 Research Journal of Chemical Sciences ______________________________________________ ISSN 2231-606X Vol. 4(7), 93-98, July (2014) Res. J. Chem. Sci. International Science Congress Association        
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Solvent free green Synthesis of 5-arylidine Barbituric acid Derivatives Catalyzed by Copper oxide NanoparticlesDighore N.R., Anandgaonker P.L., Gaikwad S.T. and Rajbhoj A.S.* Department of Chemistry, Dr. Babasaheb Ambedkar Marathwada University, Aurangabad-431004, MS, INDIA Available online at: 
www.isca.in, www.isca.me
Received 29th June 2014, revised 10th July 2014, accepted 17th July 2014Abstract Copper oxide nanoparticles as an efficient catalyst was used for the synthesis of 5-arylidine barbituric acid derivatives by condensation reaction of barbituric acid and various aromatic aldehydes at room temperature with high speed stirring. The present protocol especially favoured because it offers advantages of high yields, short reaction times, simplicity and easy workup. Moreover the catalyst is inexpensive, stable, can be recycled and reused for three cycles without loss of its activity. Keywords: Electrochemical method, CuO nanoparticles, heterogeneous catalyst, 5-arylidine barbituric acid derivatives, room temperature synthesis. Introduction Barbituric acid is a strong acid in aqueous medium with an active methylene group and can be involved in knoevenagel type condensation reactionThe barbiturates are associated with a number of biological activities such as antibacterial, hypotensive, sedative and local anesthetic drugs2-3 to the more recent report indicating that they have applications in anti-tumor, anti-cancer, analeptics, anti-AIDS agents and anti-osteoporosis treatments, used as oxidants for mild oxidation of thiols and alcohols10. Owing to the wide range of biological and medicinal activities the synthesis of 5-arylidine barbituric acid compounds by the use of barbituric acid and 2-thio barbituric acid as starting compound have become an important target in recent years. Numerous synthetic method have been reported for the synthesis of synthesis of 5-arylidine barbituric acid derivatives by solvent free grinding, using NHSO11, infra red promoted12, microwave irradiation13, ionic liquid mediated condensation14, and uses variety of catalysts such as ZnCl15, CdI16, Ni-SiO17, KF–Al18, natural phosphate [(NP)/KF or NP/NaNO19 and synthetic phosphate (NaCaP20, NiP21, dry condensation with acidic clay catalysts22, Ni nanoparticles23 and CoFe nanoparticles24 etc. However these methods are plagued by limitation of longer reaction time, effluent pollution, bis-addition and self condensation, lower yield. Owning to the importance of barbituratic acid derivatives especially 5-arylidine barbiturates there is need to develop efficient method for the Knovengel Condensation at mild conditions. Solvent free organic reaction have drawn great interest, particularly from the viewpont of green chemistry as organic solvent are toxic and flammable. Solid state reactions are simple to handle, reduce pollution and comparatively cheaper to operate. Heterogeneous catalysts offer several intrinsic advantages over their homogeneous counterparts such as easy removal of catalyst, operational simplicity and reusability. The use of metal nanoparticles in the field of catalysis is of great interest, since they have a large surface-to-volume ratio compared to bulk materials. Recently, there has been growing interest in using cupper nanoparticles in organic synthesis because of their potent catalytic activity, high stability and non toxic. Material and MethodsThe AR grade tetra propyl ammonium bromide (TPAB), tetrahydrofuran (THF) and acetonitrile (ACN) were purchased from Aldrich and S.D. Fine chemicals and used as such. The sacrificial anode in the form of copper sheet and platinum sheet as inert cathode having thickness 0.25 mm and purity 99.9% was purchased from Alfa Asaer. The specially designed electrolysis cell with a volume capacity of 30 ml was used. The prepared copper oxide nanoparticles were characterized by UV-Visible, XRD, SEM-EDS techniques. The UV-Visible studies were recorded [JASCO 503] spectrophotometer using a quartz cuvette with ACN / THF (4:1) as reference solvent. The X-ray powder diffraction patterns of the copper oxidenanoparticles were recorded on Bruker 8D advance X-ray diffractometer using CuK radiation of wavelength = 1.54056 Å. To study the morphology and elemental composition in copper oxide nanoparticles were examined using energy dispersive spectrophotometer (EDS), the SEM analysis were carried out with JEOL; JSM- 6330 LA operated at 20.0kV and 1.0000nA. 
H NMR and 13C NMR spectra were recorded on a Bruker AvIII 
HD300 MHz FTNMR spectrometer with CDCl as a solvent and the chemical shift values recorded as  (ppm units). Mass 
spectra were recorded on an Agilent 6520 Q-Tof mass 
