Food and Nutrition Sciences
Vol.10 No.05(2019), Article ID:92406,16 pages
10.4236/fns.2019.105038

Matrix Extension with Fitness for Purpose and Stability Assessment of DHA and Additional Fatty Acids in Individual Whole Chicken Eggs

Gerald Patrick Dillon1*,Alexandros Yiannikouris2,Walter Brandl3,Cathy Cardinall3,Wendy Yuan3,
Colm Anthony Moran4

1Regulatory Affairs Department, Alltech Ireland, Dunboyne, Ireland

2Research Department, Alltech Inc., Nicholasville, USA

3Analytical Chemistry Department, Mérieux NutriSciences, Burnaby, Canada

4Regulatory Affairs Department, Alltech SARL, Vire, France

Copyright © 2019 by author(s) and Scientific Research Publishing Inc.

This work is licensed under the Creative Commons Attribution International License (CC BY 4.0).

http://creativecommons.org/licenses/by/4.0/

Received: April 5, 2019; Accepted: May 13, 2019; Published: May 16, 2019

ABSTRACT

The consumption of long chain polyunsaturated fatty acids (LC-PUFA) is associated with several human health benefits. Most notable of these LC-PUFA is docosahexaenoic acid (DHA C22:6) whose inclusion is considered essential for optimum human health. Biofortification of common foods such as eggs with DHA has emerged as a specific approach to increase the intake of DHA in human populations. This can be achieved by supplementing poultry rations with feeds like microalgae or fish oil that are rich in DHA, which results in an increased uptake in the egg. Gas chromatography with flame ionization detection (GC-FID) is the method of choice when analyzing food such as eggs for DHA and other fatty acids. For regulatory studies it is desirable to demonstrate that the method is specifically suitable for the analysis of DHA and fatty acids in eggs. The purpose of this paper is to further extend the scope of the AOAC 996.06 methodology examined in the paper by Dillon et al., and to demonstrate the fitness for purpose of the method by examining specific validation parameters. It is a further objective to investigate the stability of DHA and other fatty acids of short and long timepoints. A validation of the method for the determination of DHA and three other fatty acids in eggs is thus presented.

Keywords:

DHA, GC-FID, Fatty Acids, Analytical Method, Fitness for Purpose, Aurantiochytrium limacinum

1. Introduction

An increased consumption of long-chain polyunsaturated fatty acids (LC-PUFA) in the human diet can be related to several health benefits including improved cognitive and cardiovascular function and immune health [1] [2] [3] . Among the group of LC-PUFA compounds, docosahexaenoic acid (DHA) is perhaps the best well known and researched and its inclusion in diets for optimum health has been well publicised [4] [5] [6] . Despite this, DHA intake remains low in many countries, particularly those where Western diets are prevalent [7] [8] [9] . The biofortification of common foods with DHA and other LC-PUFA is seen as a key approach by which to seamlessly boost consumption of these essential nutrients in human populations [3] [10] . DHA intake for example, can be increased in household foods, such as chicken eggs, by supplementing poultry dietary rations with feeds like microalgae or fish oil which are rich in DHA [11] [12] [13] [14] .

Gas chromatography with flame ionization detection (GC-FID) has been established as the principle technique for analyzing fatty acids in foods, with the original method of fatty acids extraction and methylation to yield methyl ester derivatives being described by Folch et al. [15] . The method has been referenced in several publications in the analysis of DHA and fatty acids in eggs [11] [16] . In addition, variations of the method have been examined with a view to further developing the method in the analysis of eggs [17] [18] . Whilst the methodology has been widely investigated, there is a need for the method to be thoroughly validated to demonstrate to fitness for purpose in analyzing eggs for regulatory studies, for example in the analysis of fatty acids profiles, assessing egg enrichment studies and gaining an understanding of the efficacy of feed ingredients for the purpose of enriching chicken eggs.

The purpose of this paper therefore is to further extend the scope of the AOAC 996.06 methodology as examined in the paper by Dillon et al., [19] to include this additional matrix. The method was further applied to assess the stability of DHA and other fatty acids in the eggs over a range of timepoints. The parameters examined during the validation study included; linearity and range, the limit of detection (LOD) and limit of quantification (LOQ), accuracy, repeatability, inter-analyst reproducibility and specificity. Stability experiments were conducted samples of extracted egg after 2, 24 and 48 hours at room temperature; the stability of freeze-dried egg samples spiked with various concentrations of fatty acids was assessed after storage at <−16˚C for periods of 0, 2, 4, 8, 12, 16, 20 and 26 weeks and a freeze/thaw study over four cycles were conducted.

