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Free Maillard reaction products in milk reflect nutritional intake of glycated proteins and can be used to distinguish “organic” and “conventionally” produced milk Uwe Schwarzenbolz, Thomas Hofmann, Nina Sparmann, and Thomas Henle J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b01375 • Publication Date (Web): 23 May 2016 Downloaded from http://pubs.acs.org on June 5, 2016
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Journal of Agricultural and Food Chemistry
Free Maillard reaction products in milk reflect nutritional intake of glycated proteins and can be used to distinguish “organic” and “conventionally” produced milk
Uwe Schwarzenbolz, Thomas Hofmann, Nina Sparmann, Thomas Henle
Institute of Food Chemistry, Technische Universität Dresden, D-01062 Dresden, Germany
Corresponding author: T. Henle Tel.: +49-351-463-34647 Fax: +49-351-463-34138 Email:
[email protected] 1 ACS Paragon Plus Environment
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Abstract
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Using LC-MS/MS and isotopically labelled standard substances, quantitation of free Maillard
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reaction products (MRPs), namely Nε-(carboxymethyl)lysine (CML), 5-(hydroxymethyl)-1H-
5
pyrrole-2-carbaldehyde (pyrraline, PYR), Nδ-(5-hydro-5-methyl-4-imidazolon-2-yl)-ornithine
6
(MG-H) and Nε-fructosyllysine (FL) in bovine milk was achieved. Considerable variations in
7
the amounts of the individual MRPs were found, most likely as a consequence of the
8
nutritional uptake of glycated proteins. When comparing commercial milk samples labelled as
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originating from “organic” or “conventional” farming, respectively, significant differences in
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the content of free PYR (organic milk: 20-300 pmol/mL; conventional milk: 400-1000
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pmol/mL) were observed. An analysis of feed samples indicated that rapeseed and sugar beet
12
are the main sources for MRPs in conventional farming. Furthermore, milk of different dairy
13
animals (cow, buffalo, donkey, goat, ewe, mare, camel) as well as for the first time human
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milk was analyzed for free MRPs. The distribution of their concentrations, with FL and PYR
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as the most abundant in human milk and with a high individual variability, also points to a
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nutritional influence As the components of concentrated feed do not belong to the natural
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food sources of ruminants and equidae, free MRPs in milk might serve as indicators for an
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adequate animal feeding in near-natural farming and can be suitable parameters to distinguish
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between an “organic” and “conventional” production method of milk.
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Keywords
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Milk, organic and conventional farming, Maillard reaction, pyrraline, animal feeding
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Introduction
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Since mankind started to use fire for cooking, Maillard reaction products are part of the
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human diet.1 MRPs can be divided into compounds from the “early” stage, namely Amadori
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products, and “advanced glycation end products” (AGE) such as the lysine derivatives N-ε-
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carboxymethyllysine (CML) or pyrraline (PYR), respectively, and the arginine derivative
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MG-H1. 2,3 The daily amount of MRPs taken up with a regular Western diet was estimated to
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1000 mg for Amadori products, calculated for N-ε-fructosyllysine (FL), and 25 to 75 mg for
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the AGEs CML and PYR.4 For CML and FL a release of protein-bound derivatives into
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peptides, which are small enough to be absorbed (< 1000 Da), is described.5 Depending on the
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individual chemical structure there are reports about the metabolic transit of MRPs. Amadori
34
products were found to pass through the intestinal mucosa only by diffusion to absorption
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rates of 1-3%,6 while MRPs like CML, MG-H1 and PYR can be transported actively into
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mucosa cells by the PEPT-1 transporter when bound in dipeptides.7 Within the epithelial
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cells, after peptidolysis, MRPs with hydrophobic side chains, namely PYR, can pass through
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the basolateral membrane, while MRPs with charged or polar side chains, like CML and MG-
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H1 remain trapped inside the epithelial cells. Nevertheless, in infants the plasma and urine
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levels of CML can be influenced through the diet8, most likely because of the still developing
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barrier function of the epithelium. Consequently, from dietary studies it could be concluded
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that the excretion of PYR, measured in urine
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this particular MRP.
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Due to the fact that dietary MRPs like pyrraline can be found in the urine originating from
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blood clearance, it can be speculated, that mammals also excrete AGEs by lactation.
