of PSD parameters of MFG (Figure 1), it was found that the fat globules had a different amount of MFG size between two types of milk for the same period of lactation. DM has smaller sizes of MFG compared to HM, as shown inFigure 1. Mastersizer 2000 software showed that 38.42% of DM volume has globules in the range of 0.1 to 1 μm, while only 12.15% of the HM volume contains globules in that interval. On the other hand, 56.81% of DM volume has particles in the range of 1 to 10 μm and 80.49% of HM volume has globules in that range. Compared to Amiata donkey milk analyzed byMartini et al. (2014), the average distribution percentage of globules in the range of 0.1 to 1 μm was 25.98% of the total measured MFG, which is a smaller proportion than that obtained in our study. Several other studies have shown that the average size of MFG can vary during lactation, due to changes in the total amount of milk fat produced during lactation (Chang et al., 2015). However, other authors indicate that an increase in the fat content of milk leads primarily to an increase in the number of MFG, and not in size (Mizuno et al., 2009).

DM has significantly (p<0.05) lower values of all particle size parameters compared to HM, as shown in theTable 3. The volume mean diameter of MFG in DM is 3.20 μm while HM has volume mean diameter of 4.56 μm. Moreover, the same lactation period in both types of milk led to a greater (p>0.05) synthesis of SG globules, which are most accounted and subsequently followed by MGs and LGs. The AA of HM was significantly higher 42.95% compared to DM 35.83% after the 6th month’s lactation. In our study, DM showed an AA lower than DM found in previous research by Bučević Popović et al. (2014). Compared to the results of the present study, higher AA in DM compared to HM could be observed (Beghelli et al., 2016). When HM is unavailable, DM may be one of the finest alternatives, not only for its nutritional qualities but also for its antioxidant capabilities, which may help prevent oxidative stress-mediated illness in disease in early human life (Beghelli et al., 2016).

Table 3 Particle size distribution (PSD) of milk fat globules (MFG) and antioxidant activity (AA) in dokey milk (DM) and human milk (HM) in the 6th month of lactation
ParametersDMHM
d0.1 µm0.31a0.86b
d0.5 µm1.31a3.36b
d0.9 µm5.48a8.80b
D [4,3] µm3.20a4.56b
SG%69.46a54.13b
MG%22.72a29.77b
LG%7.83a16.10b
AA%35.83a42.95b

Data are expressed as mean ± SEM. Values with different superscripts (a,b) are significantly different (p<0.05).

The relationship between different groups of the FA and the MFG size, subdivided into SG, MG, LG, and dsr in both types of milk, are presented inTable 4. The Pearson correlation analysis was performed to find out how MFG in both types of milk are related to their FA content. Only the SG group positively correlated with the MUFA and PUFA n-6, but the relationship coefficient varied. The dimensional parameters as MG, LG, and dsr are negatively correlated to the percentages of the MUFA, PUFA n-3, and PUFA n-6 FA and positively related to SFA and n-6/n-3 ratio. The SFA concentrations were positively correlated and higher in larger MFG in an earlier study that looked at the composition of small fatty acids and MFG in HM (Agrov et al., 2008). In line with results of some previous studies (Agrov et al., 2008;Faustini et al., 2014; Mesilati-Stah et al., 2011), many correlations between fat globules dimensional parameters and FA percentages could be due to a different composition along the range of PSD. It is considered that the morphometric characteristics of MG may be related to the FA composition of the fat which means that a higher number of small MFG implies a greater abundance in these of MUFA and PUFA acids (Agrov et al., 2008;Faustini et al., 2014; Mesilati-Stah et al. 2011).

