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Article

One-Pot Quinazolin-4-yl-thiourea Synthesis via N-(2-Cyanophenyl) benzimidoyl isothiocyanate

1
Department of Organic Chemistry, Faculty of Science, Masaryk University, Brno, Czech Republic
2
Laboratory of Biomolecular Structure and Dynamics, Faculty of Science, Masaryk University, Brno, Czech Republic
3
Department of Inorganic Chemistry, Masaryk University, 611 37 Brno, Czech Republic
*
Author to whom correspondence should be addressed.
Molecules 2001, 6(7), 588-602; https://doi.org/10.3390/60700588
Submission received: 10 November 2000 / Revised: 22 May 2001 / Accepted: 23 May 2001 / Published: 30 June 2001

Abstract

:
1-substituted-3-(2-phenylquinazolin-4-yl) thioureas (7) were produced by an intramolecular cycloaddition reaction of 1-substitued-3-[(2-cyanophenyl- imino)phenylmethyl] thioureas (3). These compounds in turn were prepared by the reaction of N-(2-cyanophenyl)benzimidoyl isothiocyanate (2) with primary amines. The structures of products 7 were confirmed by FTIR, 1H-NMR, 13C-NMR, mass spectroscopy and X-ray crystallography.

Introduction

This work is a continuation of our studies of the competition between the sulfur and nitrogen atoms in a thioamide moiety towards intermolecular and intramolecular reactions with electrophiles [1,2,3]. The intramolecular cycloaddition reaction of the product formed in situ by addition of secondary amines to N-(2-cyanophenyl)benzimidoyl isothiocyanate affords 1,1-disubstituted-3-(2- phenyl-3H-quinazolin-4-ylidene)thioureas [3]. These  cyclic products are  formed via a one-pot reaction sequence including cyclization, Dimroth rearrangement and tautomerisation steps, as reported in [3].

