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Chemistry
Organic Building Blocks
Aryls
benzyl
tert-Butyl ((2S,3R)-4-chloro-3-hydroxy-1-phenylbutan-2-yl)carbamate
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benzyl

[ CAS No. 162536-40-5 ] {[proInfo.proName]}

,{[proInfo.pro_purity]}
Cat. No.: {[proInfo.prAm]}
Chemical Structure| 162536-40-5
Chemical Structure| 162536-40-5
Structure of 162536-40-5 * Storage: {[proInfo.prStorage]}
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Quality Control of [ 162536-40-5 ]

COA NMR CNMR HPLC LC-MS

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SDS Specification
Alternatived Products of [ 162536-40-5 ]

Product Details of [ 162536-40-5 ]

CAS No. :162536-40-5 MDL No. :MFCD01317802
Formula : C15H22ClNO3 Boiling Point : -
Linear Structure Formula :- InChI Key :GFGQSTIUFXHAJS-STQMWFEESA-N
M.W : 299.79 Pubchem ID :9944139
Synonyms :

Calculated chemistry of [ 162536-40-5 ]

Physicochemical Properties

Num. heavy atoms : 20
Num. arom. heavy atoms : 6
Fraction Csp3 : 0.53
Num. rotatable bonds : 8
Num. H-bond acceptors : 3.0
Num. H-bond donors : 2.0
Molar Refractivity : 80.34
TPSA : 58.56 Ų

Pharmacokinetics

GI absorption : High
BBB permeant : Yes
P-gp substrate : Yes
CYP1A2 inhibitor : No
CYP2C19 inhibitor : No
CYP2C9 inhibitor : No
CYP2D6 inhibitor : No
CYP3A4 inhibitor : No
Log Kp (skin permeation) : -6.06 cm/s

Lipophilicity

Log Po/w (iLOGP) : 2.84
Log Po/w (XLOGP3) : 2.92
Log Po/w (WLOGP) : 2.72
Log Po/w (MLOGP) : 2.57
Log Po/w (SILICOS-IT) : 2.83
Consensus Log Po/w : 2.78

Druglikeness

Lipinski : 0.0
Ghose : None
Veber : 0.0
Egan : 0.0
Muegge : 0.0
Bioavailability Score : 0.55

Water Solubility

Log S (ESOL) : -3.23
Solubility : 0.176 mg/ml ; 0.000586 mol/l
Class : Soluble
Log S (Ali) : -3.81
Solubility : 0.0463 mg/ml ; 0.000155 mol/l
Class : Soluble
Log S (SILICOS-IT) : -4.29
Solubility : 0.0156 mg/ml ; 0.0000519 mol/l
Class : Moderately soluble

Medicinal Chemistry

PAINS : 0.0 alert
Brenk : 1.0 alert
Leadlikeness : 1.0
Synthetic accessibility : 3.33

Safety of [ 162536-40-5 ]

Signal Word:Warning Class:N/A
Precautionary Statements:P261-P305+P351+P338 UN#:N/A
Hazard Statements:H302-H315-H319-H335 Packing Group:N/A
GHS Pictogram:

Application In Synthesis of [ 162536-40-5 ]

* All experimental methods are cited from the reference, please refer to the original source for details. We do not guarantee the accuracy of the content in the reference.

  • Downstream synthetic route of [ 162536-40-5 ]