Table 4 Relationship coefficients between dimensional parameters PSD of MFG and percentage of FA in DM and HM
VariableSGMGLGdsr
SFA-0.9970.9960.9980.983
C4:00.787**-0.865*-0.782**-0.811**
C6:00.849*-0.908*-0.849*-0.901*
C8:00.997+-0.965+-0.996+-0.971+
C10:00.995+-0.961+-0.994+-0.964+
C11:0-1.000+0.969+1.000+0.979+
C12:0-0.995+0.968+0.997+0.985+
C14:0-0.736**0.6790.741**0.731**
C16:00.592-0.561-0.584-0.510
C18:00.280-0.366-0.275-0.312
C20:00.6980.763-0.798-0.676
C22:00.680-0.568-0.675-0.410
MUFA0.995-0.959-0.969-0.978
C10:10.664-0.510-0.672-0.599
C12:10.664-0.5100.672-0.599
C14:10.990+-0.977+0.990+0.981+
C16:10.664-0.510-0.672-0.599
C17:10.994+0.975+-0.992+-0.959+
C18:10.996+-0.973+-0.997+-0.984+
C20:10.991+-0.984+0.991+-0.992+
C22:1 n-90.958+-0.918**-0.959+0.937+
C24:1 n-90.991+0.924+-0.991**-0.992+
PUFA0.998-0.963-0.9980.976
PUFA n-30.996-0.953-0.978-0.996
C18:3 n-30.991+-0.984+-0.991+-0.992+
C18:4 n-3-0.990+-0.984+-0.990+-0.976+
C20:3 n-30.998+-0.984+-0.991+-0.992+
C20:4 n-30.965+-0.901*-0.970+-0.959+
C20:5 n-3-0.990+-0.995*-0.991+-0.992+
C22:5 n-30.965+-0.901*-0.968+0.937+
C22:6 n-30.990+-0.984+-0.995+0.995+
PUFA n-60.998-0.964-0.999-0.979
C18:2 n-60.965+-0.901*-0.968+-0.937+
C18:3 n-60.999+-0.969+-0.999+-0.979+
C20:2 n-60.991+-0.984+-0.991+-0.992+
C20:4 n-60.179-0.118-0.1740.978
n6/n3 ratio-0.9980.9720.9980.978

+Correlation is statistically significant at p<0.01 level,

*Correlation is statistically significant at p<0.05 level,

**Correlation is statistically significant at p<0.10 level

The concentration of minerals in DM and HM is presented inTable 5. In both types of milk, Ca and P were the most abundant micronutrients, followed by Zn, Fe and Cu. The obtained results of the DM are lower than the literature data (Fantuz et al., 2016). According to previous studies, in HM 10 to 16% of Ca, and 2% of P were reported to be associated with the fat fraction (Fox et al., 2015). The Ca content in milk is correlated to MFG size and smaller MFG are characteriyed than larger Ca content (Manoni et al., 2021). Also, the major minerals found in the milk lipid fraction lead to an increase in their bioavailability and bioaccessibility (Baldi et al., 2008). The studies byLi et al. (2018) and Malacarne et al. (2019) showed the most abundant element is Ca followed by P, K, Na, Mg, Zn, Fe, and Cu in DM, which is similar to the distribution of elements in HM (Ballard et al. 2013). Ca is the most abundant mineral in DM and HM and half of the phosphorus present is associated with enhanced calcium absorption from the organism (EFSA, 2013).

Table 5 The concentration of minerals in donkey (DM) and human milk (HM)
Mineral content (mg/L)DMHM
Ca250.80±0.05a140.80±0.10b
P120.20±0.10a75.30±0.20b
Cu0.32±0.05b0.22±0.03a
Zn1.90±0.02a1.65±0.05a
Fe0.98±0.12a0.80±0.10a

Data are expressed as mean ± SEM. Mean values of the observed parameters are written as the result of three measurements (n=3). Values with different superscripts (a,b) are significantly different (p<0.05).

Conclusion

The increasing interest in the use of donkey milk as a natural product proved to be a good opportunity for its research as a substitute for human milk. The obtained results show similarity in nutrition quality, particle size distribution of fat globules and AA between DM and HM obtained after six months of lactation. DM had a high level of PUFA, especially n-3 FA, a favorable ratio of n-6/n-3 fatty acids, low AI and TI index values compared to HM. Since DM is considered a good substitute for HM, these data support the growing interest in further research of DM as an alternative in infant nutrition, which has adequate levels of FA, bioavailable minerals and antioxidants to meet the needs of infants. The information presented in this study may be useful for further research on DM as a substitute for breast milk after 6 months of age.

