Investigation of New Procedure for Selective Reaction and Synthesis of Some New 2-Substituted Benzimidazole Derivatives
Arjun Bodkhe1, Dattatraya Pansare2*, Dnyaneshwar Karpe1 , Vilas Sudrik1, Manohar Suryawanshi1 and Shamrao Lawande1*
1Department of Chemistry, Shri Chhatrapati Shivaji Mahavidyalaya, Shrigonda, Maharashtra, India.
2Department of Chemistry, Deogiri College Chhatrapati Sambhajinagar, Maharashtra, India.
Corresponding Author E-mail: splawande@gmail.com
DOI : http://dx.doi.org/10.13005/ojc/400408
Article Received on : 12 Jul 2024
Article Accepted on : 21 Aug 2024
Article Published : 29 Aug 2024
Reviewed by: Dr. Madhavi Nannapaneni
Second Review by: Dr. Reena Tyagi
Final Approval by: Dr.Murat HATİPOĞLU
The objective of this study is to investigate a new procedure for specifically reducing the NO2 group present on the aromatic ring along with ester group. We revealed that NaBH4-FeCl2 serves as a crucial reagent in this process. The reduction mediated by NaBH4-FeCl2 exhibited remarkable chemoselectivity, yielding the wanted products in outstanding yields of up to 90-95%. Furthermore, this process was successfully utilized in the synthesis of diamino compound, and in the synthesis of 2-substituted benzimidazole derivatives The diamine compounds was condensed with various aromatic or heterocyclic carboxylic acids in the existence of EDC.HCl and catalyst DMAP. The resulting moiety or product underwent cyclization by using CH3COOH at 100-110°C. Both the reactions (coupling & cyclization) reaction completed effectively, within the minimal reaction times. The structure of created compounds was confirmed using modern spectral techniques like FT-IR, mass spectrometry, NMR.
KEYWORDS:benzimidazole; DMAP; Green synthesis; HCl; NaBH4-FeCl2
Download this article as:Copy the following to cite this article: Bodkhe A, Pansare D, Karpe D, Sudrik V, Suryawanshi M, Lawande S. Investigation of New Procedure for Selective Reaction and Synthesis of Some New 2-Substituted Benzimidazole Derivatives. Orient J Chem 2024;40(4). |
Copy the following to cite this URL: Bodkhe A, Pansare D, Karpe D, Sudrik V, Suryawanshi M, Lawande S. Investigation of New Procedure for Selective Reaction and Synthesis of Some New 2-Substituted Benzimidazole Derivatives. Orient J Chem 2024;40(4). Available from: https://bit.ly/3XqwuHS |
Introduction
The Benzimidazole pharmacophore stands as a pipathogensrocyclic element within a plethora of pharmaceutical1,2. Because of their broad spectrum of bioactivity, this compounds class has captured the interest of medicinal and organic chemists, spurring the exploration of diverse synthetic methodologies.3 With seven positions available for substitution, the benzimidazole moiety offers a canvas for the manifestation of unique and varied bioactivities across various drug classes4. Notably, compounds featuring the benzimidazole pharmacophore find utility in numerous therapeutic areas, including antimicrobial 5 and antiviral agent combating pathogens 6-14 .
The remarkable diversity in bioactivity spurred chemists to explore various synthetic routes for benzimidazole synthesis. Initially, benzimidazoles were readily obtained through the condensation of diamine with compound containing functional groups like -COOH, -CN, and RC(OR’)315 . Though, this method is disadvantaged by drawbacks such as lesser yields, the formation of impurities16 . Moreover, employing catalysts like Titanium containing catalyst , cumene hydroxide17 ,has confirmed to offer good to better yields.
Additionally, metal Ru,18 Pd19 and Rh20 catalysts also employed in the creation of benzimidazole. However, described approaches for producing 2-substituted benzimidazole moiety often lack compatibility with diverse functional group or several starting materials revealing varying substitution designs. Furthermore, they typically necessitate high-priced catalysts, elevated temperature, or harsher reaction circumstances, like the use of hazardous acid for reactions. Accordingly, these approaches may not be conductive to kilo-scale production.