[ 162536-40-5 ] Synthesis Path-Downstream   1~33

  • 1
  • [ 102123-74-0 ]
  • [ 165727-45-7 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
With hydrogen;Ru(S-P-Phos)Cl2(dmf)2; In methanol; at 65℃; under 15001.5 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; A series of experiments were carried out with the following ligands coordinated to ruthenium:; Some results of this study are shown in Table 1:; Table 1EntryCatalystT (°C)P(bar)Conv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-Xyl-P-Phos)(acac)250io51822R.3S2Ru (S-P-Phos) Cl2 (dmf)2652089792R,3SReaction conditions: 1mmol substrate, S/C ratio = 100/1, 4mL MeOH, unoptimized reaction time 20 hrs.
With hydrogen;(R)-[RuCI2(BINAP)]n; In ethanol; at 55℃; under 3361.55 Torr; for 16h;Parr autoclave;Product distribution / selectivity; The reduction of BocChloroketone with a BINAP catalyst (R)-[RuCI2(BINAP)]n at 4.5bar hydrogen (65psi) at 55°C in ethanol, substrate/catalyst ratiol000:1 gave negligible reaction after 16h. 97.4percent starting material, 1.05percent product, de 58percent in favour of R,S (dr 3.8:1). The result suggests that Ru-BINAP is not an efficient catalyst for this conversion and the selectivity is poor.
With hydrogen;[Rh(R-PCyCo-BoPhoz)(COD)]OTf; In ethanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-PCyCo-BoPhoz)(COD)]OTf; In isopropyl alcohol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-PCyCo-BoPhoz)(COD)]OTf; In ethanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-PCyCo-BoPhoz)(COD)]OTf; In 1,2-dichloro-ethane; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-PCyCo-BoPhoz)(COD)]OTf; In tetrahydrofuran; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-PCyCo-BoPhoz)(COD)]OTf; In methanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;(Rp)-pseudo-o-bis(di(3,5-dimethylphenyl)phosphino)[2.2]paracyclophane; bis(cycloocta-1,5-diene)rhodium(I) trifluoromethanesulfonate; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 18:Table 18EntryRh precursorConv(percent) (HPLC)Product (HPLC)d.e (percent)config1[Rh(NBD)2]BF49961^ 2R,3S2[Rh("COD)2pTf10077h2R,3S3[Rh(ethylene)2cF|29245h2R,3S4[Rh(ethyiene)2(acac)j87h 46h 2R.3S5rRh(C6j2"(OA"CJJ2431 48t 2R,3SaReaction conditions: 1mmol substrate, catalyst generated in situ from the corresponding Rh precursor and R-Xyl-PhanePhos. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;(Rp)-pseudo-o-bis(di(3,5-dimethylphenyl)phosphino)[2.2]paracyclophane; bis(ethylene)rhodium acetylacetonate; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 18:Table 18EntryRh precursorConv(percent) (HPLC)Product (HPLC)d.e (percent)config1[Rh(NBD)2]BF49961^ 2R,3S2[Rh("COD)2pTf10077h2R,3S3[Rh(ethylene)2cF|29245h2R,3S4[Rh(ethyiene)2(acac)j87h 46h 2R.3S5rRh(C6j2"(OA"CJJ2431 48t 2R,3SaReaction conditions: 1mmol substrate, catalyst generated in situ from the corresponding Rh precursor and R-Xyl-PhanePhos. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Xyl-PhanePhos)(NBD)]BF4; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for initial experimental studies.OMe OMeMeO' ^"PPh2 MeO MeO^^k ^PPh2 MeOPXyl2 PXyl2Ph2P PPh2i iNHPPh2 NHPPh2H 00OMe Xyl-P-PhosH8-BINAMPSpirOPPhanephos Xyl-Phanephos MeOXyl-Phanephos Cy-Phanephos'Pr-Phanepho"'."jf ,--'""N.^MeO^^P'Pr2 FeDIPFcMe-DUPHOSMeODIPAMPSome results of this study are shown in Table 14.Table 14EntryCatalyst(°C)P(bar)Conv (percent) (HPLC)Product . (HPLC)d.econfig1[Rh(R-Xyl-PhanePhos)(NBD)]BF4501096502R.3S2[Rh(S-MeOXyl-PhanePhos)(NBD)]BF45010100562R.3S3[Rh(R-Me-DuPhos)(COD)]OTf501015682R.3S4[Rh(R-SpirOP)(NBD)]BF4501011842R.3SReaction conditions: 1mmol substrate, S/C ratio = 100/1, 4ml_ MeOH, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-MeOXyl-PhanePhos)(NBD)]BF4; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for initial experimental studies.OMe OMeMeO' ^"PPh2 MeO MeO^^k ^PPh2 MeOPXyl2 PXyl2Ph2P PPh2i iNHPPh2 NHPPh2H 00OMe Xyl-P-PhosH8-BINAMPSpirOPPhanephos Xyl-Phanephos MeOXyl-Phanephos Cy-Phanephos'Pr-Phanepho"'."jf ,--'""N.^MeO^^P'Pr2 FeDIPFcMe-DUPHOSMeODIPAMPSome results of this study are shown in Table 14.Table 14EntryCatalyst(°C)P(bar)Conv (percent) (HPLC)Product . (HPLC)d.econfig1[Rh(R-Xyl-PhanePhos)(NBD)]BF4501096502R.3S2[Rh(S-MeOXyl-PhanePhos)(NBD)]BF45010100562R.3S3[Rh(R-Me-DuPhos)(COD)]OTf501015682R.3S4[Rh(R-SpirOP)(NBD)]BF4501011842R.3SReaction conditions: 1mmol substrate, S/C ratio = 100/1, 4ml_ MeOH, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Me-DuPhos)(COD)]OTf; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for initial experimental studies.OMe OMeMeO' ^"PPh2 MeO MeO^^k ^PPh2 MeOPXyl2 PXyl2Ph2P PPh2i iNHPPh2 NHPPh2H 00OMe Xyl-P-PhosH8-BINAMPSpirOPPhanephos Xyl-Phanephos MeOXyl-Phanephos Cy-Phanephos'Pr-Phanepho"'."jf ,--'""N.^MeO^^P'Pr2 FeDIPFcMe-DUPHOSMeODIPAMPSome results of this study are shown in Table 14.Table 14EntryCatalyst(°C)P(bar)Conv (percent) (HPLC)Product . (HPLC)d.econfig1[Rh(R-Xyl-PhanePhos)(NBD)]BF4501096502R.3S2[Rh(S-MeOXyl-PhanePhos)(NBD)]BF45010100562R.3S3[Rh(R-Me-DuPhos)(COD)]OTf501015682R.3S4[Rh(R-SpirOP)(NBD)]BF4501011842R.3SReaction conditions: 1mmol substrate, S/C ratio = 100/1, 4ml_ MeOH, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-Et-BoPhoz)(COD)]OTf; In ethanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-Et-BoPhoz)(COD)]OTf; In tetrahydrofuran; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Xyl-PhanePhos)(COD)]OTf; In butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 17.Table 17EntryLigandSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1(R-Xyl-PhanePhos)MeOH100632R,3S2(R-Xyl-PhanePhos)EtOH100772R,3S3(R-Xyl-PhanePhos)10percentH2O-EtOH100802R,3S4(R-Xyl-PhanePhos)1-BuOH100792R,3S5(R-Xyl-PhanePhos)10percent H20-BuOH100842R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Xyl-PhanePhos)(COD)]OTf; In ethanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 17.Table 17EntryLigandSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1(R-Xyl-PhanePhos)MeOH100632R,3S2(R-Xyl-PhanePhos)EtOH100772R,3S3(R-Xyl-PhanePhos)10percentH2O-EtOH100802R,3S4(R-Xyl-PhanePhos)1-BuOH100792R,3S5(R-Xyl-PhanePhos)10percent H20-BuOH100842R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Xyl-PhanePhos)(COD)]OTf; In methanol; at 50 - 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for experimental studies:PV ,Ph PPPh2Phv fh P,PPh2 -EtPh PPh PCy2Ph. fhPPh,OY~Me ^MN~Et 0-AEt ^AHFeFeFeFeMeBoPhozEtBoPhozPCycoBoPhozProBoPhozSome results of this study are shown in Table 15.Table 15EntryLigandSolventConv(percent) (HPLC)Product (HPLC).d:e (percent) J .cqnfjg1lS-Me:BoPhc)z)MeOH98722R,3S(S-Et-BoPhoz)MeOH94832R,3SIR-Xy^PhjmePhos^MeOH10059 2R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL MeOH, 65°C, 10 bar, unoptimized reaction time 20 hrs.; Example 17Influence of the solvent on the hvdrogenation of BocChloroketone in the presence of fRh(COD21QTf/Xvl-PhanePhos systemsSome results of this study are shown in Table 17.Table 17EntryLigandSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1(R-Xyl-PhanePhos)MeOH100632R,3S2(R-Xyl-PhanePhos)EtOH100772R,3S3(R-Xyl-PhanePhos)10percentH2O-EtOH100802R,3S4(R-Xyl-PhanePhos)1-BuOH100792R,3S5(R-Xyl-PhanePhos)10percent H20-BuOH100842R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Et-BoPhoz)(COD)]OTf; In 1,2-dichloro-ethane; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Et-BoPhoz)(COD)]OTf; In methanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;(Rp)-pseudo-o-bis(di(3,5-dimethylphenyl)phosphino)[2.2]paracyclophane; diacetatetetracarbonyl dirhodium(I); at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 18:Table 18EntryRh precursorConv(percent) (HPLC)Product (HPLC)d.e (percent)config1[Rh(NBD)2]BF49961^ 2R,3S2[Rh("COD)2pTf10077h2R,3S3[Rh(ethylene)2cF|29245h2R,3S4[Rh(ethyiene)2(acac)j87h 46h 2R.3S5rRh(C6j2"(OA"CJJ2431 48t 2R,3SaReaction conditions: 1mmol substrate, catalyst generated in situ from the corresponding Rh precursor and R-Xyl-PhanePhos. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;(Rp)-pseudo-o-bis(di(3,5-dimethylphenyl)phosphino)[2.2]paracyclophane; bis(ethylene)rhodium(I) chloride dimer; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 18:Table 18EntryRh precursorConv(percent) (HPLC)Product (HPLC)d.e (percent)config1[Rh(NBD)2]BF49961^ 2R,3S2[Rh("COD)2pTf10077h2R,3S3[Rh(ethylene)2cF|29245h2R,3S4[Rh(ethyiene)2(acac)j87h 46h 2R.3S5rRh(C6j2"(OA"CJJ2431 48t 2R,3SaReaction conditions: 1mmol substrate, catalyst generated in situ from the corresponding Rh precursor and R-Xyl-PhanePhos. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;(Rp)-pseudo-o-bis(di(3,5-dimethylphenyl)phosphino)[2.2]paracyclophane; rhodium(I)-bis(1,5-cyclooctadiene) tetrafluoroborate; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 18:Table 18EntryRh precursorConv(percent) (HPLC)Product (HPLC)d.e (percent)config1[Rh(NBD)2]BF49961^ 2R,3S2[Rh("COD)2pTf10077h2R,3S3[Rh(ethylene)2cF|29245h2R,3S4[Rh(ethyiene)2(acac)j87h 46h 2R.3S5rRh(C6j2"(OA"CJJ2431 48t 2R,3SaReaction conditions: 1mmol substrate, catalyst generated in situ from the corresponding Rh precursor and R-Xyl-PhanePhos. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-Me-BoPhoz)(COD)]OTf; In methanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for experimental studies:PV ,Ph PPPh2Phv fh P,PPh2 -EtPh PPh PCy2Ph. fhPPh,OY~Me ^MN~Et 0-AEt ^AHFeFeFeFeMeBoPhozEtBoPhozPCycoBoPhozProBoPhozSome results of this study are shown in Table 15.Table 15EntryLigandSolventConv(percent) (HPLC)Product (HPLC).d:e (percent) J .cqnfjg1lS-Me:BoPhc)z)MeOH98722R,3S(S-Et-BoPhoz)MeOH94832R,3SIR-Xy^PhjmePhos^MeOH10059 2R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL MeOH, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With isopropyl alcohol;aluminum tri-tert-butoxide; In ethyl acetate;Inert atmosphere;Product distribution / selectivity; The MPV reduction was conducted in various organic solvents as described in Example 3, where the solvent of interest was used in the place of toluene. Isopropanol (10percent) was added to each solvent for the reaction to proceed in a reasonable time.Table 1 shows the results of these reactions. The (R,S)/(S,S) ratio increased when the reaction was run in aprotic polar solvents like ethyl acetate and THF. While not limiting any embodiment by theory, it is believed that the hydrogen bonding between ketone 1 and Al(OiPr)3 may contribute to increasing the rate of reaction by keeping 1 coordinated with the aluminum center, bringing to close proximity the two reactive centers.Table 1. MPV reduction of 1 in various organic solvents

Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
[2]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
[3]Journal of Organic Chemistry,2004,vol. 69,p. 7344 - 7347
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[5]Journal of Organic Chemistry,2004,vol. 69,p. 7391 - 7394
[6]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-16
[7]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 26
[8]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[9]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[10]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[11]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[12]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[13]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[14]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 32-33
[15]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 32-33
[16]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 29-30
[17]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 29-30
[18]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 29-30
[19]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[20]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[21]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31-32
[22]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31-32
[23]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 30-32
[24]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[25]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31
[26]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 32-33
[27]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 32-33
[28]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 32-33
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  • 2
  • [ 162536-40-5 ]
  • [ 98760-08-8 ]
YieldReaction ConditionsOperation in experiment
93% With sodium hydroxide; In water; isopropyl alcohol; at 0℃; for 4h;Product distribution / selectivity; To (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (45.1 g) obtained in Example 3 were added isopropanol (120 ml) and water (45 ml), and the mixture was cooled to 0C. 29%. Aqueous sodium hydroxide solution was added, and the mixture was stirred for 4 hours. Aqueous citric acid solution (a mixed solution of citric acid (6.73 g) and water (14 ml)) was added to the reaction mixture, and acetone (35 ml) and water (59.5 ml) were further added. A seed crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane was added, and this mixture was stirred for 1 hour. Water (200 ml) was added dropwise to the mixture over 1 hour, and the mixture was stirred overnight. The slurry solution was filtered, and the crystals were washed twice with aqueous acetone solution (a mixed solution of acetone (50 ml) and water (350 ml)). Wet crystals were dried under reduced pressure at room temperature to give (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane as white crystals (37.1 g, 100 wt%, yield 93%). As a result of HPLC analysis, it was found that the peak area ratio of the compound was 99.9%, and the diastereomer ((2S,3S)-form) was not detected.
83% With sodium hydroxide; In water; isopropyl alcohol; at 0℃; for 8.5h;Product distribution / selectivity; The organic layer (26.5 g) obtained in Comparative Example 2, step (2'g), was concentrated under reduced pressure, isopropanol (2 ml) was added to the residue, and the mixture was concentrated again to dryness. Isopropanol (21.8 ml) and water (3.0 ml) were added to the residue and the mixture was cooled to 0C. Then, 6 M aqueous sodium hydroxide solution (2.7 ml) and water (1.2 ml) were added to the solution, and the mixture was reacted for 8.5 hours. An aqueous solution (36.6 ml) of citric acid (351 mg) was added to the reaction mixture, and the mixture was cooled from 0C to -10C over 3 hours. A seed crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane was added, and the mixture was stirred at -10C for 3 days and filtered. The obtained crystals were dried under reduced pressure to give adhesive orange crystals (2.47 g). As a result of HPLC analysis, it was found that the content of the object compound, (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane, was 2.07 g, 83.8 wt%, and the yield was 83%. In addition, the crystals contained 0.071 g of a diastereomer ((2S,3S)-form)), and the diastereomer ratio (2R,3S)/(2S,3S) was 96.7/3.3. Moreover, the peak area ratio of other byproduct was 10% relative to the object compound, (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane.
81.4 mg (93.5%) With potassium carbonate; citric acid; In methanol; water; ethyl acetate; Example 6 Production of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (100 mg) and potassium carbonate (91.5 mg) were added to methanol (2.0 ml) for agitation at ambient temperature for 4 hours. Aqueous 10% citric acid solution (0.204 ml) and water (0.408 ml) were added to the resulting mixture, from which the solvent was evaporated under reduced pressure. To the residue were added water (1 ml) and ethyl acetate (1 ml) for extraction; the organic phase was concentrated under reduced pressure, to afford (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane {(2R,3S) yield: 81.4 mg (93.5%)}. 1H-NMR (CDCl3, 300 MHz) delta ppm: 1.38 (s, 9H), 2.59 (bs, 1H), 2.69 (t. J=4.4 Hz, 1H), 2.83-3.04 (m, 3H), 4.12 (bs, 1H), 4.48 (bs, 1H), 7.17-7.37 (m, 5H) Mass spectrum m/e: 286 (M+Na+)
191 mg (71.6%) With potassium carbonate; citric acid; In ethanol; water; Example 7 Production of crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane To (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane {(2R,3S) content of 300 mg; (2S,3S) content of 6.67 mg} obtained in the same manner as in Example 1 were added ethanol (3.40 ml), water (0.109 ml) and potassium carbonate (755 mg), for agitation at ambient temperature for 5 hours and further agitation at 30 C. for one hour. After cooling to 5 C., aqueous 17.5% citric acid solution (3.99 g) was added. After phase separation at 0 C., the ethanol layer was cooled to -10 C., followed by addition of the seed crystal and overnight agitation, to crystallize (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane. The resulting slurry was filtered, to afford (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane. {(2R,3S) yield: 191 mg (71.6%) The dried crystal was analyzed by HPLC. (2R,3S): (2S,3S)-96.8:3.2.
64.2 mg (75%) With sodium hydroxide; In water; acetone; Example 8 Production of crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane Acetone (0.8 ml) and aqueous 2.5 mol/l sodium hydroxide solution (0.2 ml) were added to (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane {(2R,3S) content of 97.8 mg; (2S,3S) content of 2.2 mg} obtained in the same manner as in Example 1, for agitation at ambient temperature for 2 hours and 50 minutes. The resulting mixture was separated into phases. To the resulting acetone layer was added water (1.18 ml), which was then cooled to -10 C., followed by addition of the seed crystal and overnight agitation, to crystallize (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane. The resulting slurry was filtered, to recover the crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane {(2R,3S) yield: 64.2 mg (75%)}. The dried crystal was analyzed by HPLC. (2R,3S): (2S,3S)=97.9:2.1.