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Cattle are ruminants and their digestive system is specialized on feed with high amounts of
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roughage. The milk yield of dairy cows in conventional farming increased significantly over
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the past years.10 To cover the energy consumption for the production of up to 40-50 l milk per
9
accounts for 50% of the ingested amount of
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day, a cow needs feed with a higher energy density and more nitrogen compared to its natural
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food sources. Thus the addition of molasses, coarse colza and soy are indispensable in
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conventional farming with the consequence of elevated MRP levels in cow’s nutrition11.
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It is known that MRPs, administered with feed ingredients, are able to influence the rumen
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flora12, but in contrast to pet food13, to the best of our knowledge, there are no reports on the
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amount of MRPs in feed used for cattle.
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Caused by an increasing consumer’s demand, the production of organic food grew in recent
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years and was covering about 7-8% of the total agricultural production in European countries
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like Danmark or Germany in 2012. 14
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Milk and milk products are of particular importance, as they have the highest sale revenue
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among all the different categories. Currently, the demand is still exceeding the supply, so it is
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essential, to find ways to distinguish between “organic” and “conventional” products. For
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milk, the ratios of carbon and nitrogen isotopes were suggested to be valid parameters.15 As
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the studies showed that the δ13C value as single indicator is not sufficient, additional
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parameters like the α−linoleic acid content16 or the δ15N nitrogen isotope ratio17 were
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included for an unequivocal differentiation between organic and conventional milk. Recently,
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with a sophisticated analysis of the fatty acid and antioxidant profile of milk fat, combined
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with multivariate statistics, Kusche et al.
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between samples of organic and conventional farming. Although the stable isotope ratio as
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well as the spectrum of fatty acids in milk vary with the season and may possess regional
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variations, in combination these parameters offer effective tools to distinguish between
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organic and conventional milk and within limitations their significance can be transferred on
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processed milk products as well.19
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Additionally, for milk products like cheese, phytanic and pristanic acid, microbiological
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degradation products of chlorophyll in the rumen were suggested as indicators of organic
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feeding.20 A target value of 200 mg/100g lipid of phytanic acid was proposed to be a 4
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demonstrated that it is possible to distinguish
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threshold, but some conventional products also reached the lowest levels of products from
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organic farming. To increase the accuracy of the discrimination between organic and
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conventional, the authors additionally suggest to validate the ratio of the diastereomers of
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phytanic acid and to include the δ13C values in the decision.21
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As feed is able to influence the composition of milk, the hypothesis for the work presented
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here was that higher levels of free MRPs should be detectable in milk of mammals which
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have consumed heated food/feed. Especially, if cows are fed concentrated feed and are able to
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absorb MRPs in their intestine, these substances could be helpful to indicate feed ingredients,
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which are not part of the natural food sources. For this reason we adapted an LC-MS/MS
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method22 and examined commercially available milk samples from organic and conventional
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production for free MRPs and compared the values with the free MRP content of milk from
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other species as well as with the MRP content in cows feed.
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Materials and Methods
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Chemicals. Nonafluoropentanoic acid (NFPA) was from Sigma (Seelze, Germany), CML and
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[2H2]CML were obtained from PolyPeptide (Strasbourg, France). [13C6,15N2] lysine and [13C6]
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arginine were purchased from Euriso-top (Saarbrücken, Germany). HPLC grade methanol and
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acetonitrile were from VWR Prolabo (Darmstadt, Germany).
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The synthesis of the following MRPs was performed according to the literature stated: FL,23
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[13C6,15N2]FL,24 PYR,25 and MG-H1.7 The synthesis of [13C6,15N2] PYR and [13C6] MG-H1
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were performed in the same manner but using [13C6,15N2] lysine (PYR) and [13C6] arginine
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(MG-H1) instead of the unlabeled amino acids.
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All other chemicals were from Merck (Darmstadt, Germany).