Results and Discussion

The extension of such a reaction to include primary amines, anilines, heterocyclic amines, and adamantanamine derivatives is now reported in this paper. The reaction proceeds by the addition of primary amines to N-(2-cyanophenyl)benzimidoyl isothiocyanate (2) to predictably give the thiourea derivatives 3 [3] (Scheme 1).
Scheme 1. Reaction of the 2 with primary amines and possible reaction pathways
Scheme 1. Reaction of the 2 with primary amines and possible reaction pathways
Molecules 06 00588 g004
These thioureas 3 contain three active nucleophilic sites capable of attacking the available nitrile group via an intramolecular cycloaddition reaction. The expected products might conceivably be one or all of the following cyclic products: benzothiadiazocine derivatives (4) arising via sulfur attack [4,5,6], quinazoline derivatives (6) via nitrogen attack [3] or finally the benzotriazocines (5) via nitrogen attack The reaction could be further extended to involve the Dimroth rearrangement product or could involve tautomerisation to the more stable tautomer [3].
The intramolecular addition reaction of thioureido derivatives containing functionalized carboxyl groups under neutral and basic conditions takes place on the nitrogen atom [7,8]. Consequently, the expected products formed were either the quinazoline 6 or the benzotriazocine 5 derivatives. Of these two options we might expect the quinazoline derivative 6 to be more favored due to the fact that their formation involves creation of a thermodynamically more stable six membered ring. The expected quinazoline derivative 6 might then undergo a Dimroth rearrangement to finally afford the 1-(2-phenylquinazolin-4-yl)-3-substituted thioureas 7. The quinazolines 7 can be stabilized by hydrogen bond interactions to afford an extra six membered ring as shown in Scheme 2. These compounds 7 could undergo a tautomerisation reaction by the transition of the proton of the N(1) of the substituted thioureas to N(3) of the quinazoline ring to give either of the conformations 8 or 9 that might also be stabilized by hydrogen bond interactions (Scheme 2).
Scheme 2. Possible interconversions from 6 to 9 via Dimroth rearrangement and tautomerisation processes.
Scheme 2. Possible interconversions from 6 to 9 via Dimroth rearrangement and tautomerisation processes.
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The spectral data confirmed that the structures of the isolated products were indeed 7. The secondary amine examples behaved differently, undergoing tautomerisation to give the more stable tautomer to thus afford 1,1-disubstituted-3-(2-phenyl-3H-quinazolin-4-ylidene)thioureas [3]. Discrimination between the possible structures of compounds 4-9 was possible using their spectral data as follows: the infrared spectra show both the disappearance of the ν(NCS) and ν(CN) bands present in case of the isothiocyanate 2 and the presence of νNH and ν(C=N) bands at 3220 cm-1 and 1613 cm-1, respectively, for the cyclic forms 7.
The most important peak shown by the 13C-NMR, which plays an important role in the structure identification of the cyclic products, is the one corresponding to the C=S group with a chemical shift of ca 183-184 ppm. Naturally, it is observed in the case of the quinazoline structures 6-9 and the benzotriazocines 5 but not the thiadiazocines 4.
The 1H-NMR spectra show great similarity to the simulated computer spectra; they display an important peak at ca 14 ppm (in the case of the substituted anilines) corresponding to the NH group, which together with X-ray analysis, confirms the hydrogen bond interactions between the quinazoline N(3) and the hydrogen atom of the arylamino group (Scheme 2). The spectra in the case of the aliphatic analogues displayed a peak at ca 12 ppm corresponding to the hydrogen of the alkylamino group. We might expect that the peaks corresponding to NH groups that have interactions with the thiocarbonyl group as in 8 will appear at ca 16 ppm as in the case of secondary amine analogues [3]. The 1H-NMR spectrum of product 7f (R= Ph) was measured in CDCl3 at temperature ranging from -30 °C to 30 °C in order to check whether these three conformers 7-9 interconvert or not, but no changes were observed in the resultant spectra. The 1H-NMR spectrum of 7b gave a doublet peak at ca 4.98 ppm due to the interaction between the CH2 group and the neighboring NH group. Measurement of the 1H-NMR spectrum in CDCl3/D2O, to give a singlet peak at ca 4.97 ppm, proved this.
The mass spectra for all examined products 7 showed the molecular ion, followed by a molecular fragment at m/e 33 which represents the SH moiety and the tricyclic residue of the isolated product at m/e 337 of compound 7g (R= p-tolyl). This last result confirms that the sulfur atom is exocyclic unlike the secondary amine examples where such a fragment is not formed indicating that the sulfur atom is endocyclic. Other fragmentations are represented in Figure 1
Figure 1. Mass spectral fragmentations of 7g.
Figure 1. Mass spectral fragmentations of 7g.
Molecules 06 00588 g001
Single crystals of 7f, 7a and 7b (R= Ph, n-butyl and benzyl, respectively) were used for X-ray analysis [9]. These substituents cover a range of different types to ensure that the structure of the final product is not dependent on the substituent, or the basicity of the amines compared to the anilines [3]. The structural data presented in Table 1, Table 2 and Table 3 correspond to a great extent with those calculated by the ab initio DFT quantum chemistry methods for 7f (R= Ph) [9]. The ORTEP diagram and the calculated model of compound 7f are shown in Figure 2 and Figure 3, respectively.
Figure 2. The ORTEP diagram of compound 7f.
Figure 2. The ORTEP diagram of compound 7f.
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Figure 3. The calculated model of compound 7f.
Figure 3. The calculated model of compound 7f.
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The X-ray structural analysis shows that the isolated products correspond to the Dimroth rearrangement products 7 and not to the two possible tautomeric conformations 8 and 9. The ab initio computational studies together with the X-ray analysis show that the compound 7f (R= Ph) is almost planar having the phenyl ring at position 2 slightly out of plane. The C(15) carbon of the phenylthiourea together with the thiourea moiety and the quinazoline cycle are almost in one plane. The π-electrons are in good conjugation as depicted in Figure 3. The hydrogen bond interactions between the NH group and the N(3) of the quinazoline ring add extra stability to the isolated product 7f (Scheme 2). These hydrogen bond interactions were identified from the X-ray analysis and the computational studies, which show a bond distance of about 1.86 Å and 1.94 Å, respectively.
There were no great energy differences between the two structures 7f (–891009.73 kcal.mol-1) and 8f (–891006.05 kcal.mol-1). This led us to the conclusion that the sulfur atom could be involved in intermolecular hydrogen interactions. However, the probability of this conclusion was decreased after measuring the 1H-NMR at a temperature ranging from –30 °C to 30 °C, which gave the same spectra. The other conclusion, based on the reaction sequence reported in Scheme 2, is that the major product is the one that is formed first, which identify the formation of the Dimroth rearrangement product as the first step and is the isolated product. On the contrary in the secondary amine application [3], the Dimroth rearrangement product is not stabilized by hydrogen interactions so it is less stable than the tautomeric form which have hydrogen bond interactions between the N3 hydrogen and the thiocarbonyl group.
Table 1. Selected interatomic distances in 7f.
Table 1. Selected interatomic distances in 7f.
BondBond Length [Å]BondBond Length [Å]
X-rayHF/6-31G**X-rayHF/6-31G**
N1-C21.311.29C4-C51.431.44
N1-C101.371.36N11-C121.391.38
C2-N31.361.36C12-N131.331.32
C2-C211.481.49C12-S141.661.68
N3-C41.321.30N13-C151.421.43
C4-N111.381.38C5-C101.411.40
Table 2. The most important bond angles in 7f.
Table 2. The most important bond angles in 7f.
Angle [°]X-rayHF/6-31G**Angle [°]X-rayHF/6-31G**
N1-C2-C21119.2118.4N13-C12-N11114.9116.8
C21-C2-N3115.2116.5N13-C12-S14127.6126.4
C2-N1-C10116.3116.0C12-N13-C15131.5126.8
N1-C2-N3125.6125.1C16-C15-N13115.8118.4
C2-N3-C4118.6118.9C4-N11-C12130.7132.7
N3-C4-N11118.7120.1N1-C10-C5122.8122.3
N3-C4-C5121.4121.5C2-C21-C22120.8119.7
Table 3. The most important torsion angles in 7f.
Table 3. The most important torsion angles in 7f.
Torsion angle [°]X-rayHF/6-31G**Torsion angle [°]X-rayHF/6-31G**
S14-C12-N13-C151.160.2640C10-N1-C2-C33.280.310
N3-C2-C21-C22157.74164.77N1-C2- N3-C4-1.38-0.331
N3-C4-N11-C12-4.41-3.338N1-C2-C21-C22-23.62-15.107
C4-N11-C12-N132.590.0585C2-N3-C4-C5-2.76-0.026
N1-C2-C10-C5-1.120.061C2-N3-C4-N11177.88179.752
C2-N1-C10-C9177.17179.922C4-N11-C12-S14-177.39-179.366
We confirmed the structures of the compounds 1-(2-phenylquinazolin-4-yl)-3-substituted thioureas 7a-7s on the basis of the above spectral data, reference data from the computer simulated spectra and from knowledge about the chemistry of the isothiocyanate derivative 2 [3].