spectrometer for ESI Scan. 
Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 4(7), 93-98, July (2014) Res. J. Chem. Sci.   International Science Congress Association 
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Synthesis of CuO Nanoparticles: Reetz proposed an electrochemical reduction method25 including both oxidation of bulk metal and reduction of metal ions for size selective preparation of tetra alkyl ammonium salt stabilized metal nanoparticles. In the initial experiment we have used a copper metal sheet (1x1 cm) as anode and a platinum sheet (1x1 cm) as the cathode. These two electrodes placed parallel to one another and were separated by 1.0cm in 0.01 M solution of TPAB prepared in ACN/THF (4:1) served as the supporting electrolyte. The electrolysis process was then carried out by applying current 10 mA for 2.0 hrs. The colloidal solution thus obtained was kept in air tight glass bottle to settle for a day. The agglomerated solid sample was separated from the solution by decantation and washed three to four times with THF. The washed samples were then dried under vacuum condition in desiccator and stored in air tight container for characterization. Procedure for the Synthesis of 5-Arylidene Barbituric Acids: A mixture of aromatic aldehyde(1mmol), barbituric acid (1mmol) (solid aromatic aldehyde wetted with ethanol) and CuO nanoparticles (100mg) (scheme 1) was stirred with high speed at room temperature till the completion of reaction monitored by TLC (ethyl acetate and n-hexane 7:3). After completion of reaction solid product obtained was dissolved in 10ml ethyl acetate and concentrated on rotavapor. Finally pure product was obtained by recrystalization and authentic samples were characterized by FTIR, HNMR, C13 NMR and mass spectra. Procedure for recovery of catalyst: The reaction mixture was stirred until complete dissolution of product in ethyl acetate. The resulting solution was centrifuged for 5 min. The ethyl acetate solution was collected by simple decantation. The catalyst was washed with ethanol for 2-3 times. Then dried catalyst reused in same reaction for over three cycles.  Spectral data: 5(4-Cl-Benzylidene)- Barbituric acid(3b): [IR (KBr) max/cm-1]: 3404, 3214, 2970, 1755, 1703, 1570 cm-1; H NMR (DMSO)  ppm:7.53(d, 2H, Ar-H), 8.08(2d, 2H, Ar-H), 8.25(s, 1H, HC=C), 11.25(s, H, NH), 11.40(S, 1H, NH); 13C NMR(CDCl)  ppm; 117.46, 127.76, 128.29, 133.25, 133.50, 148.70, 150.16, 165.10; EI-MS: m/z (%):250(M). 5(2-Cl-Benzylidene)- Barbituric acid(3c): [IR (KBr) max/cm]: 3460, 3120, 2981, 1754, 1569, 1454, 1079, 910, 782; H NMR (CDCl)  ppm: 7.36 (t, 1H Ar-H), 7.47 (t, 1H, Ar-H), 7.53 (d, 1H, Ar-H), 7.73 (d, 1H, Ar-H), 8.29 (s, 1H, HC=C), 11.25(s,1H, NH), 11.47(s, 1H,NH); 13C NMR(CDCl,ppm)= 121.76, 126.29, 128.29, 131.88, 132.25, 133.15, 146.70, 150.16, 160.85, 162.60; EI-MS: m/z (%):250(M). 5(4-OH-Benzylidene)- Barbituric acid(3i): [IR (KBr) max/cm]: 3420, 3214, 2970, 1755, 1703, 1570 cm-1; H NMR (DMSO)  ppm:6.86(d, 2H, Ar-H), 8.32(2d, 2H, Ar-H), 8.24(s, 1H, HC=C), 10.68(S, 1H, OH), 11.13(s, H, NH), 11.25(S, 1H, NH); 13C NMR(CDCl)  ppm; 115.60, 118.76, 128.70, 148.80, 150.20, 157.65, 165.10; EI-MS: m/z (%):232(M). Results and Discussion  In continuation of our previous work, we have developed cupper nanoparticles as catalyst for development of new synthetic methodologies. Herein, we would like to report a mild and high yielding solvent free method for the synthesis of5-arylidene barbiturates by a condensation reaction between aromatic aldehyde 1(a-m) and barbituric acid catalyzed efficiently by CuO nanoparticles. As electrochemical reaction proceeds, the colour of reaction mixture changes from colorless to brownish black indicating formation of CuO nanoparticles. About 4 ml of colloidal reaction mixture was withdrawn after 2 h to record UV–Visible spectrum. CuO capped with TPAB at current density of 10 mA has got broad peak at 640 nm indicating the formation of CuO nanoparticles figure-1.  XRD pattern of the CuO nanoparticles is shown in figure-2. All reflection peaks can be readily indexed to monoclinic phase of CuO nanoparticles. The particle size of solid materials can be estimated from X-ray line broadening and full width at half maximum (FWHM) values using the Debye-Scherrer’s equation. Peaks corresponding to the planes (-111), (111), (012) (020) (120) (220) and (121) with lattice parameter a = 4.653, b = 3.410, c = 99.480 indicate the monoclinic phase structure of CuO nanoparticles. All peaks are in good agreement with the JCPDS card no. 74-1021. The average crystallite size of CuO has been found to be 25-30 nm.  
H
O
R
HNNH
O
O
O
NH
O
O
O
R
3a-mCuO NPsSolvent FreeHigh speed stirredat room temp.1a-mScheme 1CuO nanoparticles catalyzed knoevenagel condensation of aldehydes and barbituric acid 
Research Journal of Chemical Sciences ____
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Vol. 4(7), 93-98, July (2014)
 
