Palladium-Catalyzed Cyanation under Mild Conditions: A Case Study to Discover Appropriate Substrates among Halides and Pseudohalides

Abstract

A case study has been effectively carried out to identify a suitable substrate among halides and pseudohalides for the palladium-catalyzed cyanation reactions under mild conditions. Among the various substrates considered for evaluation, aryl pentafluorobenzenesulfonates and nonaflates were identified to be the best substrates when compared to corresponding halides and pseudohalides. The substoichiometric use of nontoxic, environmentally benign potassium hexacyanoferrate as a cyanide source and exceptionally milder conditions further highlights the significance of the protocol developed. A wide range of electronically biased and sterically challenging substrates provided the corresponding the nitriles in good to excellent yields.

Aromatic nitriles are of significant importance in synthetic organic chemistry as they are essential building blocks in many drugs, pesticides, herbicides, natural products, dyes, and pigments. The possibility of converting the nitriles into other useful functionalities like amines, acids, amides, ester, imine, amidine, heterocyclic compounds, etc. also emphasizes the necessity of synthesizing various substituted benzonitriles under mild conditions.[1] Additionally, they serve as vital synthons in the synthesis of many important pharmacophores like tetrazoles, oxadiazoles, etc., which are known to improve the biological profiles of lead compounds in any drug discovery program. The general method for the synthesis of cyanoarenes in industrial scale include the diazotization of amines followed by Sandmeyer reaction and Rosenmund–von Braun reaction[2] of aryl halides using stoichiometric amount of copper(I) cyanide at high temperature. The ammoxidation reaction of toluene is also widely used in industries, but its scope is limited to only a few benzonitriles and requires very high temperature (350–500 ℃).[3] An alternative methodology include the transition-metal-catalyzed (Ni, Pt, Pd, Cu, etc.) reactions by employing various cyanide sources like zinc cyanide, potassium/sodium cyanide, trimethyl silyl cyanide, and tributyl tin cyanide. Among the transition-metal-catalyzed reactions, the palladium-catalyzed cross-coupling reactions between aromatic halides or triflates and different cyanide sources are more widely used for procuring the corresponding benzonitriles owing to its good functional group tolerance, less sensitivity, and high reactivity.[4] However, the major limitations associated with this technology are the need for toxic cyanide source and harsh conditions like high temperature and long reaction times. Furthermore, the dissolution of excess cyanide ions in the reaction medium is expected to inhibit the catalytic cycle thereby decreasing the rate of formation of the desired product significantly.[5] Recently, potassium hexacyanoferrate (K₄FeCN₆·3H₂O) was introduced as a nontoxic cyanide source in order to circumvent the aforementioned concerns.[6] Nevertheless, the need for high temperature and extended reaction times prevailed to be indispensable for the success of those protocols (Scheme [1]). These observations highlight the need for developing a milder and efficient protocol for synthesizing aromatic nitriles of significant industrial and pharmacological relevance.

The presence of nitrile functionality in many FDA approved drugs and also in many bioactive lead molecules highlights its significance in the area of organic synthesis. This has led to the development of facile and scalable synthetic protocols for introducing the nitrile group in a molecule from halide or pseudohalide counterparts. Although the introduction of nitrile functionality into an organic molecule is well reported, most of the protocols require either the use of hazardous cyanide source, high temperature, or the use of palladium-based precatalytic systems. The use of these precatalytic systems has been reported on halides and pseudohalides using zinc cyanide as the cyanide source which facilitated milder reaction conditions.[7] As a part of our research efforts,[8] we were focused on developing an efficient and milder synthetic protocol for accessing the cyano functionality from bench-stable aryl pentafluorobenzenesulfonates (ArOPFB) and aryl nonaflates (ArONf) employing traditional catalytic systems. Furthermore, a case study to identify the superior reactivity of these bench-stable pseudohalides over their corresponding halides has also been explored.