The objective of this research was to investigate a new method for selectively reducing the NO2 group without affecting the RCOOR’group. In this finding, NaBH4-FeCl2 was identified as a crucial reducing agent in the process, resulting in the formation of the corresponding amino compound. The reduction mediated by NaBH4-FeCl2– demonstrated high chemo selectivity, yielding the desired products in impressive yields (up to 90-95%). Furthermore, this method was utilized to synthesis of dabigatran intermediate. (anticoagulant drug ) and the synthesized di-amino compound. This was reacted with various Carboxylic acids by using coupling reagent like EDC.HCl and cat. DMAP, and subsequently cyclized by using CH3COOH at reflux to yield 2-substituted benzimidazole derivatives.
Result and Discussion
The investigation into reduction condition was carried out as detailed illustrated Table 1. Our finding commenced using substrate 3. Firstly, the reaction was performed with 1.0 equit. of MXn and 2.5 equit. of NaBH4 under an inert environment in THF at 25-30 °C. The exhibited process was sluggish, resulting in only a 12 % yield to the desired product 3 when CuSO4 was utilized ( Entry i in Table 1) and when using AlCl3 or LiCl, yielding 35.5% and 5 % respectively (Entries ii,iii in Table 1). Interestingly, we have observed that when used metal salts good to moderate yield was obtained. Subsequently, various ferrous salts were assessed, revealing FeCl2 as optimal, achieving high yield (up to 93.2%), whereas other salts give less yield (< 35%, Entries v,vii,viii in Table 1). Tried to reduce the amount of NaBH4 led to significant decreases in yield when reducing the loading from 2.5 equit. to 1.5 or 1.1 equit. (Entries vi and ix-xi in Table 1). Furthermore, experimentation with different quantities of FeCl2 indicated that 1.0equiv.was optimal, with decreasing equivalents resulting in less yield. (Entries xii-xiv in Table 1). Solvent choice significantly influenced the reaction, with aprotic solvents favoring high yield, while in polar Solvent yielded poor results (Entry vi, xv, xvi in Table 1). Consequently, Tetrahydrofuran was preferred as a solvent. Lastly, impact of reaction temperature on assessed, revealing decreased yield (Entry xvii in Table 1). Attempts to enhance the rate by elevating temperature to 40-45°C yielded unexpectedly low yield (Entry xviii in Table1). Ultimately, the optimal reaction conditions were established as 2.5 equit. of NaBH4, 1.0 equit. of FeCl2, THF, and a reaction temp. of 25-30 °C.
Table 1: Optimization of Reagent, its equivalent, solvent selection and reaction temp.
Entry |
MXn(eq.) |
NaBH4 (eq.) |
Solvent |
Output (%) |
Temp. (°C) |
i |
CuSO4 (1.0) |
2.5 |
THF |
12.0 |
25-30°C |
ii |
AlCl3 (1.0) |
2.5 |
THF |
35.5 |
25-30°C |
iii |
LiCl (1.0) |
2.5 |
THF |
5.3 |
25-30°C |
iv |
FeCl3 .6H2O (1.0) |
2.5 |
THF |
3.7 |
25-30°C |
v |
FeCl3 .7H2O (1.0) |
2.5 |
THF |
25.3 |
25-30°C |
vi |
FeCl2 (1.0) |
2.5 |
THF |
93.2 |
25-30°C |
vii |
FeBr2 (1.0) |
2.5 |
THF |
3.8 |
25-30°C |
viii |
FeC2O4.2H2O (1.0) |
2.5 |
THF |
12.8 |
25-30°C |
ix |
FeCl2 (1.0) |
2.0 |
THF |
83.20 |
25-30°C |
x |
FeCl2 (1.0) |
1.5 |
THF |
61.2 |
25-30°C |
xi |
FeCl2 (1.0) |
1.1 |
THF |
18.3 |
25-30°C |
xii |
FeCl2 (0.8) |
2.5 |
THF |
85.0 |
25-30°C |
xiii |
FeCl2 (0.5) |
2.5 |
THF |
72.0 |
25-30°C |
xiv |
FeCl2 (0.2) |
2.5 |
THF |
36.0 |
25-30°C |
xv |
FeCl2 (1.0) |
2.5 |
MeCN |
78.0 |
25-30°C |
xvi |
FeCl2 (1.0) |
2.5 |
EtOH |
17.5 |
25-30°C |
xvii |
FeCl2 (1.0) |
2.5 |
THF |
23.6 |
10-15°C |
xviii |
FeCl2 (1.0) |
2.5 |
THF |
34.6 |
40-45°C |
Benzimidazole derivatives prepared through the reaction of di amino compound with several aromatic compounds that have COOH gr., Catalyzed by EDC.HCl and cat. DMAP. The resulting coupled compounds were then cyclized in CH3COOH at 100-110°C (Scheme 1). The reaction supervised by TLC.
