1. Chem. 231 – 2/18 Lecture

2. Announcements Set 2 Homework – Due Wednesday Quiz 2 – Next Monday Set 1 Labs –should be switching instruments today (or after today) –HPLC – instructions on setting up sequence for more efficient use of time Extraction Labs –SPE/HPLC lab completed (hand out) –I hope to have SPME/GC lab ready soon

3. HPLC – Using Sequences Demo showed how to analyze samples, one sample at a time Using autosampler to run a sequence is useful to: –run multiple samples in a defined way (e.g. calibration standards after method optimization is done) –run samples while doing other work (preparing GC lab samples or going home) –if left running unattended, must use working “Exit” program

4. HPLC – Using Sequences Sequences will be kept in Sequence Folder

5. HPLC – Using Sequences Start a new sequence

6. HPLC – Using Sequences Sequence Parameters and Table Need Setting

7. HPLC – Using Sequences Sequence Parameters gives: Data Location and names Shut down can be set here (but we have done this using an Exit program)

8. HPLC – Using Sequences Sequence Table gives: –auto sampler location/sample name –method –No. injections per sample –Info if using ChemStation Calibration Add Exit method on last line to shut down

9. Questions I On extractions, low performance LC, and integration 1.Fatty acids are being trapped using a C18 SPE column and then analyzed by HPLC with a C18 column (both under acidic conditions). The elution order observed on the column is: C12, C16:1, C14, C18:2, C16, C18:1, C18. Efficiency tests with C14 show 98% recovery. Will all other fatty acids be retained with similar recovery? If not, which will have a risk of reduced recover? 2.Furans are recovered on a diol type SPE cartridge out of transformer oil diluted in hexane. They are eluted using 50% methanol, 50% water. They are then analyzed using reversed phase HPLC. How can you use the HPLC elution order to predict poor trapping or elution efficiency on the SPE cartridge. 3.If in the SPE analysis in question 2, the chemist forgot to wash the SPE cartridge with hexane after sample application, what would be the consequence?

10. Questions II On extractions, low performance LC, and integration 1.Under which of the following conditions would you want to use low performance LC? a) separation of chemically similar natural products from a plant sample to obtain mg quantities b) separation of mg quantities of reaction products from chemically dissimilar reactants and side products c) analysis of ng quantities of pesticides from food samples d) separation of  g quantities of reaction products from chemically dissimilar reactants and side products 2.When is it important to set the integration criteria carefully to distinguish between noise and peaks? a) when peaks have small signal to noise ratios b) when many peaks overlap c) when peak width changes over the chromatogram

11. Questions III On extractions, low performance LC, and integration Looking at the chromatogram to the right, and integrated as shown a) Which peak has the largest percent integration error? b) Is the true area for this peak larger or smaller? A B

12. Quantitation in Chromatography Levels of Detection and Quantification Limit of Detection (LOD): –minimum detectable signal can be defined as S/N peak-to-peak = 2 to 3.3σ –minimum detectable concentration = concentration needed to get S/N peak-to-peak = 2 or S/σ = 3.3 –Calculate as 2N/m where m = slope in peak height vs. conc. calibration plot –Minimum detectable quantity = (minimum detectable conc.)(injection volume) Limit of Quantification (LOQ): –Calculated in similar fashion as LOD –Lowest concentration to give an “reasonable” conc. (e.g. can be “auto-integrated” using software) –Typically 5∙LOD

13. Quantitation in Chromatography LOD/LOQ example For LOD and LOQ calculations, the peak height must be used as signal (not peak area) Determine the LODs and LOQ for the following example. Determine it for the 4.6 min peak if the concentration is 0.4 ng μL -1. Use the 3.3 and 2N LOD defintions.

14. Quantitation in Chromatography Calibration Software for Calculations –Instrument Software (e.g. ChemStation) typical method used in industry requires setting up all work before running standards often allows checks of calibration quality before running samples –Excel we will use here for a number of reasons (only have to learn one software program, example spreadsheets often available in texts, more data processing flexibility)

15. Quantitation in Chromatography Calibration Calibration Methods – using Excel –External Standard – linear calibration Standards prepared Standards and Samples analyzed on same day Use Excel spreadsheet in HW Set 1, problem 3 as an example Also, see p. 301-302 of Miller and p. 87-91 of Harris (Quantitative Chemical Analysis) for examples –Non-linear Calibration With some detectors (S – FPD and ELSD) or when operating at high concentrations, non-linear calibration curves are needed Mostly can use Y = a + bx + cx 2 (2 nd order polynomial fit) or power fit (logY = b + mlogC or Y = 10 b C m ) methods Statistics to find uncertainty is much more complex

16. Quantitation in Chromatography Calibration Example of Power Fit –Data for maltoheptaose (7 glucoses linked together) run with HPLC-CAD –Linear fit appears not bad, but also not good –Power fit shows clear non-linear exponent

17. Quantitation in Chromatography Calibration Calibration Methods – using Excel –Internal Standard See p. 303-304 of Miller and p. 109 - 110 of Harris Text Needed for GC with manual injection Best results when external calibration plot is replaced with area ratio vs. conc. ratio –Surrogate Standard Method See p. 300-301 of Miller Used when no standard is available Will only work when response is predictable (e.g. NPD with known #N atoms in surrogate standard and unknown) Predictable means either same response or same response on some basis (area/#Ns per molecule in above example) Concentration A X /A S Conc. X (constant conc. S)

18. Quantitation One Question 1.A scientist is using GC-NPD to quantitate hydrocarbons. The NPD is expected to generate equal peak areas for equal numbers of nitrogen in a sample. Determine the concentrations of compounds X and Y based on the calibration standard (pyridine). CompoundC5H5NC5H5NX = C 6 H 6 N 2 Y = C 8 H 10 N 4 O 2 Area35202991839 Conc. (ug mL -1 ) 10.0??