2. Materials and Methods

2.1. Instrumentation and Chemicals & Reagents

The procedure employed for the analysis of DHA and fatty acids in eggs followed the same analytical method as outline in the paper by Dillon et al., 2019. This includes the main chemicals, reagents and instrumentation used as well as the extraction of fat and methylation of extracts. Difference to sample and standard preparation are further noted herein.

In brief, the experiments were performed at Mérieux NutriSciences (Burnaby, Canada) and were performed on an Agilent 6890N gas chromatograph (Agilent, Ontario, Canada) equipped with a hydrogen FID and an Agilent 7683 autosampler (Agilent, Ontario, Canada). Solvents and reagents were sourced from Fisher Scientific (Ontario, Canada). These included diethyl ether, petroleum ether, water (HPLC grade), ethanol 95%, chloroform, toluene, hexane and methanol. Boron trifluoride, 7% was prepared by diluting boron fluoride 14% one to one with methanol. Hydrochloric acid, 8.3N was prepared by adding 250 ml of concentrated HCl (12 N) to 110 ml of deionized water. Pyrogallic acid was obtained from TCI America (Portland, USA).

The following fatty acid methyl ester standards were sourced from Nu-Chek-Prep Inc. (Minnesota, USA); methyl 4,7,10,13,16,19-docosahexaenoate (DHA C22:6); methyl octanoate (C8:0); methyl tetradecanoate (C14:0); methyl heptadecanoate (C17:0); methyl hexadecanoate (C18:0); methyl trans 9-octadecenoate (C18:1T); and methyl 13 docosenoate (C22:1 cis-13). In addition, the internal standard for sample extraction, 1,2,3-triundecanoylglycerol (common name: triundecanoin), the internal standard for calibration curve and QCs, methyl undecanoate and docosahexaenoic acid (DHA) were also all purchased from Nu-Chek-Prep Inc. (Minnesota, USA). The Reference material NIST SRM 3275-2 Anchovy Oil concentrate and the Quality control sample NIST 3290 (Dry Cat Food) were purchased from NIST (Gaithersburg, USA).

To examine the acceptability of the method, two commercially available reference materials were analyzed. Reference material NIST SRM 3275-2 Anchovy Oil concentrate was analyzed with each set performed during this study to verify the acceptability of the analytical set. The reference material contained 187 ± 8 mg/g of DHA C22:6. A quality control reference material NIST 3290 (Dry Cat Food) was analyzed with each set performed during this study to verify the complete hydrolysis and derivatization of fatty acid bound within the chicken eggs.

2.2. Preparation of Calibration Standards, Internal Standards and Quality Control Standards

The FAME stock solutions were prepared by taking a known quantity of each of the commercial standards and dissolving in hexane and making up to 10 ml in a volumetric flask. A mixed FAME standard working solution with a final concentration of 40 mg/ml of each FAME was prepared by taking an aliquot of each FAME stock solution and making up to 10 ml with hexane. A methyl undecanoate internal standard solution was prepared by taking 1 g of methyl undecanoate, dissolving in hexane and making up to 10 ml. Calibration FAME standard solutions were prepared at 0.3, 0.75, 1.5, 3, 7.50 and 15 mg/ml by adding volumes of the mixed FAME standard working solution with 100 μl of methyl undecanoate internal standard solution and making up to 2000 μl with hexane. Standard solutions were stored at <−16˚C when not in use.

2.3. Preparation of Egg Sample

Control (blank) chicken egg samples were purchased locally and were freeze-dried prior to extraction and analysis. Any samples that could not be freeze-dried immediately were stored at ≤−16˚C until freeze-drying could be completed. Samples were freeze dried in a VirTis Benchtop Pro Freeze Dryer (SP Scientific, Pennsylvania, USA) for 48 hours.

Extraction of fat

Control egg powder was thoroughly mixed to ensure a homogeneous sample was obtained. A 0.15 ± 0.01 g sample of the powder was weighed into a Mojonnier flask. Pyrogallic acid (100 mg) was added to the flask which was then fortified with 75 μl of 40 mg/ml mixed FAME standard working solution. A 2 ml aliquot of triundecanoin internal standard solution, a few boiling granules and 2 ml of ethanol was added, and the suspension was mixed. A 10 ml aliquot of 8.3 M hydrochloric acid was added and the flask was placed in a 70˚C - 80˚C water bath for one hour with periodic mixing before being cooled to 20˚C and vortex-mixed for 15 seconds. Excess ethanol was added to rinse down the walls of the flask. A 25 ml portion of diethyl ether was added to the flask, which was stoppered and shaken gently. A 25 ml portion of petroleum ether was added, and the flask was again shaken and vortex-mixed for two minutes. The flask was centrifuged for five minutes at 600 rpm to yield a clear supernatant, which was decanted into a round bottomed flask and evaporated using a rotary evaporator.