We selected the reaction between synthesized di-amino compound and Benzoic acid as a model reaction for optimization of coupling reagent and reagent which increase the rate of reaction. Initially, we conducted the model reaction using Thionyl Chloride & TEA, which resulted in lower conversion and isolated yield. Subsequently, we explored different coupling reagents like DCC-HOBt Carbonyldimidazole, EDC.HCl-DMAP ( Entries ii-iv in Table 2 ). We have found that DCC-HOBt and Carbonyldimidazole (Entries II-III in Table 2) yielded only 83% and 80% respectively. The optimal result, boasting a 90% yield for product 3a, was attained through the utilization of coupling reagent EDC.HCl /DMAP (Entries iv in Table 2 ).
Table 2: Optimization of Coupling reagent along with reaction time and outcome
Entry |
Reagent |
Time (Minutes) |
Output (%) a |
i |
SOCl2 & TEA |
60 |
75 |
ii |
DCC-HOBt |
60 |
83 |
iii |
Carbonyldimidazole |
60 |
80 |
iv |
EDC.HCl-DMAP |
60 |
90 |
aIsolated yield. |
Various reagents , including (HBTU) and (TBTU) , Hydroxybenzotrizole (HOBt), 4-Dimethylaminopyridine (DMAP) were also investigated to accelerate reaction rate of reaction with coupling reagent . Applying the similar 6a reaction as an example, we initially conducted the reaction as such without any reagents (Entry i in Table 3 ), which necessitated a prolonged reaction time of approximately 360 to 420minutes. However, the inclusion of catalytic amounts of HOBt , HBTU, TBTU, and DMAP (Entries ii-v in Table 3) significantly expedited the reaction, reducing the reaction time to just half an hour. While both reagents proved effective, we opted for DMAP due to safety considerations in enhancing the reaction rate.
Table 3: Optimization of Catalyst
Entry |
Catalyst |
Time (min) |
Output (%) a |
i |
— |
360 |
80 |
ii |
HOBt |
60 |
83 |
iii |
HBTU |
90 |
80 |
iv |
TBTU |
90 |
81 |
v |
DMAP |
60 |
90 |
aIsolated yield. |
Different acids, including 4N HCl, Acetic acid , Formic acid , Ammonium chloride, polyphosphoric acid and ortho phosphoric acid were also investigated in cyclization reaction. we initially conducted reaction with 4N HCl, but we got less yield. Next, acid (Entries ii-v in Table 4). It was found that only 73%, 78%,76%, and 75% yield was obtained by using Formic acid, NH4Cl, Polyphosphoric acid, Ortho-phosphoric acid respectively. CH3COOH facilitates cyclization efficiently, providing good yields in a shorter reaction time. (Entry vi in Table 4, ).
Table 4: Optimization of Acid, reaction time and output for cyclization
Entry |
Acid Reagent |
Time (min) |
Output (%) a |
i |
4N HCl |
120 |
74 |
ii |
Formic acid |
100 |
73 |
iii |
NH4Cl |
120 |
78 |
iv |
Polyphosphoric acid |
100 |
76 |
v |
Ortho-phosphoric acid |
100 |
75 |
vi |
Acetic Acid |
60 |
90 |
aIsolated yield. |
By employing these optimized reaction conditions, a range of benzimidazole derivatives 4a-j were efficiently produced within a quicker timeframe and with enhanced yields. This synthesis utilized EDC.HCl and DMAP as coupling reagents, along with a CH3COOH acid assisting in the cyclization.
This approach utilized to produce a series of new Benzimidazole (2-substituted) derivatives. The outcomes succinctly presented in Table 5.
Scheme 1: Synthesis of Some New Benzimidazole derivatives (6a-j). |
Our current procedure was applied to a diverse array of several carboxylic acids to demonstrate its broad utility, as outlined in Table 3. It was observed that both unsubstituted and electron-withdrawing substituent -bearing aromatic and heteroaryl carboxylic acids underwent smooth conversion, yielding products and purified by using Flash chromatography solvent (Table 3). Compounds (6a, 6d, and 6f) lacking substituents, as well as some compounds with electron-withdrawing substituents (6b, 6c, 6e, 6h, 6i and 6j) such as (CN) Cyano, (Br) Bromo, (Cl) Chloro , dichloro, and NO2(Nitro)respectively, were synthesized successfully. Nevertheless , in the preparation of compounds 6a-6j, it was detected that when substituents presented on ortho position, several carboxylic acids resulted in impure compounds, requiring purification through flash chromatography, resulting in a lower yield for compounds 6g. Additionally, attempts were made to synthesize benzimidazole derivatives using aromatic acid which ortho substituted aromatic benzoic acid .However, these substituted acids exhibited lower reaction conversion rates.