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[2]Patent: US6344572,2002,B1 .Location in patent: Page column 10-11
[3]Patent: EP1777213,2007,A1 .Location in patent: Page/Page column 21
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[5]Patent: EP1777213,2007,A1 .Location in patent: Page/Page column 21
[6]Patent: US2002/72621,2002,A1
[7]Patent: US2002/72621,2002,A1
[8]Patent: US2002/72621,2002,A1
  • 3
  • [ 102123-74-0 ]
  • [ 165727-45-7 ]
  • [ 162536-40-5 ]
  • (1R,2R)[3-chloro-2-hydroxy-1-(phenylmethyl)propyl]carbamic acid 1,1-dimethylethyl ester [ No CAS ]
  • [ 923601-69-8 ]
Reference: [1]Journal of the American Oil Chemists' Society,1999,vol. 76,p. 1275 - 1281
  • 4
  • [ 102123-74-0 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
The quality of (2R,3S)-1-chloro-2-hydroxy-3-N-(tert- butoxycarbonyl)amino-4-phenylbutane before treatment (after concentration to dryness in vacuo) Purity: 96.8 weight percent (2R,3S) compound/((2R,3S) compound + (2S,3S) compound): 99.7percent (3S)-1-Chloro-2-oxo-3-N-(tert-butoxycarbonyl)amino-4-phenylbutane content: 1.4 area percent
With hydrogen;Ru(S-Xyl-P-Phos)(acac)2; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; A series of experiments were carried out with the following ligands coordinated to ruthenium:; Some results of this study are shown in Table 1:; Table 1EntryCatalystT (°C)P(bar)Conv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-Xyl-P-Phos)(acac)250io51822R.3S2Ru (S-P-Phos) Cl2 (dmf)2652089792R,3SReaction conditions: 1mmol substrate, S/C ratio = 100/1, 4mL MeOH, unoptimized reaction time 20 hrs.
With hydrogenchloride; hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In water; butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;dichloro(benzene)ruthenium(II) dimer; C43H40FeNP2; In ethanol; at 55℃; under 4500.45 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Further screening was carried out using the following ligands:In a 10ml Schlenk flask (set under an atmosphere of argon) metal precursor (1 equiv) and ligand (1.05 equivalents) were placed and dissolved in 1 ml of freshly distilled solvent. The solution was stirred at room temperature for 30 minutes. BOC Chloroketone was dissolved in solvent to give a 0.5M solution in a tube suitable for parallel screening. The catalyst solution was transferred into the tube and placed in parallel reactor. The autoclave was closed, set under the desired hydrogen pressure and temperature was adjusted to the desired value. After the given reaction time, the reaction was stopped and a sample of the reaction mixture was diluted and directly analyzed by HPLC. Some results of this study are shown in Table 13.Table 13S/cMetalLigandAbs ConfSolt (h)P (bar)T °CProdsmde1250Ru"A(R)-(S)EtOH20655100092percent2250Ru*B(R)-(S)EtOH1866595590percent3100Ru*C(S)-(R)EtOH184062901096percent4250Ru*D(R)EtOH184062712996percentRu* [RuCI2(p-cymene)]2 RuUSD [Rul2(p-cymene)]2
With hydrogen;(R)MeBoPhoz-RuCl2-PPh3; sodium acetate; In ethanol; at 55℃; under 7498.84 Torr; for 18h;Endeavor catalyst system;Product distribution / selectivity; The Some results of study of effect of additives on the reaction are summarised in Tables 8, 8a and 8bTable 8 Asymmetric Hydrogenation of BocChloroketone using (R)MeBoPhoz-RuCI2-PPh3 with different additives (20 molpercent)Entry _ Additive Conv. (percent) de (percent)~1.........."........."................~ .................~...........">98.............. ~93~........2 MgBr2.OEt 75 93.53 NH4CI 60 934 Na(C02CF3) >99 93C5 Ag(OTf)2 31 906 AgBF4 157 NaOAc 16.5 83a Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2 (145 psi), 55 °C, 18 hrs. Conversion and de measured by chiral HPLC.c reaction complete after 5 hrs.
With hydrogen;(R)MeBoPhoz-RuCl2-dmf; sodium 2,2,2-trifluoroacetate; In ethanol; at 55℃; under 7498.84 Torr; for 18h;Endeavor catalyst system;Product distribution / selectivity; Table 8a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with different levels of sodium trifluoroacetate as additive.3Entry CatalystNa(C02CF3) Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2- PPh3234567 p-F-Ph-(f?)MeBoPhoz-RuCI2-dmf8(molpercent)-7392.5599931097932090915081.59010044872.5>9993.55>9993.5Reaction conditions: Endeavor catalyst system; s/c 1000, 12h, EtOH (2 ml/mmol), H2 (145 psi), 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.Table 8b. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with sodium trifluoroacetate as additive under different conditions.3EntryCatalystNa(TFA):S/cTempConv.deCatalyst(°C)(percent)(percent)1(/?)MeBoPhoz-RuCI2-dmf-10005582922u25:11000559892.43a50:110005599944p-F-Ph-(/?)MeBoPhoz-RuCI2-dmf25:11000559994525:11000459994625:11000359394725:11500559994825:12000559894950:120005578941025:12500559592a Reaction conditions: Endeavor catalyst system; 18h, EtOH (2 ml/mmol), H2 (145 psi), Na(TFA):Catalyst molar ratio. Conversion analysed by HPLC, de measured by chiral HPLC.
With hydrogen;(R)MeBoPhoz-RuCl2-PPh3; sodium 2,2,2-trifluoroacetate; In ethanol; at 55℃; under 7498.84 Torr; for 5 - 12h;Endeavor catalyst system;Product distribution / selectivity; The Some results of study of effect of additives on the reaction are summarised in Tables 8, 8a and 8bTable 8 Asymmetric Hydrogenation of BocChloroketone using (R)MeBoPhoz-RuCI2-PPh3 with different additives (20 molpercent)Entry _ Additive Conv. (percent) de (percent)~1.........."........."................~ .................~...........">98.............. ~93~........2 MgBr2.OEt 75 93.53 NH4CI 60 934 Na(C02CF3) >99 93C5 Ag(OTf)2 31 906 AgBF4 157 NaOAc 16.5 83a Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2 (145 psi), 55 °C, 18 hrs. Conversion and de measured by chiral HPLC.c reaction complete after 5 hrs.; Table 8a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with different levels of sodium trifluoroacetate as additive.3Entry CatalystNa(C02CF3) Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2- PPh3234567 p-F-Ph-(f?)MeBoPhoz-RuCI2-dmf8(molpercent)-7392.5599931097932090915081.59010044872.5>9993.55>9993.5Reaction conditions: Endeavor catalyst system; s/c 1000, 12h, EtOH (2 ml/mmol), H2 (145 psi), 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.
With hydrogen;p-fluorophenyl (R)-MeBoPhoz-RuCl2-dmf; sodium 2,2,2-trifluoroacetate; In ethanol; at 45 - 55℃; under 7498.84 Torr; for 12 - 18h;Endeavor catalyst system;Product distribution / selectivity; Table 8a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with different levels of sodium trifluoroacetate as additive.3Entry CatalystNa(C02CF3) Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2- PPh3234567 p-F-Ph-(f?)MeBoPhoz-RuCI2-dmf8(molpercent)-7392.5599931097932090915081.59010044872.5>9993.55>9993.5Reaction conditions: Endeavor catalyst system; s/c 1000, 12h, EtOH (2 ml/mmol), H2 (145 psi), 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.Table 8b. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with sodium trifluoroacetate as additive under different conditions.3EntryCatalystNa(TFA):S/cTempConv.deCatalyst(°C)(percent)(percent)1(/?)MeBoPhoz-RuCI2-dmf-10005582922u25:11000559892.43a50:110005599944p-F-Ph-(/?)MeBoPhoz-RuCI2-dmf25:11000559994525:11000459994625:11000359394725:11500559994825:12000559894950:120005578941025:12500559592a Reaction conditions: Endeavor catalyst system; 18h, EtOH (2 ml/mmol), H2 (145 psi), Na(TFA):Catalyst molar ratio. Conversion analysed by HPLC, de measured by chiral HPLC.