Methylation

The extracted fat residue was dissolved in a 3 ml volume of chloroform and a further 3 ml of diethyl ether was added. The resulting solution was placed into a 10 ml glass tube. The round bottomed flask was washed with diethyl ether and the washings were added and the solution was evaporated to dryness under nitrogen at 40˚C. A 2 ml volume of 7% BF3 reagent and 1ml of toluene was added to the glass tube which was vortex-mixed for 30 seconds. The tube was sealed and heated in an oven for 1 hour at 100˚C with shaking every ten minutes. The tube was allowed to cool to 20˚C and 5 ml of HPLC-grade water, 1 ml hexane and 1 g sodium sulfate were added. The tube was capped and vortex-mixed for one minute and then centrifuged at 2000 rpm for 3 minutes. The resulting clear supernatant was dried with sodium sulfate and injected into the GC-FID.

GC-FID Conditions

The GC system used a SP2560 100 cm long capillary column with an internal diameter of 0.25 mm and a film thickness of 0.20 μm (Supelco, Pennsylvania, USA). Helium was employed as a carrier gas and had an initial flow of 1.1 ml/min and an average velocity of 19 cm/sec at a pressure of 35.74 psi. Air and hydrogen were used for the FID with pressures of 60 and 40 psi respectively. The initial oven temperature was 100˚C which was held for four minutes and then ramped up at a rate of 3˚C/min to 240˚C and maintained for 19 minutes. The injector was employed in the split mode (200:1) at a temperature of 225˚C. The detector temperature was 285˚C.

2.4. Method Validation

Linearity

A standard curve that covered the range of analytes and the range of concentrations of fatty acids in the samples was prepared to demonstrate linearity on the GC-FID. Linear regression, forced through the origin and with equal weighting, was applied to the peak area ratios plot for the construction of calibration curves plotting FAME:IS peak area ratios of the calibration standards against FAME concentrations and provided information on the slope, coefficient of determination, and intercept. Standards contained C8:0, C14:0; C17:0; C18:0; C18:1T, C22:1 cis-13 and C22:6 FAMEs along with C11:0 internal standard.

Limit of Detection (LOD) and Limit of Quantification (LOQ)

The LOD and LOQ of the method were established for DHA C22:6 by analyzing the endogenous quantity of DHA in a freeze-dried blank egg sample which was analyzed in ten replicates. The LOD of the method was determined as three times the standard deviation, whilst the LOD was deemed to be ten times the standard deviation.

Accuracy

The blank matrix sample, i.e. whole chicken egg composite, was spiked with C14:0, C17:0, C18:0 and C22:6 in FAME form at three levels: 0.1%, 0.25% and 0.4% (w/v). All four analytes have endogenous levels in the blank matrix, which was extracted and analyzed in triplicate. The average of the endogenous levels found in the blank sample was subtracted from the final concentration prior to the spike recoveries being calculated.

Repeatability

The freeze-dried whole chicken egg composite sample was analyzed in triplicate by the first analyst in three separate analysis sets producing a total of nine results. In addition, the samples were analyzed in triplicate by the second analyst, for a total of three results. The mean, standard deviation and Relative Standard Deviation (%RSD) were determined for results from both analysts, and the relative difference between the first and second analyst were compared. The acceptable criteria for %RSD was <10%.

Specificity

To determine the identity of the FAME analyzed in the study, each of the seven standards were analyzed individually and their retention times were recorded.

Reference Materials

To examine the acceptability of the method, two commercially available reference materials were analyzed. Reference material NIST SRM 3275-2 Anchovy Oil concentrate was analyzed with each set performed during this study to verify the acceptability of the analytical set. The reference material contains 187 ± 8 mg/g of DHA C22:6. A quality control reference material NIST 3290 (Dry Cat Food) was analyzed with each set performed during this study to verify the complete hydrolysis and derivatization of fatty acid bound within the Chicken Eggs. The results for the following analytes (Total fat, C14:0, C16:0, C18:0, C18:1C, C18:1, C18:2C, C18:3, C20:5, C22:5 and C22:6) were within three standard deviations of the established mean.