Spectral data for the representative compound (6a)
The FT-IR spectrum shows a peak at 1723 cm-1 confirming the presence of a carbonyl group, and a peak at 3397 cm-1, indicating NH groups in the structure. The 1H NMR spectrum shows a chemical shift δ between 7.50–7.13, suggesting the presence of aromatic protons. The chemical shift at δ 3.75 (s, 3H) confirms that a methyl group is attached to the nitrogen atom in the structure. The molecular weight of the compound is 483.213 [M+1]+, which exactly matches the reported structure.
Table 5: Synthesis of 2-Substituted benzimidazole (6a-j): |
Experimental
Materials and Methods
Compounds were sourced from a commercial vendor, while reagents and analytical grade (A.R.) solvents were procured from Sigma-Aldrich. The reaction progress was monitored via Thin Layer Chromatography (TLC) on silica plates (Merck silica gel 60F254). Column chromatography was carried out using silica gel with a 60–120 mesh size.
Instrumentation
The FT-IR Spectra recorded at 100 FT-IR; Mass spectra recorded at Advion Expression CMS instrument. The PMR spectra were recorded on 400MHz, and CMR spectra recorded on 100MHz Brucker spectrometer in DMSO/CDCl3 using Brucker instrument. The chemical shift value was recorded with respect to standard Tetramethylsilane.
Reaction conditions
The glassware utilized for reactions underwent thorough washing and cleaning procedures before being dried at 150°C and subsequently cooled under vacuum conditions.
Experimental procedure :
General method for the preparation of compound (3):
Compound 1 (5.09 mmol) dissolve in CH2Cl2 (5 mL) and Cat. amount DMF, cool it to 0-10°C then add dropwise SOCl2 (7.63 mmol)in 10 minute. Raise the temperature to 20-30°C and stirred for 60minutes at 20-30°C, monitoring reaction TLC. After completion of reaction, concentrate reaction mixture and degassed for 30 minutes. Obtained residue cooled to 20-30°, added CH2Cl2 (5mL), triethyl amine(10.18mmol) and stirred for 10min.Cool it at 0-5° then added dropwise solution of Compound 2 (4.581mmol) in CH2Cl2 (5 mL), raised temperature to 20-30°C and stirred for 30minutes.monitor reaction by TLC.After completion of reaction added a NaHCO3 (5 mL) solution to reaction mix. and separate the organic layer and wash with water(5mL). Concentrate under vacuum and obtain crude residue crystallized form hexane to get pure Compound3.(1.30g, 79.3%)as Pale Yellow solid.
General method for the preparation of compound (4)
Compound 3 dissolved in THF (10mL) and stirred for 10-15 minutes, add FeCl2 (3.22 mmol)followed by NaBH4 (8.05 mmol) under argon/ Nitrogen atmosphere and stir for 720min.at 20-30°C, monitoring reaction on TLC. After complete consumption of Comp.3 , water (20mL) was added , Organic extract extract with Ethyl Acetate. wash with water .Concentrate the organic layer to form Crude residue and column chromatography used to get the pure compound 4 (1.01g, 93.2%).
The General method for the preparation of compound (6a-j):
To a stirred mixture of the compound 4 (1.46mmol) and DMAP(0.146mmol) in CH2Cl2 (10mL) added the different carboxylic acid (1.75mmol) in CH2Cl2 (5 mL)in one portion at RT. The resulting blend stir at 20-30°C for 60 minutes. Afterward reaction monitored by TLC.After completion of reaction added water (10mL). Separate the organic layer Organic layer and then organic layer successively wash with NaHCO3 solution and water. The organic layer dried over Na2SO4 .Concentrated under vacuum, obtained oily residue degassed for 30min. Obtained residue cool to 20-30°C, add Acetic acid (5 mL) , stirred for 5-10min. Raised temperature 100-110 °C and stirred for 60min. Cool reaction mix to 20-30°C, added water (25mL) and extracted with CH2Cl2 .The organics wash with 5% NaHCO3 solution, dried by using Na2SO4 and concentrate .The resulting residue purified by using flash chromatography technique to provide the product 6a-j. (0.56g, 90%).