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Milk samples. A total number of 32 commercially available whole milk samples (protein: 3.4
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+/ 0.1%; fat: 3.6 +/- 0.1%) from conventional or organic production (according to 5 ACS Paragon Plus Environment
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manufacturer´s data) were purchased from local stores and included 12 pasteurized (2
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conventional, 10 organic), 13 extended shelf life (ESL) (7 conventional, 6 organic), 4 ultra-
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high temperature treated (2 conventional, 2 organic) and 3 raw (1 conventional, 2 organic)
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milk samples. Two conventionally produced raw cow´s milk samples were obtained from a
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local
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Großerkmannsdorf, Germany). These samples were taken from individual cows directly from
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the udder and all single feed ingredients (coarsely grinded soy, rapeseed and corn, sugar beet
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pellets, molasses, cereals and palm oil) and readily mixed cow’s feed, which was given to the
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cows on the day of milking, was recorded. Furthermore, one milk sample each of buffalo
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(Landgut Chrusdorf, Penig, Germany), ewe (Schuberts Milchschafhof, Saultitz, Germany),
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goat (Ziegenhof Winter, St. Egidien, Germany), camel (Camel Milk Vitality, Eggerding,
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Austria), horse (NaturOase Sachsen Oederan, Germany) and donkey (Asinerie d’Embazac,
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L’Isle Jourdain, France) were analyzed. 17 samples of human milk were kindly donated by 5
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volunteers.
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All milk samples were freeze dried after purchase or sampling and stored at -18°C. Before
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analysis, the milk was reconstituted with double distilled water.
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Feed samples. All ingredients, namely grinded corn, soy and rapeseed, sugar beet pellets,
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cereals, palm oil and molasses, as well as the complete feed mixture, which additionally
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contained silage, were obtained from a local farmer (Landwirtschaftliches Unternehmen "An
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der Dresdner Heide", Großerkmannsdorf, Germany).
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Incubation of human milk
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Each 3 mL of human milk were incubated at 37° C after addition of one small crystal of
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thymol for 2, 4, 6, 20 and 24 h in sealed reaction tubes. Immediately after incubation the
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samples were frozen and kept at -18°C until analysis.
farmer
(Landwirtschaftliches
Unternehmen
"An
der
Dresdner
Heide",
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Sample preparation
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Free MRPs in milk. 1 mL of reconstituted milk was mixed with 10 mL of an ice cold
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mixture of acetonitrile with methanol (50/50, v/v) in a test tube and 10 µL of internal standard
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mixture (see table S1 in the supplement) were added. After cooling at -25 °C for 1h, the
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samples were centrifuged at 3000 g for 5 min. The supernatant was decanted into a poly
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propylene tube and evaporated on a Zymark TurboVab LV Evaporator (Hopkinton, MA,
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USA). The precipitate was dissolved in 1.4 mL water and 1.4 mL hexane. For defatting, the
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organic phase was discarded after centrifugation (1000 g; 2 min) and to the remaining water
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phase, 100 µL of NFPA were added. This mixture was applied to a solid phase extraction
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(SPE) cartridge (Waters Oasis HLB 6 cc, Milford, MA, USA), previously prepared by
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consecutively flushing with 2 mL methanol, 2 mL methanol/10 mM NFPA (50/50,v/v) and 4
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mL 10 mM NFPA. Following sample application, the SPE cartridge was washed with 4 mL
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of a mixture of methanol and 10 mM NFPA (5/95,v/v) and the analytes were eluted with 5
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mL of a mixture of methanol and 10 mM NFPA (90/10,v/v) into test tubes. The eluate was
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evaporated, redisolved in 40 µL of water and applied to HPLC-MS. All samples were
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analyzed at least in triplicate.
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Quantitation of free and total MRPs in cow’s feed. Single feed ingredients and readily
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mixed cow’s feed were grinded as fine as possible in a laboratory mill (Retsch, Haan,
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Germany) and homogenized. For analysis of free MRPs, each sample was weight in according
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to the expected concentrations (between 1.5 and 3 g) and extracted with defined volumes
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(between 6 and 16 mL) of 0.1 M HCl using an ultra-turrax disperser and an ultrasonic bath.
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These mixtures were centrifuged and 1 mL of the supernatant was treated in the same way as
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described for milk samples, starting with the addition of 10 mL of an ice cold mixture of
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acetonitrile with methanol (50/50, v/v).