Conclusions

1-substituted-3-(2-phenylquinazolin-4-yl) thioureas 7a-s were produced by a regioselective intramolecular cycloaddition reaction of the nitrogen attack at the available nitrile group of the thiourea derivatives 3.

Experimental

General

Melting points of all the compounds were measured on a Boetius Rapido PHMK 79/2106 (Wägetechnik) instrument. TLC was carried out on Silufol UV 254 plates (Kavalier, Votice). TLC detection was accomplished with a Fluotes universal (Quarzlampen, Hanau) instrument and iodine vapors. The eluent used was a (20: 80) mixture of acetone and benzene. Purity of compounds 7 was proven by their elemental analysis, measured on an Erba 1102 instrument. FTIR spectra (results reported as ν ˜ /cm-1) were taken on a Genesis (Unicam) spectrometer on potassium bromide pellets. NMR spectra were measured on a Bruker Avance DRX-500 spectrometer. Unless stated otherwise the 1H- and 13C-NMR spectra were measured in CDCl3 solutions and tetramethylsilane was used as an internal standard. Results are reported in ppm on the δ scale. The measured 13C- and 1H-NMR spectra were correlated with those obtained by on-line simulation (Advanced Chemistry Development, Inc., Toronto, Canada). The X-ray crystal data and structure refinement of compound 7f (Table 4) were collected with a KUMA KM-4 kappa four-circle diffractometer. The structure was solved by direct methods using SHELXS86 [10] and refined on F2 for all reflections using SHELXl93 [11]. Crystals suitable for X-ray determination were obtained in the form of white prisms by recrystallization from CHCl3/petroleum ether at room temperature. The crystallographic data for 7a, 7b and 7f have been deposited with the Cambridge Crystallographic Data Center as supplementary publications number CCDC 149679 – 149681. Geometry optimization of structures 7a, 7b, and 7f was performed at ab initio level of quantum chemical calculation, RHF/6-316** and DFT/VWN/6-316**, respectively. Mass spectra were determined (electron impact, 70 eV) with a Fisons TRIO 1000 and GC 8000 series instrument.
Table 4. Crystal data and structure refinement for 7f.
Table 4. Crystal data and structure refinement for 7f.
Empirical formulaC21H16N4S
Molecular weight356.44
Temperature, k293(2) k
Wavelength, Å0.71073 Å
Crystal system, space groupmonoclinic, P2 (1) / c
Unit cell dimensions
a, Å; α, °9.8405 (8) Å, α= 90 °
b, Å; β, °21.327 (2) Å, β= 95.710 (8)°
b, Å; γ, °16.722 (2) Å, γ= 90 °
Volume, Å33492.0(5) Å
Z; density calculated, mg m-38; 1.356 mg m-3
Absorption coefficient, mm-10.197 mm-1
F(000)1488
Crystal size, mm0.65 X 0.25 X 0.10 mm
θ Range for data collection,3.50- 25.00°
Range of h, k, l-12< = h< =13, -27< = k< = 26, -28< = l< = 21,
Reflections collected18128
Independent reflections6123 [R(INT) = 0.04231]
Refinement methodfull-matrix least-squares on F2
Data; restraints; parameters5483 / 0 / 597
Goodness-of-fit on F20.950
Final R indices [I > 2σ(I)]R1 = 0.0462, wR2 = 0.1192
R indices (all data)R1 = 0.0818, wR2 = 0.1322
Largest diff. Peak and hole0.230 and –0.260 e. Å-3

N-(2-cyanophenyl)benzimidoyl isothiocyanate (2) - acetone solution.

A mixture of N-(2-cyanophenyl)benzamide [3] (0.5 g, 2.25 mmol), and phosphorous pentachloride (0.5 g, 2.4 mmol) in dry toluene were refluxed for 8 h. The solvent was removed under reduced pressure to give a brownish colored oil of N-(2-cyanophenyl)benzimidoyl chloride (1) [3] which was not further purified. A solution of potassium thiocyanate (0.22 g, 2.25 mmol) in dry acetone was added portionwise over 2 h to a stirred and cooled (-5 °C) solution of crude 1 in dry acetone. The precipitated potassium chloride was filtered off to give the acetone solution of N-(2-cyanophenyl)benzimidoyl isothiocyanate (2). The IR spectrum of this solution displayed a strong peak at 2059 cm-1 corresponding to the νNCS band. The isothiocyanate was used without further isolation and purification (to avoid polymerization and destruction of this very reactive compound).

General procedure for the synthesis of 1-substituted–3-(2-phenylquinazolin-4-yl) thioureas (7).

The appropriate primary amine (2.25 mmol) was added portionwise while stirring at room temperature over a period of 1h to the acetone solution of isothiocyanate 3. An additional amount of triethylamine (0.6 ml, 4.5 mmol) was added in case of the adamantylamine hydrochloride examples 7q-7s. The reaction mixture was then stirred for 24h. The precipitated quinazoline thiourea 7 was filtered off and recrystallized from ethyl alcohol. Spectral data are given below.

1-Butyl-3-(2-phenylquinazolin-4-yl) thiourea (7a).