Acknowledgements

We would like to thank Special Nature Reserve Zasavica from the Republic of Serbia for milk samples and great cooperation.

Notes

[1] Financial disclosure Funding

This research was financially supported by Ministry of Science, Technological Development and Innovation of the Republic of Serbia, Institute of Food Technology in Novi Sad (Grant number: 451-03-47/2023-01/200222) and Faculty of Technology Novi Sad (Grant number: 451-03-47/2023-01/200134).

References

1 

Agostoni C. LC-PUFA content in human milk: is it always optimal? Acta Paediatr. 2005;94:1532–4. https://doi.org/10.1080/08035250500375491 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/16303689

2 

Altomonte I, Salari F, Licitra R, Martini M. Donkey and human milk: insights into their compositional similarities. Int Dairy J. 2019;89:111–8. https://doi.org/10.1016/j.idairyj.2018.09.005

3 

AOAC Official Method 999.11. Determination of lead, cadmium, copper, iron, and zinc in foods atomic absorption spectrophotometry after dry ashing.

4 

Argov N, Wachsmann-Hogiu S, Freeman SL, Huser T, Lebrilla CB, German JB. Size-dependent lipid content in human milk fat globules. J Agric Food Chem. 2008;56(16):7446–50. https://doi.org/10.1021/jf801026a PubMed: http://www.ncbi.nlm.nih.gov/pubmed/18656925

5 

Aspri M. (2017): Donkey milk microbiota: isolation and characterization for potential applications, Doctoral Dissertation, Limassol, Cyprus University of Technology.

6 

Ballard O, Morrow AL. Human milk composition: Nutrients and bioactive factors. Pediatr Clin North Am. 2013;60:49–74. https://doi.org/10.1016/j.pcl.2012.10.002 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/23178060

7 

Baldi A, Pinotti L. Lipophilic microconstituents of milk. Adv Exp Med Biol. 2008;606:109–25. https://doi.org/10.1007/978-0-387-74087-4_3 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/18183926

8 

Bobiński R, Bobińska J. Fatty acids of human milk - a review. Int J Vitam Nutr Res. 2022;92:280–91. https://doi.org/10.1024/0300-9831/a000651 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/32312179

9 

Beghelli D, Lupidi G, Damiano S, Cavallucci C, Bistoni O, De Cosmo A, et al. Rapid assay to evaluate the total antioxidant capacity in donkey milk and in more common animal milk for human consumption. Austin Food Science. 2016;1(1):1003.

10 

Breastfeeding (2008): Available on line:http://www.who.int/maternal_child_adolescent/topics/newborn/nutrition/breastfeeding/en/ (accessed on 20 June 2018).

11 

Bucevic-Popovic V, Delas I, Međugorac S, Pavela-Vrancic M, Kulisic-Bilusic T. Oxidative stability and antioxidant activity of bovine, caprine, ovine and asinine milk. Int J Dairy Technol. 2014;67:394–401. https://doi.org/10.1111/1471-0307.12126

12 

Chiofalo B, Dugo P, Bonaccorsi IL, Mondello L. Comparison of major lipid components in human and donkey milk: new perspectives for a hypoallergenic diet in humans. Immunopharmacol Immunotoxicol. 2011;33:633–44. https://doi.org/10.3109/08923973.2011.555409 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/21428711

13 

Czosnykowska-Łukacka M, Królak-Olejnik B, Orczyk-Pawiłowicz M. Breast milk macronutrient components in prolonged lactation. Nutrients. 2018;10(12):1893. https://doi.org/10.3390/nu10121893 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/30513944

14 

Duan B, Sik-Hong E, Ah-Shin J, Qin Y, Hee Lee J, Woo Lee C, et al. Correlations of fat content in human milk with fat droplet size and phospholipid species. Molecules. 2021;26:1–17. https://doi.org/10.3390/molecules26061596 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/33805759

15 

EFSA Panel on Dietetic Products, Nutrition and Allergies (NDA) (2013): Scientific opinion on nutrient requirements and dietary intakes of infants and young children in the European Union. EFSA, 11, 3408.

