Hydrogenolysis and Selective Reduction (Dehalogenation)

Mechanism + Description

Bonding of both the substrate and hydrogen to active sites on the metal facilitates cleavage of the carbon-heteroatom bond leading to generation of the phenol of the reduced carbon and other by-products.

General comments

Hydrogenolysis (the reductive cleavage of carbon – heteroatom bonds) is widely employed for the deprotection/cleavage of benzyl protecting groups (O and N), and to remove halogen atoms from aromatic/heteroaromatic compounds. Both classical hydrogenation and transfer hydrogenation can be utilised for hydrogenolysis. The catalyst is typically a heterogeneous precious metal, though occasionally base metals are used. Examples in this section will also highlight that by judicious choice of catalyst, additives, and reaction conditions, either multiple reducible groups can be transformed in a single operation (thus reducing step count), or selective reduction of one particular functional group in the presence of other reducible groups, which can be subsequently retained in the final structure or manipulated in downstream reactions.

Key references

See also the Nitro Reduction and O-dealkylation (specifically hydrogenolysis for O-debenzylation) guides.  

Ram, S.; Spicer, L. D. Debenzylation of N-Benzylamino Derivatives by Catalytic Transfer Hydrogenation With Ammonium Formate. Synth. Commun. 1987, 17 (4),  415–418.

Li, Y.; Manickam, G.; Ghoshal, A.; Subramaniam, P. More Efficient Palladium Catalyst for Hydrogenolysis of Benzyl Groups. Synth. Commun. 2006, 36 (7), 925–928.

Vincent, A.; Prunet, J. Selective Hydrogenolysis of Benzyl Ethers in the Presence of Benzylidene Acetals with Raney Nickel. Tetrahedron Lett. 2006, 47 (24), 4075–4077.

Sinfelt, J. H. Catalytic Hydrogenolysis over Supported Metals. Catal. Rev. 1970, 3 (1), 175–205.

Baltzly, R.; Russell, P. B. Catalytic Debenzylation. II. The Evaluation of the Relative Effect of Ring Substituents on the Stability of the N-Benzyl Linkage. J. Am. Chem. Soc. 1950, 72 (8), 3410–3413.

Song, J.; Huang, Z.-F.; Pan, L.; Li, K.; Zhang, X.; Wang, L.; Zou, J.-J. Review on selective hydrogenation of nitroarene by catalytic, photocatalytic and electrocatalytic reactions. Appl. Catal. B. 2018, 227, 386–408.

Agostini, G.; Lamberti, C.; Pellegrini, R.; Leofanti, G.; Giannici, F.; Longo, A.; Groppo, E. Effect of Pre-Reduction on the Properties and the Catalytic Activity of Pd/Carbon Catalysts: A Comparison with Pd/Al2O3. ACS Catal. 2014, 4 (1), 187–194.

Ambrüster, M.; Behrens, M.; Cinquini, F.; Föttinger, K.; Grin, Y.; Haghofer, A.; Klötzer, B.; Knop-Gericke, A.; Lorenz, H.; Ota, A.; Penner, S.; Prinz, J.; Rameshan, C.; Révay, Z.; Rosenthal, D.; Rupprechter, G.; Sautet, P.; Schlögl, R.; Shao, L.; Szentmiklósi, L.; Teschner, D.; Torres, D.; Wagner, R.; Widmer, R.; Wowsnick, G.  How to Control the Selectivity of Palladium-based Catalysts in Hydrogenation Reactions: The Role of Subsurface Chemistry. ChemCatChem 2012, 4 (8), 1048–1063.

Relevant scale up examples

Fujino, K.; Takami, H.; Atsumi, T.; Ogasa, T.; Mohri, S-I.; Kasai, M.Development of a Practical Synthetic Route of a PDE V Inhibitor KF31327. Org. Process Res. Dev. 2001, 5 (4), 426–433.
     

Allwein, S.P.; Roemmele, R.C.; Haley Jr., J. J.; Mowrey, D. R.; Petrillo, D. E.; Reif, J. J.; Gingrich, D. E.; Bakale, R. P. Development and Scale-Up of an Optimized Route to the ALK Inhibitor CEP-28122. Org. Process Res. Dev. 2012, 16 (1), 148−155.