Inter-analyst reproducibility

To demonstrate the inter-analyst reproducibility and the inter-analyst repeatability, a second analyst repeated portions of the validation and the results were compared.

2.5. Stability

The following experiments were conducted over the course of the study to examine the stability of solutions and analytes; 1) the stability of the FAME stock solutions stored at <−16˚C over six months; 2) the calibration FAME standard solutions on the autosampler over the course of each analytical sequence; 3) the short-term stability testing was carried out on chicken egg extracts prepared during the accuracy study at room temperature to examine the shelf life of the extracted analytes during the testing procedure. Each matrix extract was spiked at three different concentration levels, 0.1% (w/v), 0.25% (w/v) and 0.4% (w/v). Three aliquots for each of the three levels, and therefore a total of nine aliquots of each chicken matrix, were examined. The extracts were analysed at 2, 24 and 48 hours.; 4) Long term stability testing was carried out on the freeze-dried and stored egg, to evaluate the stability of the analytes and egg matrix during the anticipated storage time of the samples. The samples were weighed and spiked appropriately (three experimental replicates spiked at three concentration levels 0.1% (w/v), 0.25% (w/v) and 0.4% (w/v)), prior to freeze-drying. After the spiked eggs were dried, they were stored frozen (≤−16˚C) until the testing date. The long-term stability samples were analyzed at 0, 4, 8, 12, 16, 20 and 26 weeks. 5) the freeze and thaw stability was conducted over the course of four cycles. Freezing was established at <−16˚C overnight and thawing took place at room temperature for more than two hours. Initial analysis after one freeze-thaw cycle established the baseline measurement. Sample aliquots were tested after each freeze-thaw cycle for four cycles.

3. Results

Linearity

The method was linear over the calibration range of 0.3 mg/ml to 15 mg/ml for all seven FAME analytes; C8:0, C14:0; C17:0; C18:0; C18:1T, C22:1 cis-13 and C22:6

FAME. The coefficients of determination, R2, were found to range from 0.998 to 1.000 for the seven analytes within the acceptable criteria of R2 ≥ 0.990 (R ≥ 0.995). See results in Table 1.

Limit of Detection (LOD) and Limit of Quantification (LOQ)

To determine this method’s LOD and LOQ for C22:6 the blank egg matrix samples were analyzed in ten replicates. The standard deviation was determined to be 0.0068%. The LOD, calculated as three times the Standard Deviation, is 0.02%. The LOQ, calculated as ten times the Standard Deviation, is 0.07%. See Table 2.

Table 1. Correlation coefficients for fatty acid analysis of individual, whole chicken eggs (R).

Table 2. Limit of Detection (LOD) and Limit of Quantitation (LOQ) of docosahexaenoic acid (DHA) in individual, whole chicken eggs.

Accuracy, repeatability and specificity

The spike recoveries for the four monitored compounds were calculated and ranged from 91% to 110% which is within the acceptable range of 90% to 110%. The mean of the recoveries ranged from 97% to 108%. See Table 3 for the summary of accuracy results.

An example calculation for Day-1-Spike-1, C14:0 at spiked at 0.1%, is as follows:

% Recovery = ( Amt found in spike Amt found in blank ) Amt spiked × 100 % = ( 1292 . 691 2 0 2 . 953 ) 1 000 × 100 % = 1 0 9 .0 %

Table 3. Accuracy (as measured by recovery%) of select fatty acids spiked at 3 levels (0.1%, 0.25% and 0.4%) in individual whole chicken eggs.

The samples were analyzed in triplicate over three separate analysis sets by the first analyst, giving a total of nine determinations. In order to assess the repeatability, the mean and standard deviation of the recoveries were calculated to determine the %RSD. The %RSD for chicken egg samples were within the acceptable range of <10% RSD for DHA (C22:6) with results of 1.0% for the first analyst and 1.9% for the second analyst. A summary of the results can be found in Table 4.

To assess the specificity, the retention times of each FAME standard were determined individually and in a mixed standards solution. A low-level spike was compared with a blank matrix chromatogram and demonstrates that the method distinguishes between the analytes of interest and other substances which might be present in the matrix.

Table 4. Repeatability of fatty acids (% RSD; n = 9) in whole chicken egg extracts and determination of relative difference (% RD) between first and second analysts.

Reference Materials

The results of the reference materials supported the suitability of the method in determining the fatty acid analytes. The reference material NIST SRM 3275-2 Anchovy Oil concentrate yielded results ranged from 173 to 183 mg/g. These results are within the acceptable range of 2 standard deviations from the mean, which was determined to be 172 to 185 mg/g. See Table 5.