(NH2R= butylamine); Yield: 0.21 g (29%); M.p. 165-166 °C; Calc. for C19H20N4S (336.45): 67.83% C, 5.99% H, 16.65% N, 9.53% S; Found: 67.64% C, 5.81% H, 16.48% N, 9.43% S; FTIR: 3427.6 (NH), 2952.8, 2928.0, 2869.2 (CH), 1618.2 (C=N); 1H-NMR: 12.16 (1H, s, NH), 8.79 (1H, s, NH), 8.24-7.48 (9H, m, ArH), 3.79-3.75 (2H, m, NHCH2), 1.83-1.76 (2H, m, NCH2CH2), 1.49-1.42 (2H, m, HNCH2CH2CH2), 0.94 (3H, t, CH2CH3) (JA,B= 7.31 Hz); 13C-NMR: 180.11 (C=S), 158.90 (Cq), 156.16 (Cq), 151.57 (Cq), 137.70 (Cq), 134.57 (CHAr), 131.18 (CHAr), 129.89 (CHAr), 128.93 (CHAr), 128.38 (CHAr), 127.81 (CHAr), 120.67 (CHAr), 112.70 (Cq), 46.55 (NCH2), 31.05 (NCH2CH2), 20.60 (HNCH2CH2CH2), 13.99 (CH3); MS, m/z (Ir/%): 337 (24), 336 (71), 304 (15), 303 (82), 264 (58), 247 (28), 222 (59), 221 (100), 206 (37), 205 (89), 130 (15), 118 (38), 104 (25), 102 (36), 77 (50), 72 (18), 41 (17).

1-Benzyl-3-(2-phenylquinazolin-4-yl) thiourea (7b).

(NH2R= benzylamine); Yield: 0.3 g (36%); M.p. 189-190 °C; Calc. for C22H18N4S (370.47): 71.33% C, 4.90% H, 15.12% N, 8.65% S; Found: 71.24% C, 4.88% H, 15.03% N, 8.59% S; FTIR: 3292.1 (NH), 3024.58 (CH), 1619.81 (C=N); 1H-NMR: 12.31 (1H, s, NHCH2), 8.88 (1H, s, NH), 8.03-7.18 (14H, m, ArH), 4.98 (2H, d, NHCH2) (JA,B= 4.66 Hz); 13C-NMR: 179.82 (C=S), 158.90 (Cq), 156.00 (Cq), 151.36 (Cq), 136.89 (Cq), 136.49 (Cq), 134.62 (CHAr), 130.94 (CHAr), 129.77 (CHAr), 129.37 (CHAr), 129.20 (CHAr), 128.85 (CHAr), 128.59 (CHAr), 128.15 (CHAr), 127.83 (CHAr), 120.59 (CHAr), 112.57 (Cq), 51.31 (NCH2); MS, m/z (Ir/%): 371 (12), 370 (28), 339 (9), 337 (48), 264 (22), 263 (41), 239 (11), 222 (64), 221 (100), 206 (27), 205 (94), 149 (32), 118 (38), 104 (25), 102 (34), 91 (100), 77 (53), 65 (45), 51 (25).

1-Allyl-3-(2-phenylquinazolin-4-yl) thiourea (7c).

(NH2R= allylamine); Yield: 0.18 g (25%); M.p. 189-190 °C; Calc. for C18H16N4S (320.41): 67.48% C, 5.03% H, 17.49% N, 10.01% S; found: 67.32% C, 4.98% H, 17.37% N, 9.83% S; FTIR: 3441.6 (NH), 3021.8 (CH), 1620.6 (C=N); 1H-NMR: 12.30 (1H, s, NH), 8.83 (1H, s, NH), 8.30-7.49 (9H, m, ArH), 6.19-6.06 (1H, m, CH=CH2), 5.47 (1H, d, CH=CH2) (JA,B= 17.2 Hz), 5.38 (1H, d, CH=CH2) (JA,B= 9.9 Hz), 4.49 (2H, m, HNCH2); 13C-NMR: 180.16 (C=S), 158.65 (Cq), 156.04 (Cq), 151.53 (Cq), 137.27 (Cq), 134.61 (CHAr), 132.73(1H, m, CH=CH2), 131.21 (CHAr), 129.85 (CHAr), 128.90 (CHAr), 128.42 (CHAr), 127.83 (CHAr), 120.63 (CHAr),118.98 (1H, m, CH=CH2), 112.59 (Cq), 49.16 (NCH2).

1-Isobutyl-3-(2-phenylquinazolin-4-yl) thiourea (7d).

(NH2R= isobutylamine); Yield: 0.14 g (19%); M.p. 150-151 °C; Calc.for C19H20N4S (336.45): 67.83% C, 5.99% H, 16.65% N, 9.53% S; found: 67.75% C, 5.92% H, 16.59% N, 9.52% S; FTIR: 3427.65 (NH), 2957.7, 2918.7 (CH), 1620.29 (C=N); 1H-NMR: 12.26 (1H, s, NH), 8.95 (1H, s, NH), 8.41-7.61 (9H, m, ArH), 3.78 (2H, t, NHCH2) (JA,B= 6.57 Hz), 2.32-2.25 (1H, m, CH(CH3)2), 1.18 (6H, d, CH(CH3)2) (JA,B= 6.57 Hz); 13C-NMR: 180.18 (C=S), 158.83 (Cq), 156.12 (Cq), 151.41 (Cq), 137.52 (Cq), 134.57 (CHAr), 131.18 (CHAr), 129.75 (CHAr), 128.83 (CHAr), 128.31 (CHAr), 127.80 (CHAr), 120.68 (CHAr), 112.60 (Cq), 54.38 (NHCH2), 28.16 (NCH2CH), 20.75 (CH3).