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Figure-1 UV-
Visible spectrum of CuO NPs
Figure-2 XRD pattern of 
Copper oxide Nps
 
The morphology of CuO nanoparticles catalysts is shown in 
figure-
3a. The SEM micrograph of CuO nanoparticles showed 
agglomeration of particles and was irregular in shape. This was 
probably due to the partial solubility of t
he surfactant in the 
solvent under the given experimental conditions. The 
quantitative and qualitative analysis was done by EDS spectra 
and the elemental composition of CuO nanoparticles are shown 
in figure-
3b. The elemental distribution of Cu 84.02 mass %
(55.67 At %), C 7.64 mass % 
(26.80 At %), O 6.24mass % 
(16.43 At %) and Br 2.10 mass % (1.11 At %).
 
TEM was used to further examine the particle size, crystallinity 
and morphology of the sample. The sample prepare
analysis was obtained by evapora
tion of very dilute alcoholic 
suspensions onto carbon-
coated copper grids. A TEM image 
(figure-
4a) of the typical product showed that CuO 
nanoparticles were dispersed and dense agglomeration was 
observed. The magnified image showed these CuO 
nanoparticles 
were spherical with size in the range of 5
The corresponding particle size distribution of CuO 
nanoparticles is in agreement with the results calculated from 
the XRD analysis. 
The SAED image of shows high crystallinity 
of the CuO NPs. The histogram in figure-
4b showed that the 
average mean size and 
standard deviation of copper oxide NPs 
capped with TPAB is found to be 22.39 ± 5.86 nm, which 
represent the aggregated copper nano-
crystal size. 
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Association
 
 
Visible spectrum of CuO NPs
  
Copper oxide Nps
 
The morphology of CuO nanoparticles catalysts is shown in 
3a. The SEM micrograph of CuO nanoparticles showed 
agglomeration of particles and was irregular in shape. This was 
he surfactant in the 
solvent under the given experimental conditions. The 
quantitative and qualitative analysis was done by EDS spectra 
and the elemental composition of CuO nanoparticles are shown 
3b. The elemental distribution of Cu 84.02 mass %
 
(26.80 At %), O 6.24mass % 
(16.43 At %) and Br 2.10 mass % (1.11 At %).
 
