| Literature DB >> 29726583 |
Flavia Izzo1, Martina Schäfer2, Philip Lienau2, Ursula Ganzer2, Robert Stockman1, Ulrich Lücking2.
Abstract
An unprecedenteEntities:
Keywords: N-functionalization; drug design; medicinal chemistry; structural diversity; sulfonimidamides
Year: 2018 PMID: 29726583 PMCID: PMC6055826 DOI: 10.1002/chem.201801557
Source DB: PubMed Journal: Chemistry ISSN: 0947-6539 Impact factor: 5.236
Figure 1General structures of sulfonamides 1 (1° R2, R3=H; 2° R2=H, R3≠H; 3° R2≠H, R3≠H), sulfonimidamides 2 (1° R2, R3=H; 2° R2=H, R3≠H; 3° R2≠H, R3≠H), sulfinamides 3 (1° R2, R3=H; 2° R2=H, R3≠H; 3° R2≠H, R3≠H) and sulfoximines 4.
Figure 2Structures of the sulfonimidamide analogues 5 and 6 of the clinical sulfonamide‐containing anticancer agent tasisulam5 and non‐steroidal anti‐inflammatory drug celecoxib,6 as well as of the sodium channel inhibitor 7 7 disclosed in a recent patent application.
Scheme 1Synthesis of N‐functionalized tertiary sulfonimidamides by various methods using =NH sulfonimidamide 2 aa as a model compound.
Exploration of the substrate scope of the palladium‐catalyzed N‐arylation of tertiary =NH sulfonimidamide 2 aa: Variation of aryl bromide 8.
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| Aryl bromide (R4Br) | Isolated yield [%] |
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Figure 3ORTEP plot (50 % thermal ellipsoids) of the crystal structure of N‐arylated sulfonimidamide 2 bk.
Figure 4Examples of clinical and commercial sulfoximines: BAY 1251152, AZD 6738, suloxifen and sulfoxaflor.
Exploration of the substrate scope of the N‐alkylation of tertiary =NH sulfonimidamide 2 aa: Variation of alkyl halide 9.
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| Alkyl halide (R4Br/I) | Isolated yield [%] | |
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Scheme 2Synthesis of N‐trifluoromethylated tertiary sulfonimidamide 2 cs.
Scheme 3Synthesis of N‐cyanated tertiary sulfonimidamide 2 da.
N‐Sulfonylation of tertiary =NH sulfonimidamide 2 aa with sulfonyl chlorides 10 a,b.
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| Sulfonyl chloride (R5SO2Cl) | Isolated yield [%] |
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N‐Alkoxycarbonylation of tertiary =NH sulfonimidamide 2 aa with chloroformates 11 a,b (carbamate formation).
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| Chloroformate [R6OC(O)Cl] | Isolated yield [%] |
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N‐Aminocarbonylation of tertiary =NH sulfonimidamide 2 aa with isocyanates 12 a–f (urea formation).
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| Isocyanate (R7N=C=O) | Isolated yield [%] | |
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Comparison of the in vitro properties of sulfonamide 1 aa and the analogous =NH sulfonimidamide 2 aa with a structural variety of N‐functionalized sulfonimidamides.
| Compound | Recovery |
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| Efflux | log |
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| 100 (1) | 69 (h) | 4.3 | 393 | 0.64 | 2.6 |
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| 100 (1) | 97 (h) | 14 | 378 | 0.59 | 1.9 |
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| 100 (1) | 100 (h) | 3.3 | 164 | 1.5 | 1.9 |
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| 100 (1) | 100 (h) | 20 | 363 | 0.67 | 2.0 |
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| 100 (1) | 87 (h) | 7.8 | 256 | 0.73 | 2.2 |
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| 100 (1) | 84 (h) | 19 | 404 | 0.57 | 2.4 |
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| 100 (1) | 82 (h) | 26 | 400 | 0.61 | 2.6 |
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| 100 (1) | 65 (h) | 11 | 404 | 0.57 | 3.0 |
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| 56 (1) | 19 (h) | 6.8 | 192 | 0.70 | 3.7 |
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| 100 (1) | 8.3 (h) | 2.1 | 252 | 0.45 | 4.3 |
[a] Hydrolytic stability measured as recovery of test compound after 24 hours with stirring at pH 1 (HCl buffer), pH 7 (phosphate‐buffered saline) and pH 10 (sodium borate buffer).48 [b] Predicted hepatic metabolic first pass given as the maximum oral bioavailability F max based on a metabolic stability assay using (i) pooled human liver microsomes (hLMs), (ii) pooled rat liver microsomes (rLMs), (iii) pooled mouse liver microsomes (mLMs) and (iv) freshly harvested rat hepatocytes (rHep).49 [c] P app A‐B (apical to basolateral) and efflux ratio (ER) data were generated in a bidirectionally performed Caco2 permeability assay in a 24‐well format; ER was calculated as P app B‐A/P app A‐B.49 [d] Determined by reversed‐phase HPLC.50