1-Cyclohexyl-3-(2-phenylquinazolin-4-yl) thiourea (7e).

(NH2R= cyclohexylamine); Yield: 0.25 g (30%); M.p. 154-155 °C; Calc.for C21H22N4S (362.49): 69.58% C, 6.12% H, 15.46% N, 8.84% S; Found: 69.41% C, 6.12% H, 15.38% N, 8.74% S; FTIR: 3441.7, 3425.8 (NH), 1619.3 (C=N); 1H-NMR: 12.08 (1H, b, NHCH), 8.75 (1H, s, NH), 8.32-7.54 (9H, m, ArH), 4.28-4.38 (1H, m, NHCH), 2.34-2.27 (2H, m, CH2), 1.91-1.71 (4H, m, 2CH2), 1.55- 1.38 (4H, m, 2CH2); 13C-NMR: 178.54 (C=S), 158.90 (Cq), 156.07 (Cq), 151.45 (Cq), 137.69 (Cq), 134.55 (CHAr), 131.15 (CHAr), 129.77 (CHAr), 128.92 (CHAr), 128.40 (CHAr), 127.80 (CHAr), 120.65 (CHAr), 112.66 (Cq), 55.49 (CH), 32.78 (CH2), 32.78 (CH2), 25.87 (CH2), 25.17 (CH2).

1-Phenyl-3-(2-phenylquinazolin-4-yl)thiourea (7f).

(NH2R= aniline); Yield: 0.35 g (43%); M.p. 165-166oC; Calc.for C21H16N4S (356.44): 70.76% C, 4.52% H, 15.72% N, 8.99% S; Found: 70.58% C, 4.52% H, 15.64% N, 8.83% S; FTIR: 3436.3, 3418.7 (NH), 1617.3 (C=N); 1H-NMR: 14.26 (1H, s, NHPh), 8.93 (1H, s, NH), 8.35-7.29 (14H, m, ArH); 13C-NMR: 178.62 (C=S), 158.57 (Cq), 155.96 (Cq), 151.64 (Cq), 144.85(Cq), 138.49 (Cq), 137.36 (Cq), 134.85 (CHAr), 131.31 (CHAr), 129.93 (CHAr), 129.24 (CHAr), 128.39 (CHAr), 128.03 (CHAr), 126.88 (CHAr), 124.13 (CHAr), 120.65 (CHAr), 112.62 (Cq); MS, m/z (Ir/%): 356 (6), 323 (7), 276 (9), 264 (12), 263 (51), 222 (13), 221 (100), 205 (95), 178 (8), 135 (49), 118 (17), 104 (7), 102 (20), 93 (21), 91 (6), 77 (57), 51 (25).

1-(4-Methylphenyl)-3-(2-phenylquinazolin-4-yl) thiourea (7g).

(NH2R= p-toluidine); Yield: 0.31 g (38%); M.p. 179-180oC; Calc. for C22H18N4S (370.47): 71.33% C, 4.90% H, 15.12% N, 8.65% S; Found: 71.21% C, 4.89% H, 15.11% N, 8.62% S; FTIR: 3422.5 (NH), 1619.9(C=N); 1H-NMR: 14.16 (1H, s, NHPh), 8.92 (1H, s, NH), 8.36-7.29 (13H, m, ArH), 2.40 (3H, s, CH3); 13C-NMR: 178.62 (C=S), 158.57 (Cq), 155.99 (Cq), 151.52 (Cq), 144.85 (Cq), 138.49 (Cq), 137.30 (Cq), 136.83 (Cq), 134.84 (CHAr), 131.32 (CHAr), 129.82 (CHAr), 129.09 (CHAr), 128.38 (CHAr), 128.03 (CHAr), 124.18 (CHAr), 120.67 (CHAr), 112.63 (Cq), 21.33 (CH3); MS, m/z (Ir/%): 337 (4), 264 (18), 263 (62), 222 (33), 221 (85), 206 (19), 205 (100), 149 (54), 148 (18), 118 (15), 107 (71), 106 (58), 91 (29), 77 (29).

1-(3-Methylphenyl)-3-(2-phenylquinazolin-4-yl) thiourea (7h).

(NH2R= m-toluidine); Yield: 0.36 g (43%); M.p. 157-158oC; Calc. for C22H18N4S (370.47): 71.33% C, 4.90% H, 15.12% N, 8.65% S; Found: 71.32% C, 4.90% H, 15.10% N, 8.65% S; FTIR: 3405.2 (NH), 1618.7 (C=N); 1H-NMR: 14.22 (1H, s, NHPh), 8.91 (1H, s, NH), 8.38-7.11 (13H, m, ArH), 2.41 (3H, s, CH3); 13C-NMR: 178.53 (C=S), 158.56 (Cq), 155.84 (Cq), 151.38 (Cq), 144.76(Cq), 138.49 (Cq), 137.30 (Cq), 136.83 (Cq), 134.86 (CHAr), 131.37 (CHAr), 129.87 (CHAr), 129.06 (CHAr), 128.46 (CHAr), 128.05 (CHAr), 127.66 (CHAr), 124.64 (CHAr), 121.07 (CHAr), 120.67 (CHAr), 112.63 (Cq), 21.69 (CH3).

1-(2-Methylphenyl)-3-(2-phenylquinazolin-4-yl) thiourea (7I).