TEM was used to further examine the particle size, crystallinity 
and morphology of the sample. The sample prepare
 for TEM 
tion of very dilute alcoholic 
coated copper grids. A TEM image 
4a) of the typical product showed that CuO 
nanoparticles were dispersed and dense agglomeration was 
observed. The magnified image showed these CuO 
were spherical with size in the range of 5
–30 nm. 
The corresponding particle size distribution of CuO 
nanoparticles is in agreement with the results calculated from 
The SAED image of shows high crystallinity 
4b showed that the 
standard deviation of copper oxide NPs 
capped with TPAB is found to be 22.39 ± 5.86 nm, which 
crystal size. 
Figure
-
Copper oxide Nps 
a) SEM image 
synthesized at
10 mA current density.
Figure
-
Copper oxide Nps at
10 mA current density a) TEM image 
inset with SAED pattern 
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3 
a) SEM image 
and b) EDS spectra 
10 mA current density.
   
-
4 
10 mA current density a) TEM image 
inset with SAED pattern 
and b) histogram 
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The catalytic activity of the synthesized CuO nanoparticles was investigated in the synthesis of arylidene barbituric acid derivatives at room temperature. To study the efficiency of the CuO nanocatalyst, 4-chlorobenzaldehyde (1b) and barbituric acid (2) were used as the model substrate. We also carried out the reaction without any catalyst, but the product isolated gave poor yield (25%). In optimizing the reaction conditions, the amount of catalyst was the major factor. The model reaction was studied using 25, 50, 75, 100 and 125 mg of a reaction of 4-chlorobenzaldehyde (1b). The results revealed that best yield was obtained by using 100mg catalyst. With increase in the catalyst concentration, the yield of the desired product was found to be constant. Therefore, the catalyst plays a crucial role in the success of the reaction in term of yields of the product. The results obtained are summarized in table-2. It is evident that the aromatic aldehyde carrying electron-donating or electron-withdrawing groups as well as heterocyclic system such as Furan-2-carboxyaldehyde reacted smoothly to produce high yields of products. The results with different aromatic aldehydes are summarized in table-1. In this study, the catalyst was recovered and reused in another run. The catalyst was recovered by simple work-up using centrifugation method, washed with ethanol and reused for three successive reaction corresponding yields for each cycle were mentioned in table-3. To compare the merits of our work to the other reported procedure; the results of the synthesis of arylidene barbituric acid derivatives in the presence of different reported catalysts with respect to time and yield of the product are listed in table-4. These results show that our catalyst CuO nanoparticles are more stable in air, nontoxic, give good yield in short time than other catalysts and there is no use of any hazardous solvent. Table-1 Synthesis of 5-arylidine barbituric acid derivatives catalyzed by CuO Nanoparticles Sr. No. Reactant Products Time (min) Yield (%) Melting point (ºC) 
Found Reported 
1 C 3a 15 97 264 - 266 263-265  24  
2 4-ClC 3b 12 98 298 - 299 298  24
3 2-ClC 3c 13 95 250-252 252-254  24
4 4-NO 3d 09 94 268-270 272-274  11
5 3-NO 3e 07 95 230-231 231-233  11
6 4-CH 3f 15 96 290-291 297-298  11
7 2,4-Cl 3g 13 94 268-270 269-271  11
8 4-OMeC 3h 10 93 296-298 298-300  24
9 4-OHC 3i 15 94 &#x0000;300 &#x0000;320  24
10 2-furfural 3j 20 95 262-263 264  23
11 4-FC 3k 12 95 &#x0000;300 309-10  12
12 4-BrC 3l 15 92 288-290 292-293  12
13 CCH=CH 3m 18 93 267-268 270  13
Reaction condition: aldehyde (2mmol), barbituric acid (2mmol), and 100mg of CuO nanoparticles solvent free stirred at room temp. Table-2 Screening of catalyst (CuO NPs) concentration for the synthesis of 3b Entry Catalyst amount(mg) Time(min) Yield(%)
a
 