16 

Fantuz F, Salimei E, Papademas P. (2016): Macro-and micronutrients in non-cow milk and products and their impact on human health. Non-bovine milk and milk products. E. Tsakalidou and K. Papadimitriou, ed. Academic Press, London, UK., 209-261. https://doi.org/10.1016/B978-0-12-803361-6.00009-0 https://doi.org/10.1016/B978-0-12-803361-6.00009-0

17 

Faustini M, Torre ML, Perteghella S, Colombani C, Chlapanidas T, Munari E, et al. Fatty acid composition, fat globule size and reactive oxygen species-scavenging activity of mare milk: a longitudinal study. Journal of Dairy, Veterinary &. Anim Res. 2014;1(2):37–44. https://doi.org/10.15406/jdvar.2014.01.00010

18 

Folch J, Lees M, Stanley GHS. A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem. 1957;226:497–509. https://doi.org/10.1016/S0021-9258(18)64849-5 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/13428781

19 

Fox PFT. Uniacke-Lowe, P.L.H., McSweeney, O’Mahony, J.A. (2015): In Dairy chemistry and biochemistry. In Dairy chemistry and biochemistry. Second Edition. Springer International Publishing Switzerland. https://doi.org/10.1016/B978-0-12-374039-7.00001-5 https://doi.org/10.1016/B978-0-12-374039-7.00001-5

20 

Gallier S.; Vocking K.; Post J.A., De Heijning., Acton, D., Van De Beek, E.M., Baalen, T.V. A novel infant milk formula concept: Mimicking the human milk fat globule structure. Colloids Surf B Biointerfaces. 2015;136:329–39. https://doi.org/10.1016/j.colsurfb.2015.09.024 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/26432620

21 

Gastaldi D. Donkey’s milk detailed lipid composition. Front Biosci (Elite Ed). 2010;2:537–46. https://doi.org/10.2741/e112 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/20036900

22 

Gubić J, Milovanović I, Iličić M, Tomić J, Torbica A. Comparison of the protein and fatty acid fraction of Balkan donkey and human milk. Mljekarstvo. 2015;65(3):168–76. https://doi.org/10.15567/mljekarstvo.2015.0303

23 

IDF Standard 20-1. (2010): Milk, cream and evaporated milk - Determination of total solids content. Brussels, Belgium: International Dairy Federation.

24 

IDF Standard 20-1 (2001): Milk - Determination of nitrogen content - Part 1: Kjeldahl method. Brussels, Belgium: International Dairy Federation.

25 

IDF Standard 105 (2008): Milk - Determination of fat content - Gerber butyrometers. Brussels, Belgium: International Dairy Federation.

26 

IDF Standard 258 (2001): Milk and milk products - Determination of ash. Brussels, Belgium: International Dairy Federation.

27 

IDF Standard 42 (2006): Milk - Determination of total phosphorus content - Method using molecular absorption spectrometry. Brussels, Belgium: International Dairy Federation.

28 

Ivanov D, Čolović R, Lević J, Sredanović S. Optimization of supercritical fluid extraction of linseed oil using RSM. Eur J Lipid Sci Technol. 2012;114:807–15. https://doi.org/10.1002/ejlt.201100347

29 

Koletzko B, Agostoni C, Bergmann R, Ritzenthaler K, Shamir R. Physiological aspects of human milk lipids and implications for infantfeeding: a workshop report. Acta Paediatr. 2011;100:1405–15. https://doi.org/10.1111/j.1651-2227.2011.02343.x PubMed: http://www.ncbi.nlm.nih.gov/pubmed/21535133

30 

Kostecka M, Kostecka-Jarecka J. Knowledge on the complementary feeding of infants older than six months among mothers following vegetarian and traditional diets. Nutrients. 2021;13(11):3973. https://doi.org/10.3390/nu13113973 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34836229

31 

Li N, Wang Y, You C, Ren J, Chen W, Zheng H, et al. Variation in raw milk microbiota throughout 12 months and the impact of weather conditions. Sci Rep. 2018;8:2371. https://doi.org/10.1038/s41598-018-20862-8 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/29402950

