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Identification of Lipid Biomarkers to Discriminate the Different Production Systems of Asiago PDO Cheese Severino Segato, Gianni Galaverna, Barbara Contiero, Paolo Berzaghi, Augusta Caligiani, Angela Marseglia, and Giulio Cozzi J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.7b03629 • Publication Date (Web): 24 Oct 2017 Downloaded from http://pubs.acs.org on October 30, 2017
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Journal of Agricultural and Food Chemistry
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Identification of Lipid Biomarkers to Discriminate the Different Production Systems of
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Asiago PDO Cheese
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Severino Segato*,†, Gianni Galaverna‡, Barbara Contiero†, Paolo Berzaghi†, Augusta
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Caligiani‡, Angela Marseglia‡, Giulio Cozzi†
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†
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Legnaro (PD), Italy
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‡
Department of Animal Medicine, Production and Health, University of Padova, 35020
Department of Food and Drug, University of Parma, 43121 Parma, Italy
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*Corresponding author:
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Phone: ++39-049-827-2662; e-mail:
[email protected] 13
ORCID:
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Severino Segato: 0000-0003-0036-8502
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ABSTRACT
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Lipid fraction of Asiago Protected Designation of Origin (PDO) cheese was analysed to
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identify specific biomarkers of its main production systems through a canonical discriminant
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analysis. The three main production systems of the cheese were considered. Two were located
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in the upland (UL): pasture based (P-UL) vs. hay based total mixed rations (H-UL). The third
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was located in the lowland (LL) and processed milk from cows fed maize silage based rations
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(maize silage lowland: MS-LL). The discriminant analysis selected 9 fatty acids and vitamin
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A as lipid biomarkers useful to separate the three production systems. High contents of
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conjugated linoleic acids, anteiso-C15:0 and vitamin A were discriminant factors for P-UL
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cheese. The separation between H-UL and MS-LL cheese was less marked with the former
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having the higher content of conjugated linoleic acids and some polyunsaturated n-6 fatty
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acids, while the latter being identified by cyclopropane fatty acid and C9:0.
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KEYWORDS: Asiago cheese, production system, lipid fraction, canonical discriminant
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analysis
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INTRODUCTION
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Nowadays many types of cheese produced in the European Union are officially labelled
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according to specific production methods (i.e, organic or traditional specialities guaranteed)
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and/or to the geographical location of the milk production system (i.e., mountain products). In
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order to avoid frauds, both the consumers and producers would benefit from a set of
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identification biomarkers capable of discriminating and distinguish cheeses and dairy
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products from each other. At this regard, the lipid fraction of dairy products has a relevant
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role in the characterization of their nutritional1 and organoleptic quality.2,3 The outcomes of a
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recent meta-analysis on the existing scientific literature comparing conventional and organic
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bovine milk indicated that the supply of nutritionally desirable long-chain polyunsaturated n-3
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fatty acids (PUFA) was improved in the lipid composition of organic milk.4 The presence of
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conjugated linoleic acids (CLA), odd- and branched-chain fatty acids (OBCFA) and other
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secondary fatty acids have also shown to improve cheese nutritional properties, since these
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bioactive substances are positively associated with human health.5 Fat soluble vitamins are
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further bioactive constituents of the cheese lipid fraction due to their anti-oxidant activity that
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extends food shelf-life and prevents rancidity phenomena.6 Recent scientific evidences
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showed that milk fatty acids (FA) profile and fat-soluble vitamins can be used to discriminate
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different feeding systems of dairy cows.3,7,8 Therefore, the identification of qualified
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biomarkers from the analysis of the lipid fraction could represent a promising approach to
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trace the different production system of a given cheese.
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Asiago is a semi-hard cheese produced from cow’s milk in a restricted area of north-eastern
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Italy. Despite being processed and ripened according to its Protected Designation of Origin
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(PDO),9 Asiago cheese has a wide variability in quality due to its different milk production
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systems and cheese-making conditions.10 This study aimed at analysing lipid composition of
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Asiago PDO cheese in order to identify specific biomarkers capable to discriminate its main
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production systems.