1 25 60 38 
2 50 40 82 
3 75 25 90 
4 100 12 98 
5 125 12 98 
isolated yield Table-3 Studies on reusability of CuO nanoparticles in the preparation of 3b No of Cycles Fresh 1 2 3 
Yield(%) 98 94 91 85 
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Table-4 Comparisation result of CuO nanoparticles with other catalysts reported in the literature. Sr. No. Catalyst Reaction condition Yield (%)
 
Literature 
1 NH
2
SO
3
H Grinding/10 min  47 11 
2 KSF clay  MW, 560 W/7 min 70 12 
3 PVPNi Nanoparticles Ethyleneglycol, 50
o
C/10–15 min 91 23 
4 CuO nanoparticles Solvent free/ R.T./7 min  95 This work 
Thus, we report fast, clean and highly competent methodology for the Knoevenagel condensation of aromatic aldehydes with barbituric acids catalyzed by CuO nanoparticles to give 5-arylidene barbituric acids as the desired products in short time span and in quantitative yields by a simple high speed stirring at room temperature. The reaction time, yield and reusability of catalysts make the present protocol 
a useful and important addition to the present methodologies for the synthesis of 
5-arylidine barbituric acid derivatives. ConclusionWe have 
demonstrated mild, easy and green method
 for the synthesis of 5-arylidine barbituric acid derivatives using recyclable CuONps as heterogeneous catalysts at room temperature under solvent free condition.
 