With hydrogen;p-fluorophenyl (R)-MeBoPhoz-RuCl2-dmf; sodium 2,2,2-trifluoroacetate; In ethanol; at 40 - 48℃; under 7498.84 Torr; for 18h;Parr autoclave;Product distribution / selectivity; To a 50 ml Glass liner was added catalyst (5.4mg, 6umol s/c 1000; or 2.7mg, 3 umol, s/c 2000), sodium trifluoroacetate (20.4 mg, 0.15mmol, s/clOOO; or 10.2mg, 0.075mmol, s/c 2000) and substrate (1.79 g, 6 mmol). This was placed in theautoclave and the flushed with Nitrogen. Ethanol (12 ml) was added to the autoclave. The autoclave was placed in an oil bath (oil bath temperature 69°C) and left to equilibrate for 10 minutes. The autoclave was then pressurised with hydrogen (10 bar) and left for 18 hrs. The internal temperature of the autoclave was measured as being 40°C. A pressure drop of 50 psi was noted over 18 hrs. The autoclave was removed from the oil bath, cooled, depressurised and the contents analysed by HPLC. The results of this and a similar study are shown in Table 9.Table 9.Entry Catalyst Na(TFA): s/c Temp Conv. de _______________________________Catalyst________.pound.c.pound.____(percent)_____{percent)_ p-F-Ph-(R)MeBoPhoz-RuCI2 QO fto1 dmf 25:1 1000 48 88 922 " 25:1 2000 40 96 94a Reaction conditions: 50 ml Parr Autoclave; 18h, EtOH (2 ml/mmol), H2 (145 psi), Na(TFA):Catalyst molar ratio.b Internal temperature of autoclave measured using temperature probe inserted into sampling well of autoclave. Conversion analysed by HPLC, de measured by chiral HPLC.; Example 10Influence of Pressure on Asymmetric Hvdrogenation of BocChloroketone using BoPhoz-Ru catalysts.Some results of this study are shown in Table 10 and 10a.Table 10Entry Catalyst S/c Pressure Conv. (percent) De (percent)(psi). (^MeBoPho^RuCb-dmf TOOO 702 (R)MeBoPhoz-RuCI2-dmf 1000 1453 p-F-Ph-(f?)MeBoPhoz-RuCI2 dmf 1000 704 p-F-Ph-(R)MeBoPhoz-RuCI2 dmf 1000 1459494989398969894Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2, 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.Table 10a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with sodium trifluoroacetate as additive using a 50 ml Parr autoclave.3Entry Catalyst Na(TFA): s/c Temp Conv. de_ Catalyst _ _ (°Cf _ (percent) (percent)".....................p^RH^MeBoPhoz-RuCb....."~..........~............."................"..................................dmf 2 325:110004888vz25:1200040969425:12500459393
With hydrogen;(R)-[RuCl(benzene)(MeBoPhoz)]Cl; sodium 2,2,2-trifluoroacetate; In ethanol; at 55℃; under 3420.23 Torr; for 41h;Parr autoclave;Product distribution / selectivity; A Parr vessel was charged with (R)-[RuCI(benzene)(MeBoPhoz)]CI (98mg), sodium trifluoroacetate (366mg) and (3S)-3-t-butoxycarbonylamino-1-chloro-4-phenyl-2-butanone (33g) and 220ml of degassed ethanol. After purging cycle,the vessel was heated to 55°C and pressurised with hydrogen to 4.5 atm. After completion of reaction (41 h), HPLC analysis showed 96.5percent conversion and a 93.7percent de in favour of the desired (2R.3S) chloroalcohol.
With hydrogen;(R)MeBoPhoz-RuCl2-PPh3; ammonium chloride; In ethanol; at 55℃; under 7498.84 Torr; for 18h;Endeavor catalyst system;Product distribution / selectivity; The Some results of study of effect of additives on the reaction are summarised in Tables 8, 8a and 8bTable 8 Asymmetric Hydrogenation of BocChloroketone using (R)MeBoPhoz-RuCI2-PPh3 with different additives (20 molpercent)Entry _ Additive Conv. (percent) de (percent)~1.........."........."................~ .................~...........">98.............. ~93~........2 MgBr2.OEt 75 93.53 NH4CI 60 934 Na(C02CF3) >99 93C5 Ag(OTf)2 31 906 AgBF4 157 NaOAc 16.5 83a Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2 (145 psi), 55 °C, 18 hrs. Conversion and de measured by chiral HPLC.c reaction complete after 5 hrs.
With hydrogen;(R)MeBoPhoz-RuCl2-PPh3; magnesium bromide ethyl etherate; In ethanol; at 55℃; under 7498.84 Torr; for 18h;Endeavor catalyst system;Product distribution / selectivity; The Some results of study of effect of additives on the reaction are summarised in Tables 8, 8a and 8bTable 8 Asymmetric Hydrogenation of BocChloroketone using (R)MeBoPhoz-RuCI2-PPh3 with different additives (20 molpercent)Entry _ Additive Conv. (percent) de (percent)~1.........."........."................~ .................~...........">98.............. ~93~........2 MgBr2.OEt 75 93.53 NH4CI 60 934 Na(C02CF3) >99 93C5 Ag(OTf)2 31 906 AgBF4 157 NaOAc 16.5 83a Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2 (145 psi), 55 °C, 18 hrs. Conversion and de measured by chiral HPLC.c reaction complete after 5 hrs.
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In ethanol; butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 4; Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; A series of experiments were carried out with an aforementioned ligand and with the following ligands coordinated to ruthenium:; Some results of this study are shown in Table 3; Table 3.EntryCatalystS/CTime (h)Conv(percent) (HPLC)Product (HPLC)d.e (percent)config1aRu-(S)-Xyl-P-Phos-Ci2(dmf)25002055932R3S2aRu-(f?)-Me-BoPhoz-CI2(dmf)250020>99942R,3S3bRu-(f?)-Me-BoPhoz-CI2(dmf)27502496b942R,3S4CRu-(R)-Me-BoPhoz-CI2(dmf)210004894° 942R.3S5aRu-(R)-Et-BoPhoz-CI2(dmf)25002096 | 88.52R,3Sa) 0.5mmol BocChloroketone, S/C = 500/1, 3mL 1-BuOH, O.OOImmol catalyst, 50°C, 10bar H2, 20 hrs;b) 1mmol BocChloroketone, S/C = 750/1, 6mL 1-BuOH, 0.0013mmol catalyst, 50-55°C, 10bar H2, 24 hrs, reaction performed in a Parr reactor;c) 1mmol BocChloroketone, S/C = 1000/1, 6mL 1-BuOH, O.OOImmol catalyst, 50-55°C, 10bar H2, 48hrs, reaction performed in a Parr reactor.; Example 4 Influence of the solvent on the Ru-(ffl-Me-BoPhoz-CI?fclmf)rcatalyzed asymmetric hvdroqenation of BocChloroketone; Some results of this study are shown in Table 4;Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.; Example 5Influence of the substrate concentration on the hvdrogenation of BocChloroketone using Ru-fffl-MeBoPhoz-CUdmfl? catalystSome results of this study are shown in Table 5; Table 5.EntrySolventSubs. Cone. (mmol/mL)Conv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH0.1799942R3S21-BuOH0.3368942R,3S3EtOH0.1782942R3S4EtOH0.3389932R.3S5EtOH0.59993.52R,3S6EtOH7cn irr>0^ nnu-, L0.6696932R,3S
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In butan-1-ol; at 50 - 55℃; under 7500.75 Torr; for 24 - 48h;Parr reactor;Product distribution / selectivity; A series of experiments were carried out with an aforementioned ligand and with the following ligands coordinated to ruthenium:; Some results of this study are shown in Table 3; Table 3.EntryCatalystS/CTime (h)Conv(percent) (HPLC)Product (HPLC)d.e (percent)config1aRu-(S)-Xyl-P-Phos-Ci2(dmf)25002055932R3S2aRu-(f?)-Me-BoPhoz-CI2(dmf)250020>99942R,3S3bRu-(f?)-Me-BoPhoz-CI2(dmf)27502496b942R,3S4CRu-(R)-Me-BoPhoz-CI2(dmf)210004894° 942R.3S5aRu-(R)-Et-BoPhoz-CI2(dmf)25002096 | 88.52R,3Sa) 0.5mmol BocChloroketone, S/C = 500/1, 3mL 1-BuOH, O.OOImmol catalyst, 50°C, 10bar H2, 20 hrs;b) 1mmol BocChloroketone, S/C = 750/1, 6mL 1-BuOH, 0.0013mmol catalyst, 50-55°C, 10bar H2, 24 hrs, reaction performed in a Parr reactor;c) 1mmol BocChloroketone, S/C = 1000/1, 6mL 1-BuOH, O.OOImmol catalyst, 50-55°C, 10bar H2, 48hrs, reaction performed in a Parr reactor.
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In ethanol; dichloromethane; at 50℃; under 7500.75 Torr; for 20h;Parr reactor;Product distribution / selectivity; Some results of this study are shown in Table 4; Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In isopropyl alcohol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 4; Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In ethanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 4; Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.; Example 5Influence of the substrate concentration on the hvdrogenation of BocChloroketone using Ru-fffl-MeBoPhoz-CUdmfl? catalystSome results of this study are shown in Table 5; Table 5.EntrySolventSubs. Cone. (mmol/mL)Conv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH0.1799942R3S21-BuOH0.3368942R,3S3EtOH0.1782942R3S4EtOH0.3389932R.3S5EtOH0.59993.52R,3S6EtOH7cn irr>0^ nnu-, L0.6696932R,3S
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In propan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 4; Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.
With hydrogen;Ru-(R)-Me-BoPhoz-Cl2(dmf)2; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 4; Table 4.EntrySolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config11-BuOH>99942R,3S2MeOH46932R,3S3EtOH82942R.3S41-PrOH63942R.3S52-PrOH23952R.3S6EtOH/1-BuOH = 1/192942R,3S7EtOH/1-BuOH =3/179942R.3S8bEtOH/DCM =3/1I 90b93.52R,3S9DCE3--10THF---Reactionconditions: 1mmol BocChoroketone, S/Cratio = 750/1,0.0013mmolcatalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs.b 1mmol substrate, S/C ratio = 750/1, 0.0013mmol catalyst, 6mL solvent, 50°C, 10 bar, reaction time 20 hrs, reaction performed in a Parr reactor.
