7 Using the internal normalization method, we want to determine the mass composition of a sample made of four butyric esters. A reference solution of these four esters (with known mass concentrations) leads to the following relative response factors for methyl ester (ME), ethyl ester (EE), and propyl ester (PE) as compared to butyl ester (BE): From the information provided by the chromatogram of the sample being assayed, find the mass composition of this mixture.Peak No.tR CompoundArea (arbitrary units)12.54Methyl ester (ME)2,340.123.47Ethyl ester (EE)2,359.035.57Propyl ester (PE)4,077.347.34Butyl ester (BE)4,320.7
8 Assay of serotonin S (5‐hydroxytryptamine) using the internal standard method.We sample 1 ml of the solution to assay, to which we add 1 ml of a solution containing 3 ng of N‐methylserotonin (NMS). We treat this mixture to remove all other intrusive compounds from it. We perform solid‐phase extraction to isolate serotonin and its methyl derivative, diluted in a suitable phase.Why do we add the internal standard compound before the extraction stage?Calculate the response factor of serotonin with respect to N‐methylserotonin, knowing that the calibration chromatogram leads to the following results:‐ serotonin area30,885,982 μV squantity injected: 5 ng‐ N‐methylserotonin area30,956,727 μV squantity injected: 5 ngBased on the chromatogram of the sample solution, find what the serotonin concentration is in the starting sample, knowing that the serotonin peak area is equal to 2,573,832 μV s and the N‐methylserotonin peak area is 1,719,818 μV s.
SOLUTIONS
1 We have tR = tM(1+k). And tM = L/ū and k = KVS/VM, hence tR = (L/ū)(1+KVS/VM).
2 Knowing that VR = tR∙D, we get: α = (VR(2) – VM)/(VR(1) ‐ VM), i.e. α = 1.2.
3 To transform Eq. (P1.1) into Eq. (P1.2), we add k, from tM = tR/(1+k).
4 When peaks are neighbours, base widths are generally comparable. By posing ω1 = ω2 and by expressing ω2 with its value as a function of N2, we obtain R = ¼ √N2 (tR(2) – tR(1))/tR(2). Then, we add k, by using tR = tM(1 + k); finally, we introduce α = k2/k1;The relationship given in the problem is obtained by rearranging the relationship for R (as a function of k and α) and substituting the relationship for Neff from Eq. (P1.2) of problem 1.3.
5 From the base relationship R = 2(tR(2) – tR(1))/(ω1 + ω2), we can replace ω with its value depending on N, ω = 4tR /√N and since tR = tM(1 + k), we obtain Eq. (P1.5);We multiply the second member of (1), numerator and denominator by (k1 + k2) and we obtain α (α = k2/k1).
6 ω0.1 = a + b = 2A ∙ a; A = (a + b)/2a => b = a(2A − 1) => a/b = 1/(2A − 1) => where N = 53,000 plates, tR = 1.58 min and A = 1.07, and thus we get:a = 0.0142 min.b = 0.0162 min.ω0.1 = 0.0304 min.k = (tR − tM)/ tMtherefore, k4 = 4.43 and k5 = 6.62; α4‐5 = k5 /k4 = 1.47; (this assumes that the peak is Gaussian)β = 136.6;K = k β; K4 = 605 and K5 = 884; K5 > K4 means that solute 5 has more affinity for the stationary phase than solute 4; therefore, it is more retained and exits later.
7 %(ME) = 16.6; %(EE) = 16.6; %(PE) = 33.4; %(BE) = 33.4.
8 By adding N‐methylserotonin before extraction, we do not have to take into consideration any potential loss of product due to the various manipulations. We suppose that the extraction yield is the same for these two compounds, which are very similar;kS/NMS = 1.002;serotonin mass: 45 ng/ml.
Note
1 1 The symbols used follow IUPAC recommendations – Pure and Applied Chemistry, 65(4), 819 (1993).
Chapter 2 Gas Chromatography
Gas chromatography (GC) separates compounds that may be vaporized without decomposition when heated. To do so, analytes, in contact with the gaseous mobile phase, are brought to high temperatures. The same goes for the stationary phase caught in the column. GC can be paired with many types of detection, especially mass spectrometry, which often helps in positive identification of analytes. This versatile and very sensitive technique is known for its quick optimization of analytical conditions, and thanks to current advances, such as high‐speed or multidimensional gas chromatography, it is a very attractive and essential resource when studying volatile compounds.
Objectives
Represent a GC device
Choose the carrier gas
Choose the column
Compare the stationary phases
Know the injection methods
List the main detectors
Optimize a separation
Address new orientations of micro GC and fast GC
Explain retention indexes and constants of stationary phases
2.1 COMPONENTS OF A GC INSTALLATION
A gas chromatograph is composed of three components within a single surround. These components include the injector, the column, and the detector associated with a temperature‐controlled oven that enables the column to attain high temperatures (Figure 2.1). The mobile phase that transports the analytes through the column is a gas referred to as the carrier gas. The carrier gas flow, which is precisely controlled, enables great reproducibility of the retention times.
Analysis starts when a very small quantity of sample is introduced in either liquid or gas form into the injector, which has the dual function of vaporizing the sample and mixing it with the gas flow at the head of the column. The column is usually a narrow‐bore tube that coils around itself with a length that can vary from 1 m to over 100 m, depending upon the type and the contents of the stationary phase. The column, which can serve for thousands of successive injections, is housed in a temperature‐controlled oven. At the end of the column, the mobile phase (carrier gas) passes through a detector before it exits to the atmosphere. Some gas chromatograph models of reduced size have their own electrical supply, enabling them to operate in the field (Figure 2.1).
In GC, there are four operational parameters for a given stationary phase: L, length of the column; u, velocity of the mobile phase (which affects the theoretical efficiency N); T, temperature of the column; and β, phase ratio, which affects the retention factor k. The settings of the chromatograph enable modifications in terms of T and u, and therefore both the efficiency of the column and the retention factors can be adjusted as well.
Figure 2.1 Operational diagram of a gas chromatograph and practical uses. a, b) Versatile analytical chromatogram
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