Kowalczyk, B. A.; Robinson III, J.; Gardner, J. O. Process Development of the Synthetic Route to Sulamserod Hydrochloride. Org. Process Res. Dev. 2001, 5 (2), 116–121.

Green Review – Precious Metal Catalyst (PMC) and Base Metal (BM) Hydrogenation

1. Atom efficiency (by-products, molecular weight)
   With optimized catalytic efficiency, PMC/BM hydrogenation represents an atom efficient process generating only water and/or low MW by-products.
2. Safety Concerns
   Hydrogenation is a hazardous operation with the gas being highly flammable and capable of forming explosive mixtures with air. Catalytic transfer hydrogenation may avoid the need to handle H₂ gas, but it is important to note that many of these reactions generate H₂ in situ. Reduction of nitrobenzenes/alkynes/alkenes can be exothermic. Dry PMC and BM hydrogenation catalysts can be pyrophoric and are usually handled water-wet. Mixtures of solvent and catalyst in the presence of air can ignite. Appropriate care needs to be taken after processing in handling the spent-catalyst, which can often be recycled. Some Pt salts used as catalyst precursors are strong sensitizers while some Ni²⁺ salts are carcinogenic and are likely to be regulated under legislations such as REACH.
3. Toxicity and environmental/aquatic impact
   The chief concern herein is around solubilization and loss of precious metal/heavy metal catalysts into waste streams given that most PMC/BM levels are tightly regulated. The same applies to potential carry through into the final API (updated ICH guidelines for metal residues in APIs – hyperlink to final slide).  Some Ni salts are sensitizers and carcinogens and are listed on the EU SVAH list – echa.europa.eu/candidate-list-table (accessed August 30th, 2021) though this is of lesser concern for metallic hydrogenation catalysts.
4. Cost, availability & sustainable feedstocks
   H₂ is cheap, non-polluting and can be produced from renewable resources or through the electrolysis of water.
5. Sustainable implications
   All metals have a high LCA impact from mining and refining operations, so use should be catalytic with efficient recovery and recycle. Pd is most used precious metal for hydrogenolysis and this is rated at high risk of depletion. Platinum group elements (Pt, Ru, Pd, Os, and Ir) are flagged as having a high relative supply risk index value (2015 British Geological Survey Risk list – accessed 30th August 2021). There is no concern for abundant base metals like Ni, Cu, Co and Fe.

Green Review – Transfer Hydrogenation with PMC and Base Metals (BM)

1. Atom efficiency (by-products, molecular weight)
   Varies from good to poor depending on both the MW and stoichiometry (excess equivalents) used of the donor that is employed. The by-products are water, the oxidized donor, and related by-products (for example – 2-propanol/acetone, hydrazine/N₂, cyclohexene/benzene, formate/CO₂ etc). Occasionally large excesses of donors are used due to either generate excess H₂ to mitigate against loss, or to increase reaction rate.
2. Safety Concerns
   Caution around the use of pyrophoric metal catalysts as per hydrogenation with H₂ gas. In addition, systems often produce H₂ gas leading to a potentially flammable atmosphere above the reaction. There are several safety attributes of specific individual donors and the by-products they generate that warrant consideration, for example, hydrazine, boric acid, and benzene are all potential carcinogens while borohydride will generate hydrogen gas upon quenching. Safety data (SDS) on the individual components of a proposed hydrogen transfer reaction should be inspected prior to carrying out the reaction.
3. Toxicity and environmental/aquatic impact
   Generally good – ammonia and phosphate may cause issues with discharge into water while higher MW terpenes and siloxanes may bioaccumulate.
4. Cost, availability & sustainable feedstocks
   Most H₂ donor molecules are readily available and cheap. In addition, several H₂ donors can be obtained from sustainable/biorenewable sources (2-propanol, formate, terpenes).

5. Sustainable implications
   All metals have a high LCA impact from mining and refining operations, so use should be catalytic with efficient recovery and recycle. Pd is most used precious metal for hydrogenolysis and this is rated at high risk of depletion. Platinum group elements (Pt, Ru, Pd, Os, and Ir) are flagged as having a high relative supply risk index value (2015 British Geological Survey Risk list – accessed 30th August 2021).