32 

Lubetzky R, Zaidenberg-Israeli G, Mimouni FB, Dollberg S, Shimoni E, Ungar Y, et al. Human milk fatty acids profile changes during prolonged lactation: A cross-sectional study. Isr Med Assoc J. 2012;14:7–10. PubMed: http://www.ncbi.nlm.nih.gov/pubmed/22624434

33 

Lucey LA, Horne DS. (2009): Milk salts: Technological significance. P.L.H. McSweeney, P.F. Fox (Eds.), Advanced Dairy Chemistry 3. Lactose, Water, Salts and Minor Constituents (3rd ed.), Springer, New York, NY (2009), pp. 351-389. https://doi.org/10.1007/978-0-387-84865-5_9 https://doi.org/10.1007/978-0-387-84865-5_9

34 

Manoni M, Cattaneo D, Mazzoleni S, Giromini C, Baldi A, Pinotti L. Milk fat globule membrane proteome and micronutrients in the milk lipid fraction: insights into milk bioactive compounds. Dairy. 2021;2:202–17. https://doi.org/10.3390/dairy2020018

35 

Martini M, Altomonte I, Salari F. Relationship between the nutritional value of fatty acid profile and the morphometric characteristics of milk fat globules in ewes milk. Small Rumin Res. 2012;105:33–7. https://doi.org/10.1016/j.smallrumres.2011.12.007

36 

Martini M, Altomonte I, Salari F. Evaluation of the fatty acid profile from the core and membrane of fat globules in ewe’s milk during lactation. Lebensm Wiss Technol. 2013a;50:253–8. https://doi.org/10.1016/j.lwt.2012.05.019

37 

Martini M, Altomonte I, Salari F. Amiata Donkeys: fat globule characteristics, milk gross composition and fatty acids. Ital J Anim Sci. 2014;13(1):123–6. https://doi.org/10.4081/ijas.2014.3118

38 

Martini M, Altomonte I, Manica E, Salari F. Changes in donkey milk lipids in relation to season and lactation. J Food Compos Anal. 2015;41:30–4. https://doi.org/10.1016/j.jfca.2014.12.019

39 

Martini M, Altomonte I, Licitra R, Salari F. Nutritional and nutraceutical quality of donkey milk. J Equine Vet Sci. 2018;65:33–7. https://doi.org/10.1016/j.jevs.2017.10.020 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/30055917

40 

Martemucci G, D’Alessandro AG. Fat content, energy value and fatty acid profile of donkey milk during lactation and implications for human nutrition. Lipids Health Dis. 2012;11:113. https://doi.org/10.1186/1476-511X-11-113 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/22963037

41 

Massouras T, Triantaphyllopoulos KA, Theodossiou I. Chemical composition, protein fraction and fatty acid profile of donkey milk during lactation. Int Dairy J. 2017;1:83–90. https://doi.org/10.1016/j.idairyj.2017.06.007

42 

Messias TBON, Sant’Ana AMS, Araújo EOM, Rangel AHN, Vasconcelos ASE, Salles AH, et al. Milk from Nordestina donkey breed in Brazil: Nutritional potential and physicochemical characteristics in lactation. Int Dairy J. 2022;127:105291. https://doi.org/10.1016/j.idairyj.2021.105291

43 

Mesilati-Stahy R, Mida K, Agrov-Argaman N. Size-dependent lipid content of bovine milk fat globule and membrane phospholipids. J Agric Food Chem. 2011;59(13): 7427–35. https://doi.org/10.1021/jf201373j PubMed: http://www.ncbi.nlm.nih.gov/pubmed/21623627

44 

Michalski MC, Briard FM, Tasson F, Poulain P. Size distribution of fat globules in human colostrum, breast milk and infant formula. J Dairy Sci. 2005;88:1927–40. https://doi.org/10.3168/jds.S0022-0302(05)72868-X PubMed: http://www.ncbi.nlm.nih.gov/pubmed/15905422

