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HomeGas Chromatography (GC)Fast GC for Trans FAME Analysis

Fast GC for Trans FAME Analysis

Len Sidisky, Kathy Stenerson, Rodney George, Greg Baney

Reporter EU Volume 18

Introduction

There is a confirmed link between consumption of foods that contain trans fatty acids and LDL or so-called bad cholesterol levels. High LDL levels are associated with increased risk of coronary heart disease, the leading cause of death in the US and a growing concern in other parts of the world. Trans fatty acids, also known as trans fat, are made by hydrogenation of liquid oils which solidifies the oils and increases the shelf life and flavor stability of the oils and foods that contain them, including vegetable oils, crackers, candies, baked goods, cookies, snack foods, fried foods, salad dressings and many other processed foods. The US Food and Drug Administration (FDA) recently amended its regulations on nutritional labeling to require that the amount of trans fatty acids in a food be included in the Nutrition Facts panel. (See US FDA 21 CFR Part 101, Sec. 101.62 “Nutrient content claims for fat, fatty acid, and cholesterol content of foods.”) Because of their impact on health, the measurement of trans fatty acid levels requires a reliable analytical method.

Section Overview

FAME analysis by capillary GC

Whereas the fatty acid trans isomers have adverse health affects, the cis isomers typically do not. Therefore it important to be able to resolve positional cis-trans isomers in food samples to ensure the food conforms to label requirements. Capillary GC is by far the most common analytical tool to measure fatty acids in food and other matrices. (The fatty acids are first derivatized to the corresponding methyl esters (FAME) to improve their volatility prior to GC analysis.) Capillary GC columns provide the necessary selectivity to resolve cis-trans pairs and can provide rapid analysis, which is important since more samples are continually analyzed on a day-to-day basis.

For analysts employing capillary GC for FAME analysis, two critical aspects of the method need to be optimized:

  • Speed of the FAME analysis – to maximize throughput
  • Selectivity of GC stationary phase – to ensure resolution and reliable quantification of critical pairs

To address these issues we evaluated approaches to decreasing the analysis times of trans FAMEs while using selective capillary columns to provide the desired sample resolution.

Fast GC in FAME analysis

Reducing the run time of a GC separation can be achieved by the use of shorter capillary columns, decreased column internal diameter, thinner stationary phase films, H2 carrier gas, higher carrier gas velocities, optimized α values, selective detectors, faster oven temperature programming rates and combinations of the parameters in this list. However, one must be careful to understand the impact of these changes on the resolution of the method.

In our work, we focused on using narrow bore capillary columns (<250 μm I.D.) in combination with higher carrier gas linear velocities and fast temperature programming rates using H2 as the carrier gas in order to reduce analysis times while maintaining necessary sample resolution.

Column selectivity in FAME analysis

Selectivity was evaluated by preparing polar and highly polar capillary columns. Polar polyethylene glycol columns resolve FAMEs by degree of unsaturation, with minimal overlap of the carbon chain lengths. They also resolve cis and trans isomers. Highly polar cyanosilicone columns, depending upon the column type, will also resolve cis and trans isomers and positional geometric isomers.

Separation of FAMEs by carbon chain length and degree of unsaturation

Polar Omegawax and SUPELCOWAX™ (polyethylene glycol) capillary columns are the choice for resolving FAME isomers according to carbon chain length and degree of unsaturation, with minimal carbon chain length overlap. Figure 1 demonstrates the fast GC analysis of a 37-component FAME mix on this polar column. The analysis time is about 5 minutes. The elution order within a carbon chain length is: saturated, monoene, diene, triene, etc. Minimal resolution of the cis and trans isomers is achieved on this column as shown by the resolution of methyl eladate (peak 17) from methyloleate (peak 18) and methyllinolelaidic (peak 19) from methyllinoleate (peak 20). In both cases, the cis isomer elutes prior to the trans isomer.