As a starting point, we took 4-bromo toluene as a model substrate and subjected for the palladium-catalyzed cyanation reaction by using 0.2 equiv of K₄FeCN₆·3H₂O as cyanide source as reported by Weissmann et al.[9] The reaction was carried out at 120 ℃ by using 0.1 mol% Pd(OAc)₂ as the catalyst and Na₂CO₃ as base in DMA for 5 h. Unsurprisingly, we could obtain only 10% of the desired product 3a as reported by them (Table [1], entry 1). Increasing the catalyst loading to 5 mol% and changing the solvent from DMA to DMF slightly improved the yield (entries 2 and 3). The addition of extra ligands to the catalyst was found to be ineffective in significantly improving the yield of the desired product (entries 4 and 5). However, we could see the formation of the desired cyanoarene in 50% yield when tetrakis was used as a catalyst instead of Pd(OAc)₂ at 120 ℃ for 24 h (entry 7). Further increasing the time of the reaction or temperature did not give any considerable improvement in the yield (entries 8 and 9). Changing the base from Na₂CO₃ to other inorganic and organic bases decreased the formation of desired product (entries 10–12). Although the yield of the desired product obtained from our best conditions (entry 7) was found to be satisfactory (50%), the requirement of harsh reaction conditions and prolonged reaction time insisted us to continue our quest for developing a milder and efficient protocol for cyanation.

Table 1 Reaction Optimization for the Cyanation of 4-Bromotoluene^a

Entry	Catalyst	Ligand	Base	Solvent	Yield (%)b
1	Pd(OAc)2	–	Na2CO3	DMA	10c
2	Pd(OAc)2	–	Na2CO3	DMA	20
3	Pd(OAc)2	–	Na2CO3	DMF	24
4	Pd(OAc)2	PPh3	Na2CO3	DMF	18
5	Pd(OAc)2	Xantphos	Na2CO3	DMF	15
6	Pd(PPh3)4	–	Na2CO3	DMF	30
7	Pd(PPh3)4	–	Na2CO3	DMF	50d
8	Pd(PPh3)4	–	Na2CO3	DMF	48e
9	Pd(PPh3)4	–	Na2CO3	DMF	45f
10	Pd(PPh3)4	–	K2CO3	DMF	20d
11	Pd(PPh3)4	–	Cs2CO3	DMF	12d
12	Pd(PPh3)4	–	TEA	DMF	traced

^a Reaction conditions: 4-bromotoluene (1 equiv), K₄Fe(CN)₆·3H₂O (0.2 equiv), catalyst (5 mol%), ligand (10 mol%), base (1 equiv) in dry DMF, heated for 5 h at 120 ℃.

^b Isolated yield after column chromatography.

^c 0.1 mol% of catalyst used.

^d Reaction carried out for 24 h.

^e Reaction carried out for 36 h.

^f Reaction carried out at 150 ℃.

These observations encouraged us to screen other halides and pseudohalides as substrates for the palladium-catalyzed cyanation reaction. Initially, we took p-cresol and synthesized its corresponding pseudohalides like tosylate, mesylate, triflate, nonaflate (ONf), and pentafluorobenzene sulfonate (OPFB) (see the Supporting Information). The corresponding halides (chloro, bromo, and iodo) were also arranged for our control experiments. All these substrates were subsequently screened under our previously best reaction conditions (Table [1], entry 7) at 40 ℃ for 5 h (Table [2]). To our disappointment, we could obtain only a negligible amount of the desired product with 4-bromotoluene as the substrate, and the unreacted starting material was found to be major (Table [2], entry 1). From this point, we decided to carry out a case study by examining the same reaction conditions with other halides and pseudohalides. Among the halides, the chloro substrate was unreactive whereas the corresponding iodo gave 15% of the desired product (entries 2 and 3). Amongst the pseudohalides, tosylates and mesylates were found to be unreactive (entries 4 and 5). The triflates reacted almost similar to that of the bromo counterpart but showed the presence hydrolyzed product (4-hydroxytoluene) as a competing side product (entry 6). Gratifyingly, we could obtain the desired product in reasonable yield when OPFB (75%) and ONf (70%) were used as substrates (entries 7 and 8).