(NH2R= o-toluidine); Yield: 0.42 g (51%); M.p. 157-158oC; Calc. for C22H18N4S (370.47): 71.33% C, 4.90% H, 15.12% N, 8.65% S; Found: 71.03% C, 4.64% H, 14.92% N, 8.41% S; FTIR: 3325.2 (NH), 1623.59 (C=N); 1H-NMR: 14.22 (1H, s, NHPh), 8.91 (1H, s, NH), 8.38-7.11 (13H, m, ArH), 2.41 (3H, s, CH3); 13C-NMR: 178.53 (C=S), 158.56 (Cq), 155.84 (Cq), 151.38 (Cq), 144.76(Cq), 138.49 (Cq), 137.30 (Cq), 136.83 (Cq), 134.86 (CHAr), 131.37 (CHAr), 129.87 (CHAr), 129.06 (CHAr), 128.46 (CHAr), 128.05 (CHAr), 127.66 (CHAr), 124.64 (CHAr), 121.07 (CHAr), 120.67 (CHAr), 112.63 (Cq), 21.69 (CH3).

1-(4-Methoxyphenyl)-3-(2-phenylquinazolin-4-yl) thiourea (7j).

(NH2R= p-anisidine); Yield: 0.34 g (40%); M.p. 168-169oC; Calc. for C22H18N4OS (386.47): 68.37% C, 4.69% H, 14.50% N, 8.30% S; Found: 68.24% C, 4.57% H, 14.49% N, 8.23% S; FTIR: 3428.2 (NH), 2934.9 (CH), 1616.8 (C=N); 1H-NMR: 14.09 (1H, s, NHPh), 8.91 (1H, s, NH), 8.35- 6.98 (13H, m, ArH), 3.86 (3H, s, OCH3); 13C-NMR: 178.78 (C=S), 158.39 (Cq), 155.98 (Cq), 152.49 (Cq), 151.55 (Cq), 141.78 (Cq), 137.32 (Cq), 134.86 (CHAr), 131.4(Cq), 131.32 (CHAr), 129.87 (CHAr), 129.09 (CHAr), 128.35 (CHAr), 128.03 (CHAr), 125.78 (CHAr), 120.67 (CHAr), 114.48 (CHAr), 113.45 (Cq), 112.63 (Cq), 55.75 (OCH3).

1-(4-nitrophenyl)-3-(2-phenylquinazolin-4-yl) thiourea (7k).

(NH2R= p-nitroaniline); Yield: 0.48 g (53%); M.p. 165-166oC; Calc. for C21H15N5O2S (401.44): 62.83% C, 3.77% H, 17.45% N, 7.99% S; Found: 62.66% C, 3.58% H, 17.24% N, 7.84% S; FTIR: 3333.0 (NH), 1615.7 (C=N); 1H-NMR (CF3COOD): 8.87-7.94 (13H, m, ArH); 13C-NMR: 179.93 (C=S), 161.56 (Cq), 160.34 (Cq), 147.97 (Cq), 145.71 (Cq), 142.34 (Cq), 142.01 (CHAr), 138.41 (CHAr), 133.84 (CHAr), 132.67 (CHAr), 131.27 (Cq), 130.90 (CHAr), 127.36 (CHAr), 126.21 (CHAr), 125.73 (CHAr), 122.65 (CHAr), 114.20 (Cq).

1-(3-nitrophenyl)-3-(2-phenylquinazolin-4-yl)thiourea (7l).

(NH2R= m-nitroaniline); Yield: 0.39 g (41%); M.p. 174-175oC; Calc. for C21H15N5O2S (401.44): 62.83% C, 3.77% H, 17.45% N, 7.99% S; Found: 62.74% C, 3.64% H, 17.32% N, 7.87% S; FTIR: 3315.6 (NH), 1620.8 (C=N); 1H-NMR (CF3COOD): 8.87-7.75 (13H, m, ArH); 13C-NMR: 180.60 (C=S), 161.55 (Cq), 160.60 (Cq), 150.54 (Cq), 142.41 (Cq), 142.34 (Cq), 142.07 (CHAr), 140.60 (Cq), 138.47 (CHAr), 133.90 (CHAr), 132.91 (CHAr), 132.82 (CHAr), 132.76 (CHAr), 131.27 (Cq), 130.97 (CHAr), 125.91 (CHAr), 124.93 (CHAr), 122.71 (CHAr), 121.58(CHAr), 114.30 (Cq).

1-(4-Chlorophenyl)-3-(2-phenylquinazolin-4-yl) thiourea (7m).

(NH2R= p-chloroaniline); yield: 048 g (55%); M.p. 187-188oC; Calc.for C21H15ClN4S (390.89): 64.53% C, 3.87% H, 9.07% Cl, 14.33% N, 8.20% S; found: 64.34% C, 3.69% H, 9.01% Cl, 14.21% N, 8.16% S;; FTIR: 3430.3, 3339.3 (NH), 1620.40 (C=N); 1H-NMR (CF3COOD): 8.74- 7.48 (13H, m, ArH); 13C-NMR: 180.40 (C=S), 161.44 (Cq), 160.73 (Cq), 142.28 (Cq), 141.98 (CHAr), 138.41 (CHAr), 137.24 (Cq), 136.92 (Cq), 133.80 (CHAr), 132.63 (CHAr), 131.07 (Cq), 130.88(CHAr), 127.84 (CHAr), 125.86 (CHAr), 122.58 (CHAr), 114.27 (Cq).

1-(1-Naphthyl)-3-(2-phenylquinazolin-4-yl) thiourea (7n).