The quality control sample NIST 3290 (Dry Cat Food) was analyzed with each set performed during this study to verify the complete hydrolysis and derivatization of fatty acid bound within the Chicken Eggs. The results for the following analytes (Total fat, C14:0, C16:0, C18:0, C18:1C, C18:1, C18:2C, C18:3, C20:5, C22:5 and C22:6) were within three standard deviations of the established mean. See Table 6.

Inter-analyst Reproducibility

To demonstrate the robustness and the inter-analyst reproducibility, a second

Table 5. Concentration of C22:6 (DHA) in found in Reference Material (NIST SRM 3275-2 Anchovy Oil concentrate).

Where: Acceptable Range = Mean ± 2 × Standard Deviation (SD); RSD (%) = (Mean of Response/SD) * 100; Relative Difference (%) = [(Mean2nd analyst − Mean1st analyst)/Mean1st analyst] * 100.

Table 6. Concentration of fatty acids (n = 7) found in Quality Control Material (NIST 3290-Dry Cat Food) used in the verification of the hydrolysis and derivatization procedure.

Where: Acceptable Range = Mean ± 3 × Standard Deviation (SD); RSD ( % ) = ( SD / Mean of Response ) * 1 00 .

analyst repeated portions of the validation and the results were compared. The Reference Material results for the second analyst were within the acceptable range with results of 170 and 181 mg/g which meet the criteria of 2 standard deviations of the established mean. See Table 5. The results for the following analytes on the quality control sample for the second analyst were within three standard deviations of the established mean.

The egg samples were also analyzed by the second analyst. Results for DHA (C22:6) were found to be within three standard deviations of the established mean. The mean established by the first analyst for DHA was 0.504%, with a standard deviation of 0.005%. Calculating ± 3 standard deviations around the mean, this equates to an acceptable range of 0.489% to 0.519%. The second analyst had mean results of 0.513% for DHA, which is within the acceptable range (Table 4). The recoveries on the spiked matrix samples ranged between 91% and 108% for the second analyst, within the acceptable criteria of 90% to 110%. See Table 3.

3.1. Short and Long-Term Stability of Egg Samples

3.1.1. Stability of FAME Stock Solutions

New stock solutions were compared against the original stock solutions which were prepared prior to use on experiments. The change of the seven fatty acid FAME analytes between the old stock solution and new stock solutions were determined to be between −1.9% and 8% relative difference and showed stability for 207 days (over six months).

3.1.2. Stability of Calibration FAME Standard Solutions

Fresh calibration solutions were prepared for each analysis performed on the GC instrument autosampler. Repeated injections were performed at the start and end of the sequence to confirm stability over the course of the analysis. The calibration solutions at the end of the sequence ranged from −5.9% to 3.5% relative error compared to the calibration solutions at the beginning of the sequence. This is within the acceptable range of ±20% relative error.

3.1.3. Short-Term Stability—Extracts

Short term stability testing was carried out on egg extracts from the accuracy study at room temperature to account for the shelf life of the extracted analytes during the testing procedure. This involved spiking at three different concentration levels, 0.1% (w/v), 0.25% (w/v) and 0.4% (w/v). Three aliquots for each of the three levels were studied, for a total of nine aliquots. The extracts were analyzed at 2 hours, 24 hours and 48 hours. The relative error (%) was calculated as the difference between the mean recovery at time t and the mean recovery at time 0 (2 hours), divided by the mean recovery at time 0, expressed as a percentage. The calculation formula can be found as a footnote on Table 8. The relative error (%) was found to be within ±20% relative error (ranging between −6.4% to 2.9%) compared to extracts from initial extraction (T = 0 (2 hours)) for the parameters monitored: C14:0, C17:0, C18:0 and C22:6. The analytes were deemed to be stable at room temperature at the 2-hour, 24 hour and 48-hour mark. See Table 7.