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Total MRPs were analyzed after enzymatic digestion according to the literature26. In brief,
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each sample, representing 2–4 mg of protein, was incubated for 24 h at 37 °C in the presence 7 ACS Paragon Plus Environment
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of 1 FIP-U of pepsin in 1.0 mL of 0.02 N HCl. Subsequently, 250 µL of 2 N TRIS buffer, pH
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8.2 and 400 PU of pronase E were added and the solution was incubated for further 24 h at
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37 C. Finally, 0.4 U of aminopeptidase M and 1 U of prolidase were added. After an
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additional incubation for 24 h at 37 °C, the solutions were lyophilized, reconstituted in 1.4 mL
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of water. After addition of 10 µL internal standard mixture and 1.4 mL of heptane the solution
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was vortexed and centrifuged. The organic phase was discarded and to the remaining water
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phase, 100 µL of NFPA were added. The subsequent sample preparation followed the
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protocol described in the “free MRPs in milk” section by applying sample solution to the
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SPE.
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Acid hydrolysis. To verify the extent of the enzymatic hydrolysis, a comparative acid
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hydrolysis of feed and milk samples was performed according to Henle et al. 1991 27 but with
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lithium buffers on a Sykam Amino Acid Analyzer S 433 (chromatographic system and all
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buffers were purchased from Sykam, Fürstenfeldbruck, Germany). For this purpose, a sample
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amount equivalent to 10 mg protein was weight into a reaction tube and suspended in 6 N
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HCl, the tube was flushed with nitrogen, then closed with a lid and heated at 110° C for 23 h.
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Subsequent an aliquot of 1 mL hydrolysate was evaporated to dryness, solved in 500 µL
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loading buffer and 50 µL applied to the amino acid analysis. These experiments were carried
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out in triplicate.
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HPLC-MS analysis of Maillard reaction products
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The selected MRPs were analyzed on an Agilent 1200 series chromatographic system
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connected to an Agilent 6410 mass spectrometer with electro spray ion source (ESI-MS, all
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from Agilent, Waldbronn, Germany). The general working conditions were 350° C gas
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temperature, gas flow 11 l/min, nebulizer pressure 35 psi and a capillary voltage of 4000 V.
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For quantitative analysis, the MRM modus with ion transitions shown in table 1 and the
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following chromatographic conditions were used. The elution buffers were 5 mM NFPA in 8 ACS Paragon Plus Environment
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water (eluent A) and 5 mM NFPA in acetonitrile (eluent B). The gradient program started at
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85% A which reduced to 15% within 21 minutes. Subsequent to holding 15% A for 9 minutes
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the column was equilibrated (15 min) to the initial conditions. A combination of a ZORBAX
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300SB18, 2.1x50 mm; 1.8 µm column (Agilent, Waldbronn, Germany) with a Hypercarb
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2,1x150 mm, 5 µm (Thermo Fisher Scientific, Dreieich, Germany) and the flow rate was 0.2
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mL/min.
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Method validation and statistics
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The limit of detection (LOD) and limit of quantitation (LOQ) were estimated from signal to
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noise ratios (s/n) multiplied by 3 (LOD) or 9 (LOQ), respectively. Signal to noise ratios were
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taken from chromatograms of human milk samples which showed the lowest signal for the
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respective analyte.
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To assay the recovery of the tested analytes, a sample of human milk was spiked with
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standard (table 2) and analyzed according to the protocol above. The standard deviation of
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repeatability was calculated from multiple analysis (n=8) of a single human milk sample.
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Statistical parameters were calculated by using the program Sigmaplot version 12.0
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(build12.0.0182, Systat software, Chicago, USA). First, the data were tested for normality and
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depending on the individual results, mean or median with according confidence intervals
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where calculated following ISO 16269 statistical interpretation of data28 and ISO 2602
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statistical interpretation of test results29, respectively. The visiualization of the data in figure 2
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was prepared based on Massart et al. (2005)30 with whiskers which were calculated as 1.5-
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fold the interquartile range31.
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Results and discussion
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Method and validation 9 ACS Paragon Plus Environment
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Selected MRPs, namely FL, CML, MG-H and PYR, were separated via RP-HPLC in the free
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form after precipitation of proteins and solid phase extraction using two consecutive columns
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with a mass spectrometric detection in MRM mode. As can be seen in Figure 1, MRPs eluted
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between 5 and 14 minutes. Identification of each substance was achieved by comparing
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retention time and mass spectra with isotopically labeled reference compounds [13C6,15N2]FL,
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[2H2]CML, [13C6,15N2]PYR and [13C6]MG-H1. For MG-H1, the different isomers, which form
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in the reaction between methylglyoxal and arginine32, could not be separated and, therefore,
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contribute all to the area of a peak at retention time 10 min, which was named “MG-H”. For
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quantitation, a standard of [13C6]MG-H1 was used under the assumption that all isotopes show
208
equivalent signal responds.