With hydrogen;Ru-(R)-Et-BoPhoz-Cl2(dmf)2; In butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; A series of experiments were carried out with an aforementioned ligand and with the following ligands coordinated to ruthenium:; Some results of this study are shown in Table 3; Table 3.EntryCatalystS/CTime (h)Conv(percent) (HPLC)Product (HPLC)d.e (percent)config1aRu-(S)-Xyl-P-Phos-Ci2(dmf)25002055932R3S2aRu-(f?)-Me-BoPhoz-CI2(dmf)250020>99942R,3S3bRu-(f?)-Me-BoPhoz-CI2(dmf)27502496b942R,3S4CRu-(R)-Me-BoPhoz-CI2(dmf)210004894° 942R.3S5aRu-(R)-Et-BoPhoz-CI2(dmf)25002096 | 88.52R,3Sa) 0.5mmol BocChloroketone, S/C = 500/1, 3mL 1-BuOH, O.OOImmol catalyst, 50°C, 10bar H2, 20 hrs;b) 1mmol BocChloroketone, S/C = 750/1, 6mL 1-BuOH, 0.0013mmol catalyst, 50-55°C, 10bar H2, 24 hrs, reaction performed in a Parr reactor;c) 1mmol BocChloroketone, S/C = 1000/1, 6mL 1-BuOH, O.OOImmol catalyst, 50-55°C, 10bar H2, 48hrs, reaction performed in a Parr reactor.
With hydrogen;(R)MeBoPhoz-RuCl2-dmf; In ethanol; at 55℃; under 3620.13 - 7498.84 Torr;Endeavor catalyst system;Product distribution / selectivity; A series of experiments were carried out certain BoPhoz ligands coordinated to ruthenium. Some results of this study are shown in Table 6.Table 6EntryCatalystS/c _Time Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2-dmf2 (R)MeBoPhoz-RuCI2-PPh33 (R)MeBoPhoz-RuCI2-dmf4 (R)MeBoPhoz-RuCI2-dmf5 (R)MeBoPhoz-Ru (acac)26 (R)MeBoPhoz-RuCI2 (TFA)250018>999350018>9992.5100056>9993100056899210001855921000186988Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2(145 psi), 55 oC. Conversion analysed by HPLC, de measured by chiralHPLC. Example 10Influence of Pressure on Asymmetric Hvdrogenation of BocChloroketone using BoPhoz-Ru catalysts.Some results of this study are shown in Table 10 and 10a.Table 10Entry Catalyst S/c Pressure Conv. (percent) De (percent)(psi). (^MeBoPho^RuCb-dmf TOOO 702 (R)MeBoPhoz-RuCI2-dmf 1000 1453 p-F-Ph-(f?)MeBoPhoz-RuCI2 dmf 1000 704 p-F-Ph-(R)MeBoPhoz-RuCI2 dmf 1000 1459494989398969894Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2, 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.Table 10a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with sodium trifluoroacetate as additive using a 50 ml Parr autoclave.3Entry Catalyst Na(TFA): s/c Temp Conv. de_ Catalyst _ _ (°Cf _ (percent) (percent)".....................p^RH^MeBoPhoz-RuCb....."~..........~............."................"..................................dmf 2 325:110004888vz25:1200040969425:12500459393
With hydrogen;silver trifluoromethanesulfonate; (R)MeBoPhoz-RuCl2-PPh3; In ethanol; at 55℃; under 7498.84 Torr; for 18h;Endeavor catalyst system;Product distribution / selectivity; The Some results of study of effect of additives on the reaction are summarised in Tables 8, 8a and 8bTable 8 Asymmetric Hydrogenation of BocChloroketone using (R)MeBoPhoz-RuCI2-PPh3 with different additives (20 molpercent)Entry _ Additive Conv. (percent) de (percent)~1.........."........."................~ .................~...........">98.............. ~93~........2 MgBr2.OEt 75 93.53 NH4CI 60 934 Na(C02CF3) >99 93C5 Ag(OTf)2 31 906 AgBF4 157 NaOAc 16.5 83a Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2 (145 psi), 55 °C, 18 hrs. Conversion and de measured by chiral HPLC.c reaction complete after 5 hrs.
With hydrogen;(R)MeBoPhoz-RuCl2-PPh3; In ethanol; at 55℃; under 7498.84 Torr; for 18h;Endeavor catalyst system;Product distribution / selectivity; A series of experiments were carried out certain BoPhoz ligands coordinated to ruthenium. Some results of this study are shown in Table 6.Table 6EntryCatalystS/c _Time Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2-dmf2 (R)MeBoPhoz-RuCI2-PPh33 (R)MeBoPhoz-RuCI2-dmf4 (R)MeBoPhoz-RuCI2-dmf5 (R)MeBoPhoz-Ru (acac)26 (R)MeBoPhoz-RuCI2 (TFA)250018>999350018>9992.5100056>9993100056899210001855921000186988Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2(145 psi), 55 oC. Conversion analysed by HPLC, de measured by chiralHPLC.; Example 8Asymmetric Hydrogenation of BocChloroketone using (/?)MeBoPhoz-RuCI?-PPhj with different additivesThe Some results of study of effect of additives on the reaction are summarised in Tables 8, 8a and 8bTable 8 Asymmetric Hydrogenation of BocChloroketone using (R)MeBoPhoz-RuCI2-PPh3 with different additives (20 molpercent)Entry _ Additive Conv. (percent) de (percent)~1.........."........."................~ .................~...........">98.............. ~93~........2 MgBr2.OEt 75 93.53 NH4CI 60 934 Na(C02CF3) >99 93C5 Ag(OTf)2 31 906 AgBF4 157 NaOAc 16.5 83a Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2 (145 psi), 55 °C, 18 hrs. Conversion and de measured by chiral HPLC.c reaction complete after 5 hrs. Table 8a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with different levels of sodium trifluoroacetate as additive.3Entry CatalystNa(C02CF3) Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2- PPh3234567 p-F-Ph-(f?)MeBoPhoz-RuCI2-dmf8(molpercent)-7392.5599931097932090915081.59010044872.5>9993.55>9993.5Reaction conditions: Endeavor catalyst system; s/c 1000, 12h, EtOH (2 ml/mmol), H2 (145 psi), 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.
With hydrogen;(R)MeBoPhoz-Ru(acac)2; In ethanol; at 55℃; under 7498.84 Torr;Endeavor catalyst system;Product distribution / selectivity; A series of experiments were carried out certain BoPhoz ligands coordinated to ruthenium. Some results of this study are shown in Table 6.Table 6EntryCatalystS/c _Time Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2-dmf2 (R)MeBoPhoz-RuCI2-PPh33 (R)MeBoPhoz-RuCI2-dmf4 (R)MeBoPhoz-RuCI2-dmf5 (R)MeBoPhoz-Ru (acac)26 (R)MeBoPhoz-RuCI2 (TFA)250018>999350018>9992.5100056>9993100056899210001855921000186988Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2(145 psi), 55 oC. Conversion analysed by HPLC, de measured by chiralHPLC.
With hydrogen;(R)MeBoPhoz-RuCl2(TFA)2; In ethanol; at 55℃; under 7498.84 Torr;Endeavor catalyst system;Product distribution / selectivity; A series of experiments were carried out certain BoPhoz ligands coordinated to ruthenium. Some results of this study are shown in Table 6.Table 6EntryCatalystS/c _Time Conv. (percent) de (percent)1 (R)MeBoPhoz-RuCI2-dmf2 (R)MeBoPhoz-RuCI2-PPh33 (R)MeBoPhoz-RuCI2-dmf4 (R)MeBoPhoz-RuCI2-dmf5 (R)MeBoPhoz-Ru (acac)26 (R)MeBoPhoz-RuCI2 (TFA)250018>999350018>9992.5100056>9993100056899210001855921000186988Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2(145 psi), 55 oC. Conversion analysed by HPLC, de measured by chiralHPLC.
With hydrogen;p-fluorophenyl (R)-MeBoPhoz-RuCl2-dmf; In ethanol; at 55℃; under 3620.13 - 7498.84 Torr;Endeavor catalyst system;Product distribution / selectivity; Some results of this study are shown in Table 7Table 7"Entry S/c fTrnT^oTr^r^r^M^T1 500 5 >99 942 1000 12 >99 93.53 2000 55 75 93; Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2(145 psi), 55 oC. Conversion analysed by HPLC, de measured by chiralHPLC.; Example 10Influence of Pressure on Asymmetric Hvdrogenation of BocChloroketone using BoPhoz-Ru catalysts.Some results of this study are shown in Table 10 and 10a.Table 10Entry Catalyst S/c Pressure Conv. (percent) De (percent)(psi). (^MeBoPho^RuCb-dmf TOOO 702 (R)MeBoPhoz-RuCI2-dmf 1000 1453 p-F-Ph-(f?)MeBoPhoz-RuCI2 dmf 1000 704 p-F-Ph-(R)MeBoPhoz-RuCI2 dmf 1000 1459494989398969894Reaction conditions: Endeavor catalyst system; EtOH (2 ml/mmol), H2, 55 °C. Conversion analysed by HPLC, de measured by chiral HPLC.Table 10a. Asymmetric hydrogenation of BocChloroketone using BoPhoz-Ru catalysts with sodium trifluoroacetate as additive using a 50 ml Parr autoclave.3Entry Catalyst Na(TFA): s/c Temp Conv. de_ Catalyst _ _ (°Cf _ (percent) (percent)".....................p^RH^MeBoPhoz-RuCb....."~..........~............."................"..................................dmf 2 325:110004888vz25:1200040969425:12500459393
With hydrogen;di-mu-iodobis{iodo(eta-benzene)ruthenium(II)}; C64H76FeN2O4P2; In ethanol; at 65℃; under 4500.45 Torr; for 18h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Further screening was carried out using the following ligands:In a 10ml Schlenk flask (set under an atmosphere of argon) metal precursor (1 equiv) and ligand (1.05 equivalents) were placed and dissolved in 1 ml of freshly distilled solvent. The solution was stirred at room temperature for 30 minutes. BOC Chloroketone was dissolved in solvent to give a 0.5M solution in a tube suitable for parallel screening. The catalyst solution was transferred into the tube and placed in parallel reactor. The autoclave was closed, set under the desired hydrogen pressure and temperature was adjusted to the desired value. After the given reaction time, the reaction was stopped and a sample of the reaction mixture was diluted and directly analyzed by HPLC. Some results of this study are shown in Table 13.Table 13S/cMetalLigandAbs ConfSolt (h)P (bar)T °CProdsmde1250Ru"A(R)-(S)EtOH20655100092percent2250Ru*B(R)-(S)EtOH1866595590percent3100Ru*C(S)-(R)EtOH184062901096percent4250Ru*D(R)EtOH184062712996percentRu* [RuCI2(p-cymene)]2 RuUSD [Rul2(p-cymene)]2