Table 2 Screening of Different Substrates for Reaction Optimization^a

Entry	Substrate	Halide/pseudohalide	Yield (%)b
1	1a	bromo	10
2	1b	chloro	nil
3	1c	iodo	15
4	1d	tosylate	nil
5	1e	mesylate	nil
6	1f	triflate	12
7	1g	nonaflate	72
8	1h	pentafluorobenzenesulfonate	75

^a Reaction conditions: toluene derivative (1 equiv), K₄Fe(CN)₆·3H₂O (0.2 equiv), Pd(PPh₃)₄ (5 mol%), Na₂CO₃ (1 equiv) in dry DMF, heated for 5 h at 40 ℃.

^b Isolated yield after column chromatography.

Based on these results, we decided to further optimize the cyanation reaction conditions with more reactive and bench-stable pseudohalides (OPFB and ONf) as the substrates (Table [3]). We altered the stoichiometric ratio of K₄FeCN₆·3H₂O, temperature, and reaction time so as to improve the yield of the desired cyanoarene 3a. The yield of the required product was dramatically increased when 0.33 equiv of K₄FeCN₆·3H₂O were used (entry 2). To our delight, we obtained the desired product in excellent yield when the reaction was carried out at 40 ℃ for 3 h (entry 3). Further reduction in temperature and time led to incomplete conversions (entries 4 and 5).

Table 3 Reaction Optimization with Nonaflates and Pentafluorobenzenesulfonates^a

Entry	K4Fe(CN)6·3H2O (equiv)	Time (h)	Yield of 3a (%)b
			X = ONf	X = OPFB
1	0.2	5	72	75
2	0.33	5	90	92
3	0.33	3	96	97
4	0.33	2	85	84
5	0.33	3	80c	82c

^a Toluene derivative (1 equiv), K₄FeCN₆·3H₂O, Pd(PPh₃)₄ (5 mol%), Na₂CO₃ (1 equiv) in dry DMF, heated for 3–5 h at 40 ℃.

^b Isolated yield after column chromatography.

^c Reaction carried out at 30 ℃.

After getting a mild and greener protocol for cyanation reaction, our next attention was to evaluate the generality of the developed protocol. We synthesized a series of diverse nonaflates and pentafluorobenzene sulfonates and propagated the synthesis of corresponding nitriles (Scheme [2]). All the ONfs and OPFBs, irrespective of their electronic properties, reacted well enough to furnish the desired nitriles in good to excellent yield.[10]

The diversity in the availability of phenols and its facile conversion into the corresponding nonaflates or OPFBs emphasize the applicability of utilizing aryl OPFBs or nonaflates as an alternative substrate in the palladium-catalyzed cyanation reaction for obtaining aryl nitriles. The stability of nonaflates and pentafluorobenzenesulfonates in the reaction medium for palladium-catalyzed reactions has already been reported previously.[11] The nonaflates are known to suppress the O–S bond cleavage in the reaction medium and thereby prevent its hydrolysis to the corresponding phenols. The OPFBs are highly stable and more reactive towards traditional palladium-catalyzed cross-coupling reactions owing to its superior reactivity and stability. In our successful trials, we have figured out that the use of bench-stable and reactive ArOPFBs and ArONfs as electrophiles resulted in good to excellent conversions under exceptionally milder conditions. This could be probably attributed to the facile oxidative addition of these electrophiles using conventional palladium-catalyst systems like Pd(PPh₃)₄ under very milder conditions as observed with previous palladium-mediated reactions involving these pseudohalides.[11e] [12]

We have successfully performed a case study for finding a suitable substrate for the palladium-catalyzed cyanation reaction under mild conditions. The key findings of our study paved the way for developing aryl nonaflates and pentafluorobenzenesulfonates as effective substrates for the proposed reaction. As a result, we developed an exceptionally mild protocol for the palladium-catalyzed cyanation reaction to generate a series of cyanoarenes in good to excellent yields. The developed protocol can be extended for the synthesis of other complex nitriles in future.

