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Screening of a Sulfonamides Library by Supercritical Fluid Chromatography Coupled to Mass Spectrometry (SFC-MS). Preliminary properties-retention study.

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Presentation on theme: "Screening of a Sulfonamides Library by Supercritical Fluid Chromatography Coupled to Mass Spectrometry (SFC-MS). Preliminary properties-retention study."— Presentation transcript:

1 Screening of a Sulfonamides Library by Supercritical Fluid Chromatography Coupled to Mass Spectrometry (SFC-MS). Preliminary properties-retention study. SFC User Meeting Cambridge 31 st May – 2 nd June 2006 Amaury Cazenave Gassiot Dr. G. John Langley

2 SFC User Meeting - Cambridge - 2006 2 OUTLINE  Introduction  SOTLIB Library  Isocratic study  Retention models in chromatography  Polycratic study - Looking for linear relationships - Correlating data with physico-chemical properties  Conclusion and future work

3 SFC User Meeting - Cambridge - 2006 3 INTRODUCTION  SFC-MS appears more and more as a technique complementary to HPLC for high throughput analysis  Importance of knowing which technique is more suitable for a specific type of analytes  Possibility of outlining a set of properties-based rules allowing prediction of the retention of a given compound by SFC ?  To investigate those questions: design of a small library of sulfonamides compounds to be screened by SFC

4 SFC User Meeting - Cambridge - 2006 4 SOTLIB LIBRARY: NEUTRAL SET  Coupling of 4 sulfonyl chlorides with 3 amines  All compounds synthesized and analysed by SFC

5 SFC User Meeting - Cambridge - 2006 5 SOTLIB LIBRARY: BASIC SET  Coupling of 4 sulfonyl chlorides with 5 amines  All compounds synthesized and analysed by SFC

6 SFC User Meeting - Cambridge - 2006 6 ISOCRATIC STUDY: NEUTRAL SET (I)  Screening of the library using isocratic elution  Neutral set studied on: - 2-ethyl-pyridyl column 4.6x250mm - cyano column 4.6x250mm - diol column 4.6x250mm - bare silica column 4.6x250mm  Chromatographic Conditions: - mobile phase: 20% v/v MeOH in CO 2 - flow: 4mL.min -1 - temperature: 35°C - outlet pressure: 100 bars - injection volume: 4mL (~0.5mg.mL -1 )

7 SFC User Meeting - Cambridge - 2006 7 ISOCRATIC STUDY: NEUTRAL SET (II)  Retention time related to structure of compounds  2-ethyl-pyridyl (2-EP) and cyano columns: tR tR  tR tR   On 2-EP phase: co-elution of 2 compounds, despite distinct physico-chemical properties.

8 SFC User Meeting - Cambridge - 2006 8  Different trend observed on diol and silica phases: benzimidazole derivatives eluted the latest  On bare silica column: compounds 3 and 9 co-eluting tR tR  tR tR  ISOCRATIC STUDY: NEUTRAL SET (III)

9 SFC User Meeting - Cambridge - 2006 9 COLUMN COMPARISON  Compounds not more retained by a particular column  Same interactions between compounds and all four columns ?  Retention mechanism mainly due to free silanol groups ?  Method: isocratic 20% MeOH, 4mL/min, 35°C, 100 bars

10 SFC User Meeting - Cambridge - 2006 10  Screening of the library using isocratic elution  Basic set studied on: - 2-EP column 4.6x250mm - cyano column 4.6x250mm - diol column 4.6x250mm  Chromatographic Conditions: - modifier: MeOH + 0.1% v/v DEA - mobile phase: 20% v/v modifier in CO 2 - flow: 4mL.min -1 - temperature: 35°C - outlet pressure: 100 bars - injection volume: 4mL (~0.5mg.mL -1 ) ISOCRATIC STUDY: BASIC SET (I)

11 SFC User Meeting - Cambridge - 2006 11  Retention time related to structure of compounds  BUT: only with regards to sulfonyl part  Same trend as observed for neutrals: tR tR  ISOCRATIC STUDY: BASIC SET (II)  Diol columns: 4 compounds not eluted:

12 SFC User Meeting - Cambridge - 2006 12 COLUMN COMPARISON  More differences than observed with neutral set  However retention close on all columns for most of the compounds  Retention mechanism mainly due to free silanol groups ?  Isocratic elution, 20% MeOH+0.1%DEA, 4mL/min, 35°C, 100 bars

13 SFC User Meeting - Cambridge - 2006 13 LIMITS OF THE ISOCRATIC APPROACH  No simple correlation highlighted between physico-chemical properties and t R on the silica column  Is the isocratic approach right?  Indeed: methanol composition (20%) chosen arbitrarily  So, why 20% and not 30% ?  Retention time: the most obvious parameter, but is it the most appropriate ?