Spectral data
Compound (3)
Pale Yellow solid , Yield: 79.3%, m.p. 88-90°C, FT-IR (cm-1): 3382, 1721, 1648,1620, 1566 ,1368, 1270 , 1175 . 1H NMR (CDCl3, δppm): d 8.47 (d, 1H ), 8.14 (br, 2H ), 7.53 (t, 1H ), 7.43 (d, 1H ), 7.11 (dd, 1H), 6.87 (d, 1H ), 6.66 (d, 1H), 4.37 (t, 2H ), 4.09 (t, 2H ), 2.98 (d, 3H), 2.79 (t, 2H), 1.23 (t, 3H ). 13C NMR ( CDCl3 , δppm): d 171.68, 168.44, 156.08, 149.24, 147.00, 137.79, 136.35, 130.80, 128.70, 122.25, 122.17, 121.50, 112.78, 60.57, 44.97, 33.22, 29.78, 14.14. ESI-MS m/z : 373.150 [M+1]+.
Compound (4)
Light yellow, Yield: 94.9 %, m.p. 141-143 °C. FT-IR (cm-1): 3359,2986, 1729,1634 (, 1592,1569,1378, 1191,1154 . 1H NMR ( DMSO-d6, δppm ): d 8.41 (m,1H ), 7.57 (dt, 1H), 7.20 (m, 1H ), 6.78 (d, 1H), 6.67 (d, 1H ), 6.34 (dd, 1H), 6.11 (d, 1H), 5.10 (br, 1H), 4.55 (br, 2H,), 4.18 (t, 2H), 3.97 (q, 2H), 2.65 (s, 3H ), 2.65 (t, 2H), 1.12 (t, 3H).13C NMR (DMSO-d6, δppm): d 171.56, 171.10, 157.00, 148.84, 139.88, 137.82, 135.52, 123.18, 122.24, 120.93, 120.36, 115.59, 107.33, 60.41, 44.47, 33.63, 30.18, 14.44. ESI-MS m/z : 341.162[M+1]+.
Compound (6a)
Pale yellow, Yield:85%, m.p.: 117-119 °C.FT-IR (cm-1): 3397, ,2979, 1723, 1630, 1605, 1584, 1378, 1179, 1127.1H NMR ( DMSO-d6, δppm): d 8.40 (d, 1H),7.50 (m, 3H), 7.39 (d, 1H), 7.28 (br, 1H), 7.19 (d, 1H), 7.13 (t, 2H), 6.88 (m, 3H ), 4.60 (d, 2H), 4.24 (t, 2H), 3.97 (q, 2H), 3.75 (s, 3H), 2.71 (t, 2H), 1.13 (t, 3H).13C NMR (DMSO-d6, δppm): d 172.52, 171.79, 156.48, 153.79, 152.22, 149.16, 141.27, 138.34, 137.70, 133.79, 129.82, 123.33, 122.58, 121.71, 120.91, 120.01, 112.84, 109.97, 97.5, 60.49, 44.84, 40.12, 33.50, 30.35, 14.42. ESI-MS m/z : 483.213[M+1]+.
Conclusion
In conclusion of our research work, NaBH4-FeCl2 was revealed as a major reductant in the process resulting in the formation of the corresponding amino compound. NaBH4-FeCl2-mediated reduction proven high chemo selectivity, gave the required products in impressive yield (up to 90-95%). The synthesized di-amino compound condensed with several carboxylic acids (aromatic) in the existence of EDC.HCl and cat. DMAP, and insitu cyclization by using Acetic acid. The conditions are gentle, allowing for the tolerance of wide range of functional groups. This condensation reaction offers several advantages: it can be carried out using affordable, readily available chemicals, under extremely simple reaction conditions, with short reaction times, extraordinary yields. Additionally, it employs simple experimental techniques, is cost-economical, and associates with the bases of green chemistry. The biological activity of synthesized compounds will take in due course and hope it will be shows better activity against tested strains.
Acknowledgment
The authors thankful to The Principal, Shri Chhatrapati Shivaji Mahavidyalaya, Shrigonda, 413701, Maharashtra, India for providing the laboratory facility.
Conflicts of interest
The authors(s) declare(s) that there is no conflict of interests regarding the publication of this article.
Funding Sources
There is no funding sources.
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