• References and Notes

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• References and Notes

• 1a Yang C, Williams JM. Org. Lett. 2004; 6: 2837
  CrossrefPubMedSuche in Google Scholar
• 1b Yeung PY, So CM, Lau CP, Kwong Y. Angew. Chem. Int. Ed. 2010; 49: 8918
  CrossrefPubMedSuche in Google Scholar
• 1c Tu Y, Zhang Y, Xu S, Zhang Z, Xie X. Synlett 2014; 25: 2938
  Thieme ConnectSuche in Google Scholar
• 1d Yeung PY, So CM, Lau CP, Kwong FY. Org. Lett. 2011; 13: 648
  CrossrefPubMedSuche in Google Scholar
• 1e Hajipour AR, Karami K, Pirisedigh A. Appl. Organomet. Chem. 2010; 24: 454
  Suche in Google Scholar
• 2a Sandmeyer T. Ber. Chem. Dtsch. Chem. Ges. 1884; 17: 2650
  Suche in Google Scholar
• 2b Sandmeyer T. Ber. Chem. Dtsch. Chem. Ges. 1885; 18: 1492
  Suche in Google Scholar
• 2c Rosenmund KW, Struck E. Ber. Chem. Dtsch. Chem. Ges. 1919; 52: 1749
  Suche in Google Scholar
• 2d von Braun J, Manz G. Justus Liebigs Ann. Chem. 1931; 488: 111
  CrossrefSuche in Google Scholar
• 2e Moury DT. Chem. Rev. 1948; 42: 207
  Suche in Google Scholar
• 2f Ellis G, Romney-Alexander T. Chem. Rev. 1987; 87: 779
  CrossrefSuche in Google Scholar
• 3a Stevenson AC. Ind. Eng. Chem. 1949; 41: 1846
  CrossrefSuche in Google Scholar
• 3b Denton WI, Bishop RB, Caldwell HP, Chapman HD. Ind. Eng. Chem. 1950; 42: 796
  CrossrefSuche in Google Scholar
• 4a Shevlin M. Tetrahedron Lett. 2010; 51: 4833
  CrossrefSuche in Google Scholar
• 4b Littke A, Soumeillant M, Kaltenbach RF. III, Cherney RJ, Tarby CM, Kiau S. Org. Lett. 2007; 9: 1711
  CrossrefPubMedSuche in Google Scholar
• 4c Cheng Y.-N, Duan Z, Li T, Wu Y. Synlett 2007; 543
• 4d Schareina T, Jackstell R, Schulz T, Zapf A, Cotte A, Gotta M, Beller M. Adv. Synth. Catal. 2009; 351: 643
  CrossrefSuche in Google Scholar
• 4e Schareina T, Zapf A, Maegerlein W, Mueller N, Beller M. Tetrahedron Lett. 2007; 48: 1087
  CrossrefSuche in Google Scholar
• 5a Erhardt S, Grushin VV, Kilpatrick AH, Macgregor SA, Marshall WJ, Roe DC. J. Am. Chem. Soc. 2008; 130: 4828
  CrossrefPubMedSuche in Google Scholar
• 5b Marcantonio KM, Frey LF, Liu Y, Chen Y, Strine J, Phenix B, Wallace DJ, Chen C.-Y. Org. Lett. 2004; 6: 3723
  CrossrefPubMedSuche in Google Scholar
• 6a Schareina T, Zapf A, Beller M. Chem. Commun. 2004; 1388
  PubMed
• 6b Schareina T, Zapf A, Beller M. J. Organomet. Chem. 2004; 689: 4576
  CrossrefSuche in Google Scholar
• 6c Chen G, Weng J, Zheng Z, Zhu X, Cai Y, Cai J, Wan Y. Eur. J. Org. Chem. 2008; 3524
• 6d Grossman O, Gelman D. Org. Lett. 2006; 8: 1189
  CrossrefPubMedSuche in Google Scholar
• 6e Senecal TD, Shu W, Buchwald SL. Angew. Chem. Int. Ed. 2013; 52: 10035
  CrossrefPubMedSuche in Google Scholar