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MATERIALS AND METHODS
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Cheese Production Systems and Experimental Design. The study considered the three
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main cheese production systems (CPS) of the Asiago PDO which differ for size and location
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of the cheese factories, and for cows feeding and management system (Table 1). Two
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production systems represent the historic center of Asiago cheese and they are located in the
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upland (UL) of Asiago (around 1000 m above sea level) in the Veneto Region (Italy). The
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first is a seasonal pasture based system (P-UL) in which cows graze during the summer on
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natural pastures and receive a daily amount of concentrates [3.0-5.0 kg of dry matter (DM)
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per lactating cow] according to their milk yield. This is a very small scale production system
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that usually processes milk produced by a single or a few dairy herds. The other is a hay
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based production system (H-UL) with cows fed total mixed rations (TMR) made of local
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permanent grass, cereal grains and protein sources. It represents small/medium size alpine
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cheese factories that process milk produced from local dairy farms to produce cheese labelled
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as mountain product in compliance with the EU regulation n. 665/2014. A third production
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chain (MS-LL) features medium/large size cheese factories located in the lowland (LL)
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surrounding the highland of Asiago. These productive sites process milk collected from dairy
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farms in which high producing dairy cows are kept indoor and fed maize silage (MS) based
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high energy TMR.
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Three separate bulks of raw milk were collected within each CPS during the summer period
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(from July to September) and they were processed to produce Asiago PDO cheese in different
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sites. All wheels had a similar ripening time of about 6 months that was carried out in storage
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bay at 10±2 °C and 80-85% relative humidity. The sampling protocol considered 81 wheels of
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cheese (28 of P-UL, 26 of H-UL cheese and 27 of MS-LL, respectively).
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Chemical Analysis. Cheese samples were analyzed in duplicate for moisture,11 total
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protein and water soluble nitrogen,12 and sodium chloride content.13 Total lipids content was
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determined using an accelerated solvent extraction method by ASE 200 (Dionex Corporation,
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Sunnyvale, CA) with hexane/isopropanol (3:2, v/v) solution that was removed by means of a
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rotary evaporator. According to the method proposed by Christie et al.,14 an aliquote of 40 mg
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of anhydrous fat was used to methylate the fatty acids (FAs). Sodium methoxide (CH3ONa)
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was used as catalyst and methyl 12-tridecenoate as an internal standard (Nu Chek Prep Inc.,
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Elysian, MN). The analyses of FAs methyl esters were performed by two dimensional GC on
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a 7890A instrument (Agilent Technologies, Santa Clara, CA) connected with a
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chromatography data system (Agilent ChemStation) software (Agilent Technologies,
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Wilmington, DE) and fitted with two capillary columns: the first used was a 75 m x 180 µm
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i.d., 0.14 µm film thickness (Supelco, Bellefonte, PA); the second used was a 3.8 m x 250 µm
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i.d., 0.25 µm film thickness (J&W Scientific, Folsom, CA). The carrier gas was hydrogen and
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the injector temperature was 270 °C meanwhile the flame ionization detector operated at 250
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°C. The oven temperature of the GC varied from 50-150 °C with an increase of 50 °C/min,
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and then ramped up to 240 °C at 2 °C/min. The cheese FAs were identified by comparing
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their retention time and peak position to those of a mixture of 52 pure FAs [reference mixture
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(Nu Chek Prep Inc., Elysian, MN); reference mixture and bacterial acid methyl esters
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(Supelco); PUFA No.3 from menhaden oil (Sigma-Aldrich, St. Louis, MO); individual CLA
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isomers (Nu Chek Prep Inc.; Matreya LLC, State College, PA)]. Standard (dihydrosterculic
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acid methyl ester, purity >98%) of cyclopropane FA (CPFA) was commercially available
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(Abcam, Cambridge, UK) while ϖ-cyclohexyl tridecanoic acid (ϖ-C19) was synthetized as
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reported previously.15 The two-dimensional chromatograms were analysed with the
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comprensive GC x GC image software (Zoex Corp., Houston, TX). Based on peak areas,
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single FAs were expressed as g/100 g of total FAs according to the correction factors of
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AOAC 963.22 method.16 The analysis of vitamin A (retinol) and vitamin E (α-tocopherol)
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was performed by high performance liquid chromatography according to the methods
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proposed by Zahar and Smith17 and Indyk,18 respectively. A model 510 HPLC (Waters Corp.
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Milford, MA) was equipped with a 150 mm x 4.6 mm i.d., 5 µm, RP-C18 Discovery column
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(Supelco, St. Louis, MO) at 25 °C, mobile phase methanol/water (98:2, v/v) and model 2996
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UV detector (Waters Corp.). The two vitamins were determined at 324 nm for retinol and 293
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nm for α-tocopherol according to the retention times of reference standard (Sigma-Aldrich,
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St. Louis, MO).