14 SFC User Meeting - Cambridge - 2006 14  More than the retention time, the capacity ratio k is a convenient way to normalize the retention of an analyte:  Most successful models of retention developed by Snyder 1 and Soczewinski 2, in reverse phase systems like ODS/H 2 O+MeOH:  In normal phase system, strong deviation observed, but linear correlation can be found in log-log coordinate system: 1.Snyder, L. R., Principles of Adsorption chromatography. First ed.; M. Dekker: New York, 1968 2.Soczewinski, E., Mechanistic molecular model of liquid-solid chromatography - Retention-eluent composition relationships. Journal of Chromatography A 2002, 965, (1-2), 109-116 RETENTION MODEL IN CHROMATOGRAPHY (I)

15 SFC User Meeting - Cambridge - 2006 15  Regression analysis: calculation of intercept log k w and slope  log k w : standardised parameter more reliable than arbitrary isocratic log k  Start of “polycratic” study, aim: calculation of intercept “log k 0 ” and slope S RETENTION MODEL IN CHROMATOGRAPHY (II) log k = S x  + log k w

16 SFC User Meeting - Cambridge - 2006 16  Requirement: keep log k within a range of “practical interest” as defined by Schoenmaker et al. 1 : 0 < log k < 1  Getting the retention factor within the range: - slow eluting compounds: no difficulties since increasing  allows to elute them soon enough - fast eluting compounds: decreasing  doesn’t systematically allow sufficient increase in retention to comply with requirement  Consequence: some compounds to be removed from study  Analyses carried out three times, plotting of mean values « POLYCRATIC » STUDY 1.Schoenmaker et al. Journal of Chromatography 1979, 185, 179-195

17 SFC User Meeting - Cambridge - 2006 17 2-EP COLUMN  10 compounds within k range  plot  vs. log k: R 2 > 0.98  log k 0 and S calculated for the 10 compounds

18 SFC User Meeting - Cambridge - 2006 18  7 compounds within k range  plot  vs. log k: R 2 > 0.99  log k 0 and S calculated for the 7 compounds SILICA COLUMN

19 SFC User Meeting - Cambridge - 2006 19  11 compounds within k range  plot  vs. log k: R 2 > 0.99 (except compound 6 at R 2 =0.92)  log k 0 and S calculated for the 11 compounds CYANO COLUMN

20 SFC User Meeting - Cambridge - 2006 20  8 compounds within k range  plot  vs. log k: R 2 > 0.97  log k 0 and S calculated for the 8 compounds DIOL COLUMN

21 SFC User Meeting - Cambridge - 2006 21 CORRELATING DATA WITH COMPOUNDS PROPERTIES (I)  On none of the columns, log k 0 and S could be correlated with lipophilicity constants of the analytes (log P [ACD and Spartan], log D at pH 7.4) nor with pKa values.  However, other properties of the neutral set compounds calculated with Spartan, e.g.: - total dipole moment  - surface area A - volume V - electronic charges on single atoms  Multiple regression analysis performed to correlate properties with retention characteristics log k 0 and S

22 SFC User Meeting - Cambridge - 2006 22  On 2-EP column: when regressing log k 0 vs. , A and  min : log k 0 = 0.232  + 0.001 A – 1.325  min – 2.200 R=0.95 when regressing S vs. , A and  min : S = -0.003  - 1.6x10 -5 A + 0.27  min – 0.023 R=0.90 exp log k 0 vs predicted log k 0 R=0.95 exp S vs predicted S R=0.90 CORRELATING DATA WITH COMPOUNDS PROPERTIES (II)

23 SFC User Meeting - Cambridge - 2006 23  On cyano column: when regressing log k 0 vs. , A and  min : log k 0 = 0.063  + 0.001 A – 1.579  min – 1.25 R=0.94 when regressing S vs. , A and  min : S = -0.011  - 2.2x10 -5 A + 0.071  min – 0.040 R=0.84 exp log k 0 vs predicted log k 0 R=0.93 exp S vs predicted S R=0.80 CORRELATING DATA WITH COMPOUNDS PROPERTIES (III)

24 SFC User Meeting - Cambridge - 2006 24  On diol column: when regressing log k 0 vs. , A and  min : log k 0 = 0.124  + 0.0002 A – 1.409  min – 1.173 R=0.97 when regressing S vs. , A and  min : S = -0.0004  - 1.1x10 -5 A + 0.030  min – 0.008 R=0.95 exp log k 0 vs predicted log k 0 R=0.97 exp S vs predicted S R=0.95 CORRELATING DATA WITH COMPOUNDS PROPERTIES (IV)

25 SFC User Meeting - Cambridge - 2006 25  On silica column: when regressing log k 0 vs. , A and  min : log k 0 = 0.119  - 0.001 A – 1.714  min – 1.178 R=0.99 when regressing S vs. , A and  min : S = -0.0008  - 7.7x10 -5 A + 0.040 min – 0.012 R=0.84 exp log k 0 vs predicted log k 0 R=0.99 exp S vs predicted S R=0.84 CORRELATING DATA WITH COMPOUNDS PROPERTIES (V)

26 SFC User Meeting - Cambridge - 2006 26  Isocratic approach: highlighting of trends in retention  Polycratic study: CONCLUSION (I) - supposed better characterization of the retention - no correlation of log k 0 or S with lipophilicity constants or pKa - study of 12 neutral sulfonamides on 2-EP, cyano, diol and bare silica stationary phases - linearity found for log k = log k 0 + S x ϕ R 2 >0.97

27 SFC User Meeting - Cambridge - 2006 27 CONCLUSION (II)  Correlating retention characteristics and molecular descriptors - Retention characteristics log k 0 and S correlated with total dipole moment μ, surface area A and atomic charge on the most negatively charged atom δ min - Encouraging results for log k0 which are correlated with molecular descriptors with R > 0.94 on all four stationary phases - Less promising results for S, especially on cyano and silica columns (R = 0.84). - Results to be considered with care, since obtained on small set of structurally similar compounds.

28 SFC User Meeting - Cambridge - 2006 28 FUTURE WORK  Analysis of a set of 20 basic sulfonamides currently under way  Study to be extended to compounds of different structures  Recalculation of molecular descriptors by more powerful algorithms under way  Regression analysis using other descriptors has to be undertaken in an attempt to highlight better correlation (experimental log P to be measured)

29 SFC User Meeting - Cambridge - 2006 29 ACKNOWLEDGEMENTS

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