(NH2R= 1-naphthylamine); Yield: 0.41 g (45%); M.p. 168-169oC; Calc. for C25H18N4S (406.50): 73.87% C, 4.46% H, 13.78% N, 7.89% S; Found: 73.83% C, 4.46% H, 13.77% N, 7.84% S; FTIR: 3250.1 (NH), 3055.0, 2943.4 (CH), 1619.4 (C=N); 1H-NMR: 14.27 (1H, s, NHPh), 9.16 (1H, s, NH), 8.28-7.29 (19H, m, ArH); 13C-NMR: 180.79 (C=S), 164.76 (Cq), 158.76 (Cq), 156.24 (Cq), 151.73 (Cq), 141.70 (Cq), 137.02 (Cq), 134.90 (CHAr), 134.61(Cq), 131.19 (CHAr), 129.97 (CHAr), 129.02 (CHAr), 128.87 (CHAr), 128.55 (CHAr), 128.24 (CHAr), 128.05 (CHAr), 127.16 (CHAr), 126.64 (CHAr), 125.65 (CHAr), 124.71 (CHAr), 122.41 (CHAr), 120.19 (CHAr), 112.74 (Cq).

1-(2-Naphthyl)-3-(2-phenylquinazolin-4-yl) thiourea (7o).

(NH2R= 2-naphthylamine); Yield: 0.55 g (66%); M.p. 179-180oC; Calc. for C25H18N4S (406.50): 73.87% C, 4.46% H, 13.78% N, 7.89% S; Found: 73.74% C, 4.38% H, 13.61% N, 7.80% S; FTIR, ν ˜ /cm-1: 3429.1, 3374.2 (NH), 3057.6 (CH), 1618.4 (C=N); 1H-NMR (CF3COOD): 8.72-7.63 (19H, m, ArH); 13C-NMR (CF3COOD): 179.30 (C=S), 161.29 (Cq), 160.30 (Cq), 142.09 (Cq), 141.83 (CHAr), 138.41 (CHAr) 136.08 (Cq), 135.59 (Cq), 135.02 (Cq) , 133.68 (CHAr), 132.59 (CHAr), 131.86 (CHAr), 131.05 (Cq), 130.99 (CHAr), 130.67 (CHAr), 129.89 (CHAr), 129.63 (CHAr), 126.46 (CHAr), 125.68 (CHAr), 124.82 (CHAr), 122.41 (CHAr), 114.07 (Cq).

1-(2-phenylquinazolin-4-yl)-3-(2-pyridyl) thiourea (7p).

(NH2R= 2-aminopyridine); Yield 0.33 g (41%); M.p. 207-208oC; Calc.for C20H15N5S (357.43): 67.21% C, 4.23% H, 19.59% N, 8.97% S; Found: 67.04% C, 3.97% H, 19.22% N, 8.83% S; FTIR, ν ˜ /cm-1: 3348.7 (NH), 3059.4 (CH), 1621.7 (C=N); 1H-NMR (DMSO-d6): 8.71-7.27 (13H, m, ArH); 13C-NMR: 179.57 (C=S), 161.05 (Cq), 155.96 (Cq), 151.64 (Cq), 144.85(Cq), 138.49 (Cq), 135.90 (Cq), 137.73 (CHAr), 134.08 (CHAr), 130.36 (CHAr), 127.98 (CHAr), 127.69 (CHAr), 126.76 (CHAr), 123.26 (CHAr), 119.93 (CHAr), 114.25 (Cq); MS, m/z (Ir/%): 357 (14), 324 (7), 264 (30), 263 (49), 222 (21), 221 (100), 205 (82), 178 (8), 136 (55), 118 (28), 104 (13), 102 (29), 94 (27), 78 (56), 77 (38), 51 (27).

1-(1-Adamantyl)-3-(2-phenylquinazolin-4-yl) thiourea (7q).

(NH2R= 1-adamantanamine hydrochloride); Yield: 0.29g (31%); M.p. 202-203 °C; Calc.for C25H26N4S (414.50): 72.43% C, 6.32% H, 13.52% N, 7.73% S; Found: 72.31% C, 6.27% H, 13.41% N, 7.54% S; FTIR, ν ˜ /cm-1: 3445.3 (NH), 2909.9 (CH), 2854.9 (CH), 1622.5 (C=N); 1H- NMR: 11.77 (1H, s, NH), 8.53 (1H, s, NH), 8.27-7.43 (9H, m, ArH), 2.53-2.41 (6H, m, 3CH2), 2.26-2.09 (6H, m, 3CH2), 1.84-1.68 (3H, m, 3CH); 13C-NMR: 177.48 (C=S), 156.07 (Cq), 149.83 (Cq), 137.91 (Cq), 134.63 (CHAr), 131.02 (CHAr), 129.81 (CHAr), 128.70 (CHAr), 127.68 (CHAr), 120.67 (CHAr), 112.75 (Cq), 55.91 (NHCAd), 41.10 (CH2), 36.67 (CH2), 29.97 (CH); MS, m/z (Ir/%): 414.2 (4), 380.3 (2), 264 (7), 263 (21), 222 (32), 221 (75), 205 (65), 193 (15), 151 (16), 135 (100), 118 (17), 94 (45), 77 (29).

1-(3-Homoadamantyl)-3-(2-phenylquinazolin-4-yl) thiourea (7r).