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Overlay chromatograms for selected samples of raw milk from either conventional or organic
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production, respectively, are shown in Figure 1. Additionally, the isotopically labelled
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internal standards are shown. It can be seen, that all investigated MRPs are clearly separated
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and can be detected in noticeable amounts. To enhance the selectivity of the mass
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spectrometric detection, the elution time was divided into 3 different time segments 0-8 min,
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8-11.5 min and 11.5-20 min with MRM transitions as indicated in table 1.
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The recovery of the analytes was tested by analyzing a sample of human milk with and
216
without the addition of MRP standards. As shown in table 2, significant amounts of free
217
MRPs were present in the original sample and the addition of standard increased these figures
218
to expected levels. Recovery rates between 95 and 102% were calculated. The limits of
219
detection (LOD) were calculated from signal to noise ratios and are indicated in table 3.
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To verify the influence of the enzymatic digestion which is needed for the analysis of protein-
221
bound MRPs in feed, a blank sample (water) and a standard mixture in water were treated
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according to the enzymatic digestion procedure as described above. From this experiment it
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could be seen, that lysine, which could additionally be recorded in the chromatogram (data
224
not shown), is liberated through self-digestion of the enzymes, but none of the desired target 10 ACS Paragon Plus Environment
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molecules is affected by the sample preparation. The effectiveness of the enzymatic digestion
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was determined to 91% by amino acid analysis in comparison to acid hydrolysis based on the
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release of hydrophobic amino acids (valine, leucine, isoleucine; data not shown).
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Finally, the potential influence of the freeze drying process, which was used to stabilize the
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collected milk samples before analysis, was tested with cow’s milk by analyzing one sample
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before and after drying (each in triplicate). The results showed that freeze drying caused no
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significant decrease of most of analytes (table S2 in the supplement). The exceptions were
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free FL (10%) and free lysine (20%). In milk there is an approximate 7000-fold molar excess
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of lactose compared to lysine, therefore a reaction with this disaccharide, e.g. towards N-ε-
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lactulosyllysine could explain this effect for lysine. For FL it is conceivable, that the free pair
235
of electrons at the nitrogen reacts with lactose or degradation towards lysine takes place33.
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Free MRPs in commercially available milk
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A total number of 32 commercially available milk samples and 2 samples taken directly on a
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farm were analyzed for the content of free MRPs. Individual values for all samples can be
239
found as Table S3 and S4 in the supplementary material. As depicted in Figure 2, the early
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Maillard product FL in commercially available milk can be found in concentrations between
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112 pmol/mL and 960 pmol/mL. For CML, lower values between 47 pmol/mL and 119
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pmol/mL were analyzed. The data for the free arginine derivative MG-H ranged between 8
243
pmol/mL and 67 pmol/mL and values between 14 pmol/mL and 1295 pmol/mL were assigned
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to the PYR content. Especially the same order of magnitude for FL and PYR is unusual, when
245
compared to the values of their protein-bound analogues. According to literature data34,24, in
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milk products and other food there is at least a 10 fold surplus in the content of protein-bound
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FL compared to PYR. With the exception of FL, which we found in higher amounts, our
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observations fit quite well to the results which were presented by Hegele et al. (2008)24. These
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authors also showed that the technological processing has only limited influence on the
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concentration of free MRPs. 11 ACS Paragon Plus Environment
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In order to compare the milk samples with respect to the production method, samples were
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grouped according to their labeling into “organic” and “conventional” products.
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As depicted in Figure 2, in average, slightly higher values for FL were present in the
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conventional milk samples (median organic: 344, 95% confidence interval: 307 to 461
255
pmol/mL, mean conventional: 628 +/- 445 pmol/mL. If samples with FL concentrations
256
higher or lower than 1.5xIRQ31 (see Figure 2) are regarded as outliers, the values for organic
257
samples range from 112 to 959 pmol/ml, whereas the calculation for conventional milk
258
delivered an interval between 318 and 932 pmol/ml. Consequently, no significant difference
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(P