45 

Mizuno K, Nishida Y, Taki M, Murase M, Mukai Y, Itabashi K, et al. Is increased fat content of hindmilk due to the size or the number of milk fat globules? Int Breastfeed J. 2009;4:7. https://doi.org/10.1186/1746-4358-4-7 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/19607695

46 

O’Connell TD, Block RC, Huang SP, Shearer GC. ω3-polyunsaturated fatty acids for heart failure: Effects of dose on efficacy and novel signaling through free fatty acid receptor 4. J Mol Cell Cardiol. 2017;103:74–92. https://doi.org/10.1016/j.yjmcc.2016.12.003 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/27986444

47 

Pikul J, Wójtowski J. Fat and cholesterol content and fatty acid composition of mares’ colostrums and milk during five lactation months. Livest Sci. 2008;113:285–90. https://doi.org/10.1016/j.livsci.2007.06.005

48 

Prasad, B. (2020): Nutritional and health benefits of donkey milk. Journal of Food Science and Nutrition Therapy 6 (1), 022-025. https://dx.doi.org/ https://doi.org/10.17352/jfsnt

49 

Salimei E, Fantuz F. Equid milk for human consumption. Int Dairy J. 2012;24(2):130–42. https://doi.org/10.1016/j.idairyj.2011.11.008

50 

Sarti L, Martini M, Brajon G, Barni B, Salari F, Altomonte I, et al. Donkey’s milk in the management of children with cow’s milk protein allergy: nutritional and hygienic aspects. Ital J Pediatr. 2019;45:102. https://doi.org/10.1186/s13052-019-0700-4 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/31420060

51 

Senso L, Suarez MD, Ruiz-Cara T, Garcia-Gallego M. On the possible effects of harvesting season and chilled storage on the fatty acid profile of the fillet of farmed gilthead sea bream (Sparus aurata). Food Chem. 2007;101:298–307. https://doi.org/10.1016/j.foodchem.2006.01.036

52 

Simos Y, Metsios A, Verginadis I, D’Alessandro AG, Loiudice P, Jirillo E, et al. Antioxidant and anti-platelet properties of milk from goat, donkey and cow: An in vitro, ex vivo and in vivo study. Int Dairy J. 2011;21:901–6. https://doi.org/10.1016/j.idairyj.2011.05.007

53 

Stojanović, Z., Maković, S., Uskoković, D. (2010): Merenje raspodele veličina čestica metodom difrakcije laserske svetlosti. Novi materijali 19, 1-5.

54 

Szabó E, Boehm G, Beermann C, Weyermann M, Brenner H, Rothenbacher D. Fatty acid profile comparisons in human milk sampled from the same mothers at the sixth week and the sixth month of lactation. J Pediatr Gastroenterol Nutr. 2010;50(3):316–20. https://doi.org/10.1097/MPG.0b013e3181a9f944 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/20118808

55 

Ulbricht TL, Southgate DAT. Coronary heart disease: seven dietary factors. Lancet. 1991;338:985–92. https://doi.org/10.1016/0140-6736(91)91846-M PubMed: http://www.ncbi.nlm.nih.gov/pubmed/1681350

56 

Zarban A, Taheri F, Chahkandi T, Sharifzadeh G, Khorashadizadeh M. Antioxidant and radical scavenging activity of human colostrum, transitional and mature milk. J Clin Biochem Nutr. 2009;45:150–4. https://doi.org/10.3164/jcbn.08-233 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/19794922

57 

World Health Organization (WHO). (2008): The World Health Report 2008., Primary Health Care - Now More Than Ever, Geneva.https://apps.who.int/iris/handle/10665/43949

58 

World Health Organization (WHO) (2010): Fats and Fatty Acids in Human Nutrition. Rome: FAO Food and nutrition paper 91, 1-166. Report of an expert consultation. Geneva, November 10-14.

59 

Wiking L.; Stagsted J., Bj ̈orck, L., Nielsen, J.H. Milk fat globule size is affected by fat production in dairy cows. Int Dairy J. 2004;14(10):909–13. https://doi.org/10.1016/j.idairyj.2004.03.005


This display is generated from NISO JATS XML with jats-html.xsl. The XSLT engine is libxslt.