Column: SUPELCOWAX™ 10, 15 m x 0.10 mm 1.0 I.D., 0.10 μm
Over: 140 °C, 40 °C/min. to 280 °C (2 min.)
Inj: 250 °C
Det.: FID, 260 °C
Carrier gas: H2 50 cm/sec, constant
Injection: 0.2 µl, 200:1 split
Liner: 4 mm I.D., cup split
Sample: 37-component FAME Mix
A graph demonstrating the fast GC analysis of a 37-component FAME mix on this polar column.

Figure 1.37-component FAME MIX on SUPELCOWAX™ 10

Peak List

  1. Butyric (C4:0)
  2. Caproic (C6:0)
  3. Caprylic (C8:0)
  4. Capric (C10:0)
  5. Undecanoic (C11:0)
  6. Lauric (C12:0)
  7. Tridecanoic (C13:0)
  8. Myristic (C14:0)
  9. Myristoleic (C14:1)
  10. Pentadecanoic (C15:0)
  11. cis-100-Pentadecanoic (C15:1)
  12. Palmitic (C16:0)
  13. Palmitoleic (C16:1)
  1. Heptadecanoic (C17:0)
  2. cis-10-Heptadecanoic (C17:1)
  3. Stearic (C18:0)
  4. Elaidic (C18:1n9t)
  5. Oleic (C18:1n9c)
  6. Linolelaidic (C18:2n6t)
  7. Linoleic (C18:2n6c)
  8. Arachidic (C20:0)
  9. γ-Linolenic (C18:3n6)
  10. cis-11-Eicosenoic (C20:1)
  11. Linolenic (C18:3n3)
  12. Heneicosanoic (C21:0)
  13. cis-11, 14-Eicosadienoic (C20:2)
  1. Behenic (C22:0)
  2. cis-8,11,14-Eicosatrienoic (C20:3n6)
  3. Erucic (C22:1n9)
  4. cis-11,14,17-Eicosatrienoic (C20:3n3)
  5. Arachidonic (C20:4n6)
  6. Tricosanoic (C23:0)
  7. cis-13,16-Docosadienoic (C22:2)
  8. Lignoceric (C24:0)
  9. cis-5,8,11,14,17-Eicosapentaenoic (C20:5n3)
  10. Nervonic (C24:1)
  11. cis-4,7,10,13,16,19-Docosahexaenoic (C22:6n3)

Cis and trans FAME isomer separation

Highly polar cyanosilicone based capillary columns are needed to provide cis and trans FAME isomer resolution. Standard cyanosilicones such as SP-2330, SP-2340, and SP-2380 provide group cis and trans isomer resolution, where the trans isomers typically elute first as a group followed by the cis isomer group. Figure 2 demonstrates the fast GC analysis of a 37-component FAME mixture on an SP-2380 0.10 mm I.D. column. C18:1cis and trans FAMEs are included in the sample. Note the improved resolution of the cis and trans pairs (peaks 17/18 and 19/20) compared to the previous SUPELCOWAX™ 10 column separations.

Column: SP-2380, 15 m x 0.10 mm I.D., 0.08 µm
Oven: 125 °C (0 min.), 25 °C /min. to 245 °C (1 min)
Inj: 200 °C
Det.: FID, 260 °C
Carrier gas: H2 45 cm/sec, constant flow
Injection: 0.1 µl, 300:1
Liner: 4 mm I.D. cup split
Sample: 37-component FAME Mix
analysis-of-fame

Figure 2.Fast GC analysis of FAMEs on SP-2380, 15m x 0.10 mm I.D., 0.08 μM (see the Peak List under figure 1).

Positional geometric FAME isomers on SP-2560

A specially prepared and tested 100m x 0.25 mm I.D., 0.20 μM SP-2560 resolves the positional cis and trans isomers. Figure 3 demonstrates this analysis under standard run conditions using helium carrier. Simply switching to H2 carrier gas will reduce analysis time.