Short reaction times, appropriate yields and clean reactions make this procedure an attractive alternative to the existing methods. Furthermore, this method is of interest in the perspective of environmentally greener and safer method. Acknowledgment TheDepartment of Chemistry acknowledges the financial assistance by UGC-SAP-DRS scheme-1. We acknowledge the characterization facility by SEM and EDS from STIC Cochin. One of the author (ASR) is thankful for financial assistance from Major Research project [F. No. 832/2010(SR)], University Grants Commission, New Delhi.References1.Tietze L.F. and Beifuss U., Comprehesive organic synthesis, by Trost B. M., Flaming I. and Heathcock C. H.,Pergoman Press Oxford,, 341-394 (1919) 2. Borjarski J.T., Mokros J.L., Barton H.J. and Paluchowska 
M. H., Recent progress in barbituric acid chemistry, Adv. Heterocyc. Chem,38, 229-297 (1985) 
3.Cheng X., Tanaka K. and Yoneda F., Simple New Method 
for the Synthesis of 5-Deaza-10-oxaflavin, a Potential 
Organic Oxidant, Chem. Pharm. Bull., 38, 307-311 (1990)
4.Gulliya K. S., Uses for barbituric acid analogs
,
US Patent, 5869494A, (1999) 
5.Gulliya K. S.,
 Anti-cancer uses for barbituric acid analogs
US Patent, 5674870, (1997) 6.Naguib F.N.M., Levesque D.L., Wang E.C., Panzica R.P. 
and Kouni El. M.H., 5-Benzylbarbituric acid derivatives, 
potent and specific inhibitors of uridine phosphorylase, Biochem. Pharmacol, 46, 1273-1283 (1993) 7.Grams F., Brandstetter H. and D’Alo S., Pyrimidine-2,4,6-Triones: A New Effective and Selective Class of Matrix Metalloproteinase Inhibitors, Biol. Chem., 382,1277-1285 2001) 8.Sakai K. and Satoh Y., Barbituric acid derivative and preventive and therapeutic agent for bone and cartilage containing the same, International Patent, W09950252A3, 2000) 
9.Tanaka K., Chen X., Kimura T. and Yoneda F., Oxidation 
of thiol by 5-arylidene 1,3-dimethylbarbituric acid and its 
application to synthesis of unsymmetrical disulfideTetrahedron Lett., 28, 4173-4176 (1987)10.Tanaka K., Chen X., Kimura T. and Yoneda F., Mild oxidation of allylic and benzylic alcohols with 5-arylidene barbituric acid derivatives as a model of redox coenzymes, Chem. Pharm. Bull., 34, 3945-3948 (1986) 11.Li J. T., Dai H. G., Liu D. and Li T. S., Efficient method for synthesis of the derivatives of 5 arylidene barbituric acid catalyzed by aminosulfonic acid with grinding, Synth. Commun., 36, 789-794 (2006) 12.Alarreca G., Sanabria R., Miranda R., Arroyo G., Tamariz J. and Delgado F, Preparation of Benzylidene Barbituric Acids Promoted by Infrared Irradiation in Absence of Solvent Synth. Commun., 30, 1295-1301 (2000) 13.Dewan S. and Singh R., One Pot Synthesis of Barbiturates on Reaction of Barbituric Acid with Aldehydes under Microwave Irradiation Using a Variety of Catalysts, Synth. Commun., 33, 3081-3084 (2003) 14.Wang C., Ma J., Zhou X., Zang X., Wang Z. Gao Y. and Cui P., 1ButylMethylimmidazolium Tetrafluoroborate –Promoted Green Synthesis of 5Arylidene Barbituric Acids and Thiobarbituric Acid Derivatives, Synth. Commun., 35, 2759-2764 (2005) 
15.Rao P.S. and Venkataratnam R.V., Zinc chloride as a new 
catalyst for knoevenagel condensation, Tetrahedron Lett., 32, 5821-5822 (1991) 16.Prajapati D. and Sandhu J.S.,Cadmium iodide as a new catalyst for knoevenagel condensations, J. Chem. Soc. Perkin Trans., , 739-740 (1993)
Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 4(7), 93-98, July (2014) Res. J. Chem. Sci.   International Science Congress Association 
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17.Pullabhotla Rajasekhar V. S. R., Rahman A. and Jonnalagadda S. B., Selective catalytic Knoevenagel condensation by Ni–SiO supported heterogeneous catalysts: An environmentally benign approach, Catal. Commun., 10, 365-369 (2009) 18.Dai G., Shi D., Zhou L. and Huaxue Y., Knoevenagel condensation catalyzed by potassium fluoride/alumina Chin. J. Appl. Chem.,12, 104-108 (1995) 19.Sebti S., Smahi A. and Solhy A., Natural phosphate doped with potassium fluoride and modified with sodium nitrate: efficient catalysts for the Knoevenagel condensation, Tetrahedron Lett., 43, 1813-1816 (2002) 20.Bennazha J., Zahouily M., Sebti S., Boukhari A. and Holt 
E. M., NaCaP, a new catalyst for Knoevenagel 
reaction, Catal. Commun., , 101-104 (2001) 21.Maadi El. A., Matthiesen C.L., Ershadi P., Baker J., Herron D.M., Holt E.M., J. Chem. Cryst., 33, 757 (2003)22.Deb M. L. and Bhuyan P. J., Uncatalysed Knoevenagelcondensation in aqueous medium at room temperature, Tetrahedron Lett., 46, 6453-6456 (2005) 23.Khurana J. M. and Vij K., Nickel Nanoparticles Catalyzed Knoevenagel Condensation of Aromatic Aldehydes with Barbituric Acids and 2-Thiobarbituric Acids, Catal. Lett., 138, 104-110 (2010) 24.Kaur J. R. and Kaur G., CoFe nanoparticles: An efficient heterogeneous magnetically separable catalyst for “click” synthesis of arylidene barbituric acid derivatives at room temperature, Chinese Journal of Catalysis, 34, 1697-1704 (2013) 25.Reetz M. T., Helbig W., Quaiser S. A., Electrochemical Preparation of Nanostructural Bimetallic Clusters, Chem. Mater., , 2227-2228 (1995) 
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