With hydrogen;di-mu-iodobis{iodo(eta-benzene)ruthenium(II)}; C32H40FeP2; In ethanol; at 62℃; under 30003 Torr; for 18h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Further screening was carried out using the following ligands:In a 10ml Schlenk flask (set under an atmosphere of argon) metal precursor (1 equiv) and ligand (1.05 equivalents) were placed and dissolved in 1 ml of freshly distilled solvent. The solution was stirred at room temperature for 30 minutes. BOC Chloroketone was dissolved in solvent to give a 0.5M solution in a tube suitable for parallel screening. The catalyst solution was transferred into the tube and placed in parallel reactor. The autoclave was closed, set under the desired hydrogen pressure and temperature was adjusted to the desired value. After the given reaction time, the reaction was stopped and a sample of the reaction mixture was diluted and directly analyzed by HPLC. Some results of this study are shown in Table 13.Table 13S/cMetalLigandAbs ConfSolt (h)P (bar)T °CProdsmde1250Ru"A(R)-(S)EtOH20655100092percent2250Ru*B(R)-(S)EtOH1866595590percent3100Ru*C(S)-(R)EtOH184062901096percent4250Ru*D(R)EtOH184062712996percentRu* [RuCI2(p-cymene)]2 RuUSD [Rul2(p-cymene)]2
With hydrogen;di-mu-iodobis{iodo(eta-benzene)ruthenium(II)}; C77H106N2O6P2; In ethanol; at 62℃; under 30003 Torr; for 18h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Further screening was carried out using the following ligands:In a 10ml Schlenk flask (set under an atmosphere of argon) metal precursor (1 equiv) and ligand (1.05 equivalents) were placed and dissolved in 1 ml of freshly distilled solvent. The solution was stirred at room temperature for 30 minutes. BOC Chloroketone was dissolved in solvent to give a 0.5M solution in a tube suitable for parallel screening. The catalyst solution was transferred into the tube and placed in parallel reactor. The autoclave was closed, set under the desired hydrogen pressure and temperature was adjusted to the desired value. After the given reaction time, the reaction was stopped and a sample of the reaction mixture was diluted and directly analyzed by HPLC. Some results of this study are shown in Table 13.Table 13S/cMetalLigandAbs ConfSolt (h)P (bar)T °CProdsmde1250Ru"A(R)-(S)EtOH20655100092percent2250Ru*B(R)-(S)EtOH1866595590percent3100Ru*C(S)-(R)EtOH184062901096percent4250Ru*D(R)EtOH184062712996percentRu* [RuCI2(p-cymene)]2 RuUSD [Rul2(p-cymene)]2
With hydrogen;[Rh(R-SpirOP)(NBD)]BF4; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for initial experimental studies.OMe OMeMeO' ^"PPh2 MeO MeO^^k ^PPh2 MeOPXyl2 PXyl2Ph2P PPh2i iNHPPh2 NHPPh2H 00OMe Xyl-P-PhosH8-BINAMPSpirOPPhanephos Xyl-Phanephos MeOXyl-Phanephos Cy-Phanephos'Pr-Phanepho"'."jf ,--'""N.^MeO^^P'Pr2 FeDIPFcMe-DUPHOSMeODIPAMPSome results of this study are shown in Table 14.Table 14EntryCatalyst(°C)P(bar)Conv (percent) (HPLC)Product . (HPLC)d.econfig1[Rh(R-Xyl-PhanePhos)(NBD)]BF4501096502R.3S2[Rh(S-MeOXyl-PhanePhos)(NBD)]BF45010100562R.3S3[Rh(R-Me-DuPhos)(COD)]OTf501015682R.3S4[Rh(R-SpirOP)(NBD)]BF4501011842R.3SReaction conditions: 1mmol substrate, S/C ratio = 100/1, 4ml_ MeOH, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(S-Et-BoPhoz)(COD)]OTf; In methanol; at 65℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; The following ligands coordinated to rhodium were chosen for experimental studies:PV ,Ph PPPh2Phv fh P,PPh2 -EtPh PPh PCy2Ph. fhPPh,OY~Me ^MN~Et 0-AEt ^AHFeFeFeFeMeBoPhozEtBoPhozPCycoBoPhozProBoPhozSome results of this study are shown in Table 15.Table 15EntryLigandSolventConv(percent) (HPLC)Product (HPLC).d:e (percent) J .cqnfjg1lS-Me:BoPhc)z)MeOH98722R,3S(S-Et-BoPhoz)MeOH94832R,3SIR-Xy^PhjmePhos^MeOH10059 2R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL MeOH, 65°C, 10 bar, unoptimized reaction time 20 hrs.; Example 16Influence of the solvent on the hvdrogenation of BocChloroketone in the presence of rRh(COD21QTf/BoPhoz systemsSome results of this study are shown in Table 16.Table 16EntryLigandSolventConv(percent) (HPLC)Product (HPLC)d.e (percent)config1(S-Et-BoPhoz)y MeOH94832R,3S2(S-Et-BoPhoz)THFt 52512R.3S3(S-Et-BoPhoz)BOH73422R.3S4(R-Et-BoPhoz)MeOH9545L2R,3S5(R-Et-BoPhoz)DCE15792R.3S6(S-PCyCo-BoPhoz)MeOHToo632S.3S7(S-PCyCo-BoPhoz) jTHF74392R.3S8(S-PCyCo-BoPhoz)EtOH99342S.3S9(S-PCyCo-BoPhoz)'PrOH9973h 2S.3S10(S-PCyCo-BoPhoz)DCE15142R.3S11(R-PCyCo-BoPhoz)EtOH100522R.3SaReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4ml_ solvent, 65°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Xyl-PhanePhos)(COD)]OTf; In water; butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 17.Table 17EntryLigandSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1(R-Xyl-PhanePhos)MeOH100632R,3S2(R-Xyl-PhanePhos)EtOH100772R,3S3(R-Xyl-PhanePhos)10percentH2O-EtOH100802R,3S4(R-Xyl-PhanePhos)1-BuOH100792R,3S5(R-Xyl-PhanePhos)10percent H20-BuOH100842R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;[Rh(R-Xyl-PhanePhos)(COD)]OTf; In ethanol; water; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 17.Table 17EntryLigandSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1(R-Xyl-PhanePhos)MeOH100632R,3S2(R-Xyl-PhanePhos)EtOH100772R,3S3(R-Xyl-PhanePhos)10percentH2O-EtOH100802R,3S4(R-Xyl-PhanePhos)1-BuOH100792R,3S5(R-Xyl-PhanePhos)10percent H20-BuOH100842R.3SReaction conditions: 1mmol substrate, [Rh(bisphosphine)(COD)]OTf generated in the corresponding solvent by reacting [Rh(COD)2]OTf with the bisphosphine for 30min under N2. S/C ratio = 100/1, 4mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-P-Phos)Cl2(dmf)2; In butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-P-Phos)Cl2(dmf)2; In isopropyl alcohol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-P-Phos)Cl2(dmf)2; In ethanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-P-Phos)Cl2(dmf)2; In iso-butanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-P-Phos)Cl2(dmf)2; In methanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In water; butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In butan-1-ol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; A series of experiments were carried out with an aforementioned ligand and with the following ligands coordinated to ruthenium:; Some results of this study are shown in Table 3; Table 3.EntryCatalystS/CTime (h)Conv(percent) (HPLC)Product (HPLC)d.e (percent)config1aRu-(S)-Xyl-P-Phos-Ci2(dmf)25002055932R3S2aRu-(f?)-Me-BoPhoz-CI2(dmf)250020>99942R,3S3bRu-(f?)-Me-BoPhoz-CI2(dmf)27502496b942R,3S4CRu-(R)-Me-BoPhoz-CI2(dmf)210004894° 942R.3S5aRu-(R)-Et-BoPhoz-CI2(dmf)25002096 | 88.52R,3Sa) 0.5mmol BocChloroketone, S/C = 500/1, 3mL 1-BuOH, O.OOImmol catalyst, 50°C, 10bar H2, 20 hrs;b) 1mmol BocChloroketone, S/C = 750/1, 6mL 1-BuOH, 0.0013mmol catalyst, 50-55°C, 10bar H2, 24 hrs, reaction performed in a Parr reactor;c) 1mmol BocChloroketone, S/C = 1000/1, 6mL 1-BuOH, O.OOImmol catalyst, 50-55°C, 10bar H2, 48hrs, reaction performed in a Parr reactor.
With hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In isopropyl alcohol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In ethanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.
With hydrogen;Ru(S-Xyl-P-Phos)Cl2(dmf)2; In iso-butanol; at 50℃; under 7500.75 Torr; for 20h;Argonaut Endeavour hydrogenation unit;Product distribution / selectivity; Some results of this study are shown in Table 2:Table 2EntryCatalystSolventConv (percent) (HPLC)Product (HPLC)d.e (percent)config1Ru(S-P-Phos)CI2(dmf)2MeOH56892R,3S2Ru(S-P-Phos)CI2(dmf)2EtOH77932R,3S3Ru(S-Xyl-P-Phos)CI2(dmf)2EtOH80942R.3S"4 'Ru(S-P-Phos)CI2(dmf)2'PrOH40892R,3S5Ru(S-Xyl-P-Phos)CI2(dmf)2'PrOH81932R,3S6Ru(S-P-Phos)CI2(dmf)21-BuOH83932R,3S7Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH98942R.3S8Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/10percent H2085852R.3S9Ru(S-Xyl-P-Phos)CI2(dmf)21-BuOH/1eq HCI45932R,3S10Ru(S-P-Phos)CI2(dmf)22-BuOH25852R,3S11Ru(S-Xyl-P-Phos)CI2(dmf)22-BuOH60922R,3SaReaction conditions: 0.5mmol substrate, S/C ratio = 100/1, 3mL solvent, 50°C, 10 bar, unoptimized reaction time 20 hrs.