3.1.4. Long-Term Stability

Long term stability testing was carried out on the freeze-dried and stored egg, to evaluate the stability of the analytes and egg matrix during the anticipated storage time of the samples. For the 4- and 8-week time frames, the stored samples were within ±20% relative error (ranging between −20% to 7.0%) compared to extracts from initial extraction (T = 0) for the parameters monitored: C14:0, C17:0, C18:0 and C22:6. For the 12-week stability samples, however, the data for C18:0 was outside the range of ±20% relative error, with results of −36%, −26% and −20% for the 0.1%, 0.25% and 0.4% spiking levels, respectively. For 16, 20, and 26 weeks storage, results for C18:0 remained outside the range of ±20% relative error for the 0.1% spiking level only. Results for C18:0 at the 0.25% and 0.4% spiking levels were within ±20% relative error. Results for the other three analytes, C14:0, C17:0, and C22:6 remained within ±20% relative error for all time periods up to 26 weeks. Based on the results, it can be stated that C18:0 is stable for up to 8 weeks, and C14:0, C17:0, and C22:6 are stable for up to 26 weeks of frozen storage. See Table 8.

Table 7. Short-term stability (2, 24, 48 hour) of four fatty acids (% recoveries [±RE%]) in whole chicken egg extracts spiked (0.1%, 0.25% and 0.4% µg/ml; n = 3) with mixed FAME standard solution.

Where: R E % ( Relative Error % ) = [ ( X t X t 0 ) / X t 0 ] * 1 00 .

3.1.5. Freeze and Thaw

The freeze and thaw process consisted of repeated analysis of egg samples over the course of four freeze and thaw cycles. Freezing was established at ≤−16˚C overnight and thawing took place at room temperature for more than two hours. Initial analysis after one freeze-thaw cycle established the baseline measurement. Sample aliquots were tested after each freeze-thaw cycle for four cycles. The results after each freeze-thaw cycle compared to extracts from initial extraction (T = 0 (cycle 1)) for the parameters monitored: C14:0, C17:0, C18:0 and C22:6 ranged from −9.6% to 0.8%, within the acceptable range of ±20% relative error. The analytes were deemed to be stable over four freeze and thaw cycles (Table 9).

Table 8. Long-term (26 week) stability of four fatty acids (% recoveries [±RE% compared to Time 0]) in whole chicken egg extracts spiked (0.1%, 0.25% and 0.4% µg/ml; n = 3) with mixed FAME standard solution.

Table 9. Freeze and Thaw Stability (four cycles) of four fatty acids in chicken egg extract at a spiked concentration of 3000 µg/ml.

FTC: Freeze thaw cycle number.

4. Conclusion

Considering that whole egg is frequently consumed, either as a stand-alone food item in the diet or in the formulation of a variety of food products, with the growing trend in omega-3 biofortification through the chicken’s diet, the establishment of an accurate quantification assay for the determination of the fatty acid composition is important for nutritionists and regulatory scientists. From the results of our study, the suitability of the AOAC method 996.06 for the determination of DHA (C22:6) and three additional fatty acids (C14:0, C17:0 and C18:0) was established for an individual whole chicken egg. The method was verified for use by examining the method parameters, linearity, accuracy and precision, specificity and by determining the LOD and LOQ for each analyte. The results of the accuracy and precision experiments were within acceptable limits for the individual whole chicken egg matrix, along with robustness of the method confirmed through limited variability of the analysis precision and accuracy when investigated by a second analyst. The measured fatty acid components of the egg products showed good stability when subjected to 4 freeze-thaw challenge cycles and DHA was stable when stored for up to 26 weeks at −20˚C.

Acknowledgements

Experimental analyses were performed by Huey Kuan, Gloria Wang, Yuki Nakagawa of Merieux NutriSciences (Burnaby). The authors would like to express their gratitude to Ms. Rebecca Timmons (Alltech USA) for her technical input.

Declaration of Conflicting Interests

The funders had no role in the design of the study; in the collection, analyses, or the interpretation of data. GD, AY and CM work for Alltech, who sponsored the research, contributed to the writing of the manuscript and in the decision to publish the results.

Conflicts of interest

The authors declare that there is no conflict of interest regarding the publication of this paper.

Cite this paper

Dillon, G.P., Yiannikouris, A., Brandl, W., Cardinall, C., Yuan, W. and Moran, C.A. (2019) Matrix Extension with Fitness for Purpose and Stability Assessment of DHA and Additional Fatty Acids in Individual Whole Chicken Eggs. Food and Nutrition Sciences, 10, 517-532. https://doi.org/10.4236/fns.2019.105038

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Abbreviations

DHA = Docosahexaenoic Acid

EPA = Eicosapentaenoic acid

FID = Flame Ionization Detector

GC = Gas Chromatography

HPLC = High Performance Liquid Chromatography

IS = Internal Standard

LA = Linoleic Acid

LC-PUFA = Long Chain Poly Unsaturated Fatty Acids

LOD = Limit of Detection

LOQ = Limit of Quantitation