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molecular formula C24H29NO3 B133215 Donepezil CAS No. 142057-79-2

Donepezil

Cat. No. B133215
M. Wt: 379.5 g/mol
InChI Key: ADEBPBSSDYVVLD-UHFFFAOYSA-N
Attention: For research use only. Not for human or veterinary use.
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Patent
US08124783B2

Procedure details

There are many processes as disclosed in the prior arts for producing donepezil of formula 1. U.S. Pat. No. 4,895,841 wherein substituted 1-indanone-2-phosphonate prepared from 2-bromo-5,6-dimethoxyindanone and triethyl phosphite, is treated with 1-benzylpiperidine-4-carboxaldehyde in the presence of a strong base, such as lithium diisopropylamide (LDA), followed by catalytic reduction using palladium on carbon in tetrahydrofuran (40 volumes) to yield donepezil with an overall yield of 50.8%. This process however suffers with few limitations i.e. it employs triphenylphosphonium methoxymethyl chloride, which is expensive and toxic and the overall yield of this process is quite low. (scheme 1).
[Compound]
Name
substituted 1-indanone-2-phosphonate
Quantity
0 (± 1) mol
Type
reactant
Reaction Step One
Quantity
0 (± 1) mol
Type
reactant
Reaction Step One
Quantity
0 (± 1) mol
Type
reactant
Reaction Step One
Quantity
0 (± 1) mol
Type
reactant
Reaction Step Two
Quantity
0 (± 1) mol
Type
reactant
Reaction Step Two
Quantity
0 (± 1) mol
Type
catalyst
Reaction Step Three
Quantity
0 (± 1) mol
Type
solvent
Reaction Step Four
Yield
50.8%

Identifiers

REACTION_CXSMILES
Br[CH:2]1[CH2:10][C:9]2[C:4](=[CH:5][C:6]([O:13][CH3:14])=[C:7]([O:11][CH3:12])[CH:8]=2)[C:3]1=[O:15].P(OCC)(OCC)OCC.[CH2:26]([N:33]1[CH2:38][CH2:37][CH:36]([CH:39]=O)[CH2:35][CH2:34]1)[C:27]1[CH:32]=[CH:31][CH:30]=[CH:29][CH:28]=1.C([N-]C(C)C)(C)C.[Li+]>[Pd].O1CCCC1>[CH3:12][O:11][C:7]1[CH:8]=[C:9]2[CH2:10][CH:2]([CH2:39][CH:36]3[CH2:35][CH2:34][N:33]([CH2:26][C:27]4[CH:28]=[CH:29][CH:30]=[CH:31][CH:32]=4)[CH2:38][CH2:37]3)[C:3](=[O:15])[C:4]2=[CH:5][C:6]=1[O:13][CH3:14] |f:3.4|

Inputs

Step One
Name
substituted 1-indanone-2-phosphonate
Quantity
0 (± 1) mol
Type
reactant
Smiles
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
BrC1C(C2=CC(=C(C=C2C1)OC)OC)=O
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
P(OCC)(OCC)OCC
Step Two
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
C(C1=CC=CC=C1)N1CCC(CC1)C=O
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
C(C)(C)[N-]C(C)C.[Li+]
Step Three
Name
Quantity
0 (± 1) mol
Type
catalyst
Smiles
[Pd]
Step Four
Name
Quantity
0 (± 1) mol
Type
solvent
Smiles
O1CCCC1

Conditions

Other
Conditions are dynamic
1
Details
See reaction.notes.procedure_details.

Outcomes

Product
Name
Type
product
Smiles
COC=1C=C2C(=CC1OC)C(=O)C(C2)CC3CCN(CC3)CC=4C=CC=CC4
Measurements
Type Value Analysis
YIELD: PERCENTYIELD 50.8%

Source

Source
Open Reaction Database (ORD)
Description
The Open Reaction Database (ORD) is an open-access schema and infrastructure for structuring and sharing organic reaction data, including a centralized data repository. The ORD schema supports conventional and emerging technologies, from benchtop reactions to automated high-throughput experiments and flow chemistry. Our vision is that a consistent data representation and infrastructure to support data sharing will enable downstream applications that will greatly improve the state of the art with respect to computer-aided synthesis planning, reaction prediction, and other predictive chemistry tasks.
Patent
US08124783B2