176 °C, 17 cm/sec, He

Graph – Resolution of C18:1 Cis/Trans Isomers on SP-2560, 100m x 0.25 mm I.D. x 0.20 μM

Figure 3.Resolution of C18:1 Cis/Trans Isomers on SP-2560, 100m x 0.25 mm I.D. x 0.20 μM

Fast GC on 0.1 mm I.D. columns

In developing a fast GC alternative to this long (100m) column, we investigated decreasing the column internal diameter in order to provide similar resolution in a faster analysis time. Figure 4 demonstrates the analysis on 30m and 35m x 0.10 mm I.D. x 0.08 μM df SP-2560 columns. As shown, these columns do not provide the resolution demonstrated on the 100m column. The 0.10 mm I.D. columns have limited sample capacity, resulting in the columns being easily overloaded. We also investigated various temperature program rates (Figure 4) to try and improve the resolution. Some improvements were noted, but results comparable to the 100m columns were not achieved.

Temperature Programmed Analysis
160 °C (4 min.) 3 °C40/min.
to 185 °C 40 cm/sec H2 @ 160 °C



30 m x 0.10 mm I.D., 0.08 µm

Two graphs - C18:1 Cis/Trans Isomers on the 0.10 mm I.D. SP-2560

Temperature Programmed Analysis
160 °C (4 min.) 3 °C/min. to 185 °C
40 cm/sec H2 @ 160 °C



35 m x 0.10 mm I.D., 0.08 µm

Graph - C18:1 Cis/Trans Isomers on the 0.10 mm I.D. SP-2560

Figure 4.C18:1 Cis/Trans Isomers on the 0.10 mm I.D. SP-2560

Fast GC on 0.18 mm I.D. columns

Since the 0.10 mm I.D columns did not provide the necessary resolution and decreased analysis time, we focused our attention on 0.18 mm I.D. columns. Theoretical calculations predict that a 75m x 0.18 mm I.D. x 0.14 μM SP-2560 should provide similar resolution to the 100m x 0.25 mm I.D. column. Figure 5 shows the results of this analysis.

175 °C, 25 cm/sec, H2

Graph of C18:1 Cis/Trans Isomers on the SP-2560, 75 m x 0.18 mm I.D. x 0.14 μM df.

Figure 5.C18:1 Cis/Trans Isomers on the SP-2560, 75 m x 0.18 mm I.D. x 0.14 μM df

Analysis temperature

We also investigated the effect of analysis temperature on the resolution of the cis and trans C18:1 isomers. Figures 6 through 8 show that slight adjustments in the temperature can affect the resolution of the isomers and the overall analysis time.

175 °C, 25 cm/sec, H2

Graph of temperature effects on the SP-2560, 75 m x 0.18 mm I.D. x 0.14 μM df

Figure 6.Temperature Effects on the SP-2560, 75 m x 0.18 mm I.D. x 0.14 μM df

 

178 °C, 25 cm/sec, H2

Graph of the temperature effects on the SP-2560, 75 m x 0.18 mm I.D. x 0.14 μm df 178 °C, 25 cm/sec, H2

Figure 7.Temperature Effects on the SP-2560, 75 m x 0.18 mm I.D. x 0.14 μM df

 

180 °C, 25 cm/sec, H2

Graph of temperature effects on the SP-2560, 75m x 0.18 mm I.D. x 0.14 μm df 180 °C, 25 cm/sec, H2

Figure 8.Temperature Effects on the SP-2560, 75m x 0.18 mm I.D. x 0.14 μM df

Summary

Fast GC analysis is typically performed using short, 0.10 mm I.D. capillary columns with H2 carrier gas and rapid temperature programming rates. FAMEs can be analyzed with a variety of 0.10 mm I.D. columns, depending upon the information required. SUPELCOWAX™ 10 (polyethylene glycol) polar columns resolve FAME isomers according to carbon chain length and degree of unsaturation. SP-2380 and SP-2560 (cyanosilicone) highly polar columns provide cis and trans resolution of FAME isomers. SP-2560 column length will impact the resolution of positional geometric C18:1 FAME isomers. A 0.10 mm I.D. version of the SP-2560 column does not provide the necessary resolution. However, the 75 m x 0.18 mm I.D. x 0.14 μM df SP-2560 offers the best alternative to the 100 m x 0.25 mm I.D. x 0.20 μM df SP-2560 column for resolving positional geometric isomers in a shorter analysis time. Analysis temperature can affect the resolution and overall analysis time for trans FAME analysis. It is important when reducing the analysis time to consider the impact on overall resolution.

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