(NH2R= 3-homoadamantanamine hydrochloride); Yield: 0.3 g (33%); M.p. 217-218 °C; Calc.for C26H28N4S (428.59): 72.86% C, 6.58% H, 13.07% N, 7.48% S; Found: 72.43% C, 6.48% H, 13.01% N, 7.24% S; FTIR, ν ˜ /cm-1: 3436.2 (NH), 2909.9 (CH), 2849.9 (CH), 1620.4 (C=N); 1H- NMR: 11.98 (1H, s, NH), 8.64 (1H, s, NH), 8.36-7.54 (9H, m, ArH), 2.61-1.53 (15H, m, Ad); 13C- NMR: 176.92 (C=S), 159.19 (Cq), 156.03 (Cq), 151.30 (Cq), 137.86 (Cq), 134.45 (CHAr), 131.03 (CHAr), 129.71 (CHAr), 128.71 (CHAr), 127.72 (CHAr), 120.73 (CHAr), 112.65 (Cq), 60.98 (CH2), 43.15 (CH2), 37.84 (CH2), 35.56 (CH2), 31.22 (CH), 31.18 (CH2), 27.82 (CH); MS, m/z (Ir/%): 428.2 (3), 264 (12), 263 (34), 222 (48), 221 (86), 205 (83), 165 (12), 149 (100), 118 (13), 94 (23), 77 (29).
1-(1-Adamantylmethyl)-3-(2-phenylquinazolin-4-yl) thiourea (7s).
[NH2R= 1-(1-adamantylmethylamine hydrochloride)]; Yield: 0.33 g (34%); M.p. 197-198 °C; Calc. for C26H28N4S (428.53): 72.86% C, 6.59% H, 13.07% N, 7.48% S; Found: 72.86% C, 6.57% H, 13.04% N, 7.39% S; FTIR, ν ˜ /cm-1: 3450.3 (NH), 2909.9 (CH), 2849.5 (CH), 1620.0 (C=N); 1H- NMR: 12.04 (1H, s, NH), 8.90 (1H, s, NH), 8.31-7.51 (9H, m, ArH), 3.69 (2H, d, NHCH2) (JA,B= 6.14 Hz), 1.96-1.56 (15H, m, Ad); 13C-NMR: 180.75 (C=S), 156.08 (Cq), 151.43 (Cq), 138.70 (Cq), 137.76 (Cq), 134.63 (CHAr), 131.04 (CHAr), 129.78 (CHAr), 128.78 (CHAr), 127.85 (CHAr), 120.77 (CHAr), 112.67 (Cq), 58.74 (NHCH2), 40.85 (CH2 Ad), 36.95 (CH2 Ad), 34.82 (CqAd), 28.38 (CH); MS, m/z (Ir/%): 428 (9), 395 (5), 264 (15), 263 (24), 222 (41), 221 (49), 205 (64), 165 (11), 149 (12), 135 (100), 118 (9), 93 (19), 77 (23).

Acknowledgments

This work was supported by a grant from the Ministry of Education of the Czech Republic (Grant No. CEZ: J07/98:143100011) and from the Grant Agency of the Czech Republic (Grant No. 203/01/1333). We would like to thank the Analytical Department of Lachema Co., Brno, Czech Republic for elemental analysis. The authors wish to acknowledge the Academic Supercomputer Center in Brno for providing access to computer facilities.

References and Notes

  1. Fathalla, W.; Čajan, M.; Pazdera, P. Molecules 2001, 6, 557–573. [CrossRef]
  2. Fathalla, W.; Čajan, M.; Pazdera, P. Molecules 2000, 5, 1210–1223. [CrossRef]
  3. Fathalla, W.; Marek, J.; Pazdera, P. Molecules 2001, 6, 574–587. [CrossRef]
  4. Bodajla, M.; Stankovský, Š.; Špirková, K. Collect. Czech. Chem. Commun. 1995, 60, 1415.
  5. Bodajla, M.; Stankovský, Š.; Špirková, K.; Jantová, S. Collect. Czech. Chem. Commun. 1996, 61, 1681. [CrossRef]
  6. Bodajla, M.; Stankovský, Š.; Jantová, S.; Hudecová, D.; Špirková, K. Chem. Papers 1996, 50, 28.
  7. Pazdera, P.; Nováček, E.; Kalviňš, I.; Trapencieris, P.; Pugovics, O. Chem. Papers 1991, 45, 527.
  8. Pazdera, P.; Ondráček, D.; Nováček, E. Chem. Papers 1989, 43(6), 771.
  9. The complete computational analysis of all the predicted structures and the X-ray analysis data for compounds 7a and 7b are available from the authors.
  10. Sheldrick, G. M. Acta Crystallogr, Sect. A.: Fundam. Crystallogr. 1990, 46, 467.
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  • Sample Availability: Available from the authors.

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MDPI and ACS Style

Fathalla, W.; Čajan, M.; Marek, J.; Pazdera, P. One-Pot Quinazolin-4-yl-thiourea Synthesis via N-(2-Cyanophenyl) benzimidoyl isothiocyanate. Molecules 2001, 6, 588-602. https://doi.org/10.3390/60700588

AMA Style

Fathalla W, Čajan M, Marek J, Pazdera P. One-Pot Quinazolin-4-yl-thiourea Synthesis via N-(2-Cyanophenyl) benzimidoyl isothiocyanate. Molecules. 2001; 6(7):588-602. https://doi.org/10.3390/60700588

Chicago/Turabian Style

Fathalla, W., M. Čajan, J. Marek, and P. Pazdera. 2001. "One-Pot Quinazolin-4-yl-thiourea Synthesis via N-(2-Cyanophenyl) benzimidoyl isothiocyanate" Molecules 6, no. 7: 588-602. https://doi.org/10.3390/60700588

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