• 6f Zhang J, Chen X, Hu T, Zhang Y, Xu K, Yu Y, Huang J. Catal. Lett. 2010; 139: 56
  CrossrefSuche in Google Scholar
• 6g So CM, Kwong FY. Chem. Soc. Rev. 2011; 40: 4963
  CrossrefPubMedSuche in Google Scholar
• 7 Cohen DT, Buchwald SL. Org. Lett. 2015; 17: 202
  CrossrefPubMedSuche in Google Scholar
• 8a Karuvalam RP, Haridas KR, Sajith AM, Pakkath R, Savitha B, Padusha MS. A, Bakulev VA, Joy MN. ARKIVOC 2019; (vi): 431
  Suche in Google Scholar
• 8b Savitha B, Reddy EK, Kumar CS. A, Karuvalam RP, Padusha MS. A, Bakulev VA, Narasimhamurthy KH, Sajith AM, Joy MN. Tetrahedron Lett. 2019; 60: 151332
  CrossrefSuche in Google Scholar
• 9 Weissman SA, Zewge D, Chen C. J. Org. Chem. 2005; 70: 1508
  CrossrefPubMedSuche in Google Scholar
• 10 Typical Experimental Procedure for the Synthesis of 3a To a pre-dried 10 mL screw cap equipped reaction vial, aryl pentafluorobenzenesulfonate (1h, 1 mmol), K₄Fe(CN)₆·3H₂O (2, 0.33 mmol, 0.33 equiv) and Na₂CO₃ (1 mmol, 1 equiv) were added, dissolved in dry DMF (3 mL), and degassed for 5 min. Pd(PPh₃)₄ (5 mol%) was then added, and the reaction mixture was heated in a pre-heated metal block at 40 ℃ for 3 h under continuous stirring. After the completion of the reaction, the reaction mixture was filtered through a short column using diethyl ether. The filtrate was distilled under reduced pressure, and the crude mixture was purified by column chromatography to afford the 3a (114 mg, 97%) as colorless liquid. ¹H NMR (400 MHz, CDCl₃): δ = 2.40 (s, 3 H, CH₃), 7.25 (d, J = 8 Hz, 2 H, ArH), 7.51 (d, J = 8 Hz, 2 H, ArH). ¹³C NMR (100 MHz, CDCl₃): δ = 23.7, 111.2, 121.0, 131.7, 133.9, 145.6.
• 11a Joy MN, Bodke YD, Khader KK. A, Sajith AM. Tetrahedron Lett. 2014; 55: 2355
  CrossrefSuche in Google Scholar
• 11b Joy MN, Bodke YD, Khader KK. A, Padusha MS. A, Sajith AM, Muralidharan A. RSC Adv. 2014; 4: 19766
  CrossrefSuche in Google Scholar
• 11c Joy MN, Bodke YD, Khader KK. A, Sajith AM, Venkatesh T, Kumar AK. A. J. Fluorine Chem. 2016; 182: 109
  CrossrefSuche in Google Scholar
• 11d Hickey S, Nitschke S, Sweetman MJ, Sumby CJ, Brooks DA, Plush SE, Ashton TD. J. Org. Chem. 2020; 85: 7986
  CrossrefPubMedSuche in Google Scholar
• 11e Joseph JT, Sajith AM, Ningegowda RC, Nagaraj A, Rangappa KS, Shashikanth S. Tetrahedron Lett. 2015; 56: 5106
  CrossrefSuche in Google Scholar
• 12a Joseph JT, Sajith AM, Ningegowda RC, Shashikanth S. Adv. Synth. Catal. 2017; 359: 419
  CrossrefSuche in Google Scholar
• 12b Raghu N, Savitha B, Sajith AM, Aswathanarayanappa C, Padusha MS. A, Shivananju NS, Priya BS. Aust. J. Chem. 2017; 70: 44
  CrossrefSuche in Google Scholar

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