Procedure details

There are many processes as disclosed in the prior arts for producing donepezil of formula 1. U.S. Pat. No. 4,895,841 wherein substituted 1-indanone-2-phosphonate prepared from 2-bromo-5,6-dimethoxyindanone and triethyl phosphite, is treated with 1-benzylpiperidine-4-carboxaldehyde in the presence of a strong base, such as lithium diisopropylamide (LDA), followed by catalytic reduction using palladium on carbon in tetrahydrofuran (40 volumes) to yield donepezil with an overall yield of 50.8%. This process however suffers with few limitations i.e. it employs triphenylphosphonium methoxymethyl chloride, which is expensive and toxic and the overall yield of this process is quite low. (scheme 1).
[Compound]
Name
substituted 1-indanone-2-phosphonate
Quantity
0 (± 1) mol
Type
reactant
Reaction Step One
Quantity
0 (± 1) mol
Type
reactant
Reaction Step One
Quantity
0 (± 1) mol
Type
reactant
Reaction Step One
Quantity
0 (± 1) mol
Type
reactant
Reaction Step Two
Quantity
0 (± 1) mol
Type
reactant
Reaction Step Two
Quantity
0 (± 1) mol
Type
catalyst
Reaction Step Three
Quantity
0 (± 1) mol
Type
solvent
Reaction Step Four
Yield
50.8%

Identifiers

REACTION_CXSMILES
Br[CH:2]1[CH2:10][C:9]2[C:4](=[CH:5][C:6]([O:13][CH3:14])=[C:7]([O:11][CH3:12])[CH:8]=2)[C:3]1=[O:15].P(OCC)(OCC)OCC.[CH2:26]([N:33]1[CH2:38][CH2:37][CH:36]([CH:39]=O)[CH2:35][CH2:34]1)[C:27]1[CH:32]=[CH:31][CH:30]=[CH:29][CH:28]=1.C([N-]C(C)C)(C)C.[Li+]>[Pd].O1CCCC1>[CH3:12][O:11][C:7]1[CH:8]=[C:9]2[CH2:10][CH:2]([CH2:39][CH:36]3[CH2:35][CH2:34][N:33]([CH2:26][C:27]4[CH:28]=[CH:29][CH:30]=[CH:31][CH:32]=4)[CH2:38][CH2:37]3)[C:3](=[O:15])[C:4]2=[CH:5][C:6]=1[O:13][CH3:14] |f:3.4|

Inputs

Step One
Name
substituted 1-indanone-2-phosphonate
Quantity
0 (± 1) mol
Type
reactant
Smiles
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
BrC1C(C2=CC(=C(C=C2C1)OC)OC)=O
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
P(OCC)(OCC)OCC
Step Two
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
C(C1=CC=CC=C1)N1CCC(CC1)C=O
Name
Quantity
0 (± 1) mol
Type
reactant
Smiles
C(C)(C)[N-]C(C)C.[Li+]
Step Three
Name
Quantity
0 (± 1) mol
Type
catalyst
Smiles
[Pd]
Step Four
Name
Quantity
0 (± 1) mol
Type
solvent
Smiles
O1CCCC1

Conditions

Other
Conditions are dynamic
1
Details
See reaction.notes.procedure_details.

Outcomes

Product
Name
Type
product
Smiles
COC=1C=C2C(=CC1OC)C(=O)C(C2)CC3CCN(CC3)CC=4C=CC=CC4
Measurements
Type Value Analysis
YIELD: PERCENTYIELD 50.8%

Source

Source
Open Reaction Database (ORD)
Description
The Open Reaction Database (ORD) is an open-access schema and infrastructure for structuring and sharing organic reaction data, including a centralized data repository. The ORD schema supports conventional and emerging technologies, from benchtop reactions to automated high-throughput experiments and flow chemistry. Our vision is that a consistent data representation and infrastructure to support data sharing will enable downstream applications that will greatly improve the state of the art with respect to computer-aided synthesis planning, reaction prediction, and other predictive chemistry tasks.
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