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Statistical Analysis. All the statistical analyses were performed using SAS 9.4 software
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(SAS Institute Inc., Cary, NC). Cheese chemical data were submitted to ANOVA (PROC-
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GLM), adopting a linear model that considered the fixed effects of production system and
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milk bulk. The two degrees of freedom of CPS factor were used to perform the following set
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of orthogonal contrasts: P-UL vs. (H-UL + MS-LL)/2 and H-UL vs. MS-LL. The dataset of
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the cheese lipid fraction was submitted to a preliminary selection in order to avoid
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redundancy among variables. The procedure deleted variables strongly correlated among each
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other (r value > 0.95 for the Pearson coefficient). A stepwise discriminant analysis (PROC
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STEPDISC) was then applied on the remaining FAs and fat-soluble vitamins to reduce the
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number of variables according to CPS. A canonical discriminant analysis (PROC CANDISC)
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was performed to achieve the most discriminant variables that maximize the distance among
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CPS groups. Two canonical functions named CAN1 and CAN2 were obtained and the final
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pool of FAs and vitamins highly correlated to them (r value > 0.60) was identified. The
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degree of dissimilarity among production systems was measured by squared Mahalanobis
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distances (D2-Mahalanobis) and the reliability of the canonical discriminant model was finally
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assessed by a cross-validation.
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RESULTS AND DISCUSSION
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Cheese Chemical Composition, Fatty Acids Profile and Fat Soluble Vitamins Content.
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Chemical composition of the cheese samples belonging to the three CPS are reported in Table
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2. Cheese from MS-LL had the highest moisture content and the lowest fat content. Limited
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difference in chemical composition were detected between P-UL and H-UL except for water
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soluble nitrogen and salt content. The FA profiles of the cheese samples are reported in Table
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3. Cheese from the pasture based system had the highest content of the short-chain FA C4:0,
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whereas it had a lower concentration of medium-chain FAs (from C8:0 to C14:0) than H-UL
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and MS-LL cheese. Pasture based cheese was also associated to a higher (P < 0.001)
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concentration of MUFAs and PUFAs and a reduction of SFAs. Moreover, consistent with
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previous studies on alpine pasture cheese and milk,19,20 P-UL cheese had the richest CLAs
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content (P < 0.001). The concentration of these healthy constituents in milk and dairy foods is
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increased by the intake of fresh grass that are rich in C18 precursors, such as linolenic and
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linoleic acid as well as by the prevention of the reduction to stearic acid of the vaccenic acid
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produced in the rumen.21,22 Under grazing conditions, the dietary C18:3 n-3 is mainly
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biohydrogenated and the derivatives are trans-11 C18:1 and C18:0 that are strongly
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desaturated to CLA in the mammary gland. Odd- and branched chain FAs (OBCFA) are
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further healthy compounds of the lipid fraction in milk and dairy products and in this study,
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their total content (P = 0.008) and in particular that of iso- and anteiso-C15:0, iso-C16:0,
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anteiso-C17:0 and iso-C18:0 (P < 0.001) increased in P-UL cheese according to the higher
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forage content of the diets fed in this CPS.23 Among cyclic FAs, ϖ-cyclohexyl tridecanoic (ϖ-
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C19) was similar across CPS, whereas cyclopropane FA (CPFA), was detected only in MS-
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LL cheese. The statistical contrast between H-UL and MS-LL samples was not significant for
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most FAs (Table 3). However, H-UL cheese had a lower concentration of SFAs (P < 0.001)
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and higher concentration of MUFAs (P = 0.020), PUFAs (P < 0.001) and cis-9,trans-11 CLA
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(P < 0.001). Vitamin A (retinol) and vitamin E (α-tocopherol) concentrations were highest (P
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< 0.001) in P-UL cheese, while there was no difference between H-UL and MS-LL (Table 3).
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Fresh grass is rich of carotenoids and α-tocopherol while sun exposure and oxidation during
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harvest, ensiling and storage cause their losses in preserved forages explaining the lower
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content of their derivatives in food products from hay and/or silage based dairy systems.24
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Canonical Discriminant Analysis. A canonical discriminant analysis (CDA) was carried out
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by using the dataset relative to the lipid fraction of the 81 cheese samples to categorize the
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three CPS. Two significant functions (CAN1 and CAN2) (Wilks’ Lambda = 0.0023, approx.
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F value = 60.5, df1= 38, df2= 116, P < 1·10-4) accounted for 91.4% and 8.6% of the total
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variability, respectively. The stepwise procedure used by the discrimination model selected 15
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variables among all lipid compounds: 14 FAs and vitamin A (Table 4). However, only 9 FAs
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and vitamin A had correlation coefficient values with the total canonical structure higher than
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0.60 (Figure 1). A scattergram based on the standardized canonical coefficients was created to
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plot the separation of the cheese samples according to the three CPS (Figure 2). The squared
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Mahalanobis distances among them indicated that P-UL samples were extremely different
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from both H-UL (D2-Mahalanobis = 272; P < 0.001) and MS-LL (D2-Mahalanobis = 260; P