Reference: [1]Tetrahedron Asymmetry,2003,vol. 14,p. 3105 - 3109
[2]Patent: EP1151992,2001,A1
[3]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-16
[4]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[5]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 26-28
[6]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 21-22
[7]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 23
[8]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 21-23
[9]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 22-23
[10]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 23-25
[11]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 25-26
[12]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 21-22
[13]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 21-22
[14]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 19
[15]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 17-20
[16]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 17-18
[17]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 19
[18]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 19
[19]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 5; 15; 19-20
[20]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 19
[21]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 19
[22]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 17-18
[23]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 20; 24-25
[24]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 21-22
[25]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 20-22
[26]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 20
[27]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 20
[28]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 20-21; 24-25
[29]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 26-28
[30]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 26-28
[31]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 26-28
[32]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 29-30
[33]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 30-31
[34]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31-32
[35]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 31-32
[36]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[37]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[38]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[39]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[40]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[41]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[42]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[43]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15; 17-18
[44]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[45]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[46]Patent: WO2006/16116,2006,A1 .Location in patent: Page/Page column 7; 15-17
[47]ChemCatChem,2015,vol. 7,p. 984 - 992
  • 5
  • [ 51987-73-6 ]
  • [ 162536-40-5 ]
Reference: [1]Journal of Organic Chemistry,2004,vol. 69,p. 7344 - 7347
  • 6
  • [ 13734-34-4 ]
  • [ 162536-40-5 ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
  • 7
  • [ 60398-41-6 ]
  • [ 162536-40-5 ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
  • 8
  • [ 67729-36-6 ]
  • [ 162536-40-5 ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
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  • [ 162536-40-5 ]
  • [ 162541-34-6 ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
  • 10
  • [ 162536-40-5 ]
  • (1S-(1R*,2R)(3S*))-<3-<<3-<<(1,1-dimethylethoxy)carbonyl>amino>-2-hydroxy-4-phenylbutyl>amino>-2-hydroxy-1-(phenylmethyl)propyl>carbamic acid 1,1-dimethylethyl ester [ No CAS ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
  • 11
  • [ 162536-40-5 ]
  • <(S,S)-3-<<(R,S)-3-<<(1,1-dimethylethoxy)carbonyl>amino>-2-hydroxy-4-phenylbutyl>amino>-2-hydroxy-1-(phenylmethyl)propyl>carbamic acid 1,1-dimethylethyl ester [ No CAS ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
  • 12
  • [ 162536-40-5 ]
  • [ 162677-31-8 ]
Reference: [1]Journal of Medicinal Chemistry,1994,vol. 37,p. 1758 - 1768
YieldReaction ConditionsOperation in experiment
7.94g (80.2%) Example 20 Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane and production of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane 2-Propanol (25.3 ml) and water (8.5 ml) were added to (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane {(2R,3S) content of 11.28 g; (2S,3S) content of 1.55 g} obtained by the same method as in Reference Example 3, to prepare a slurry, followed by addition of potassium chloride (329 mg) at 70 C., which was then agitated for 15 hours and cooled to 20 C. over 2.5 hours. The slurry was filtered at 20 C., to remove insoluble matters. 2-Propanol (58.7 ml) and water (3.2 ml) were added to the resulting mother liquor, followed by cooling at 4 C. and addition of aqueous 4 mol/l sodium hydroxide solution (14.1 ml), for agitation at 4 C. for 2.5 hours. The reaction solution was analyzed by HPLC. The objective (2R,3S) compound was at 93.6% (HPLC area ratio). The reaction was quenched by addition of aqueous 0.85% citric acid solution (142 g). After cooling from 27 C. to -10 C. for 2.5 hours, the addition of the seed crystal and overnight agitation enabled the crystallization of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane. The resulting slurry was filtered; to the resulting crystal was added water (56.4 ml), to prepare a slurry, followed by agitation at 20 C. for one hour; the slurry was filtered and dried, to afford the crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane {(2R,3S) recovery yield of 7.94g (80.2%)}. The dried crystal was analyzed by HPLC. (2R,3S):(2S,3S)=98.1:1.9. Additionally, (2R,3S) purity was at 97.6% (HPLC area ratio).
YieldReaction ConditionsOperation in experiment
99.0% After completion of the reaction, the reaction mixture was extracted with toluene, desolvated and the extract was analyzed in the same manner as in Example 8. As a result, (2R,3S)-1-chloro-3-tert-butoxycarbonylamino-4-phenyl-2-butanol (yield 99.0%, diastereomeric excess 99.8% d.e.) was obtained.
99.1% After completion of the reaction, the reaction mixture was extracted with toluene, desolvated and the extract was analyzed in the same manner as in Example 8. As a result, (2R,3S)-1-chloro-3-tert-butoxycarbonylamino-4-phenyl-2-butanol (yield 99.1%, diastereomeric excess 99.8% d.e.) was obtained.
99.6% After completion of the reaction, the reaction mixture was extracted with toluene, desolvated and the extract was analyzed in the same manner as in Example 8. As a result, (2R,3S)-1-chloro-3-tert-butoxycarbonylamino-4-phenyl-2-butanol (yield 99.6%, diastereomeric excess 99.8% d.e.) was obtained.
4.0% [1(S)-benzyl-2(R)-hydroxy-3-chloropropyl]carbamic acid t-butyl ester: 12.1 mg (0.04 mmol); yield 4.0%.
2.0% [1(S)-benzyl-2(R)-hydroxy-3-chloropropyl]carbamic acid t-butyl ester: 0.059 g (0.20 mmol); yield 2.0%.
1.0% [1(S)-benzyl-2(R)-hydroxy-3-chloropropyl]carbamic acid t-butyl ester: 3.1 mg (0.01 mmol); yield 1.0%.
1.8% [1(S)-benzyl-2(R)-hydroxy-3-chloropropyl]carbamic acid t-butyl ester: 5.5 mg (0.02 mmol); yield 1.8%.
1.9% [1(S)-benzyl-2(R)-hydroxy-3-chloropropyl]carbamic acid t-butyl ester: 5.9 mg (0.02 mmol); yield 1.9%.
Example 4 Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane To the crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane {200.6 mg; (2R,3S): (2S,3S)=84.7:15.3} obtained in
81.9% (17.9 g) Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane: A crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer product (21.9 g) as prepared in the same manner as that of Reference Example 1, and containing the (2S,3S) diastereomer at a (2R,3S): (2S,3S) ratio of 84.9:15.1, was added with 2-propanol (49.2 ml) and water (16.4 ml), to be dissolved therein at 70ØC. The resulting solution was cooled to 20ØC over a period of 4 hours. Further, it was stirred at 20ØC for 16 hours, and then cooled to 15ØC, at which temperature it was stirred for 1 hour. The insolubles produced were removed by filtration. The mother liquor was concentrated to dryness, and the (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer was obtained in a recovery yield of 81.9% (17.9 g). The production ratio of the target (2R,3S) diastereomer to the impurity (2S.3S) diastereomer was (2R,3S):(2S,3S) = 98.4:1.6 therein.
Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (1): A crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer product (0.997 g) as prepared in the same manner as that of Reference Example 2, and containing 0.790 g and 0.013 g of the (2R,3S) and (2S,3S) diastereomers, respectively (therefore, (2R,35): (25,35) ratio being 98.4:1.6, and the (2R,3S) diastereomer purity being 94.2%, as determined by the HPLC area ratio), was added with methanol (4.0 ml) as a polar organic solvent to be dissolved therein at room temperature (20ØC). The resulting solution was added with water (2.5 ml) dropwise over a period of 20 minutes, and then seeded with seed crystals, followed by stirring for 30 minutes. The mixture was cooled from 20ØC to 0ØC over a period of 1 hour, and then stirred for 40 minutes, followed by filtering. The crystals collected by filtering were dried, and the (2R,3S) diastereomer was obtained in a recovery yield of 78.2% (0.618 g). The (2R,3S):(2S,3S) ratio was 100:0, and the (2R,3S) diastereomer purity was 99.4%, as determined by the HPLC area ratio. 1H-NMR(CDCl3, 300MHz) deltappm: 1.38 (s, 9H), 2.91 (dd, J=8.1, 13.2Hz, 1H), 3.01 (dd, J=7.1, 13.2Hz, 1H), 3.14 (d, J=4.0Hz, 1H), 3.53 (s, 1H), 3.55 (d, J=2.3Hz, 1H), 3.70-3.77 (m, 1H), 3.79-3.89 (m, 1H), 4.88 (bd, 1H), 7.19-7.35 (m, 5H). Mass spectra m/e: 322 (M+Na+). [alpha]D20=-28.3Ø (c=0.50, CH2Cl2).
Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (2): A crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer product (1.007 g) as prepared in the same manner as that of Reference Example 2, and containing 0.982 g and 0.017 g of the (2R,3S) and (2S,3S) diastereomers, respectively ((2R,3S):(2S,3S) ratio being 98.3:1.7, and the (2R,3S) diastereomer purity being 97.5%, as determined by the HPLC area ratio), was added with ethylene glycol (5 ml) to be dissolved therein at 60ØC. The resulting solution was cooled from 60ØC to 50ØC over a period of 1 hour, and then seeded with seed crystals, followed by stirring for 30 minutes. The mixture was cooled from 50ØC to 20ØC over a period of 3 hours, and then stirred for 2 hours, followed by filtering. The crystals collected by filtering were washed with a 1:1 mixed solution of ethylene glycol and water (3 ml) and water (3 ml) in this order. The washed crystals were dried, and the (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer was obtained in a recovery yield of 67.1% (0.660 g). The (2R,35):(25,35) ratio was 99.94:0.06, and the (2R.3S) diastereomer purity was 99.8%, as determined by the HPLC area ratio.
Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (3): A crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer product (1.000 g) as prepared in the same manner as that of Reference Example 2, and containing 0.972 g and 0.017 g of the (2R,3S) and (2S,3S) diastereomers, respectively ((2R,3S):(2S,3S) ratio being 98.3:1.7, and the (2R,3S) diastereomer purity being 97.2%, as determined by the HPLC area ratio), was added with 1,3-propanediol (5 ml) to be dissolved therein at 60ØC. The resulting solution was cooled from 60ØC to 40ØC over a period of 2 hours, and then seeded with seed crystals. The mixture was cooled from 40ØC to 5ØC over a period of 3 hours and 30 minutes, and then stirred for 2 hours, followed by filtering. The crystals collected by filtering were washed with a 1:1 mixed solution of methanol and water (3 ml). The washed crystals were dried, and the (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer was obtained in a recovery yield of 63.8% (0.620 g). The (2R,3S): (2S,3S) ratio was 100:0, and the (2R,3S) diastereomer purity was 99.5%, as determined by the HPLC area ratio.
Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (4): A crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer product (1.000 g) as prepared in the same manner as that of Reference Example 2, and containing 0.981 g and 0.016 g of the (2R,3S) and (2S,3S) diastereomers, respectively ((2R,3S):(2S,3S) ratio being 98.4:1.6, and the (2R,3S) diastereomer purity being 98.1%, as determined by the HPLC area ratio), was added with ethylene glycol (4 ml) and 1,4-butanediol (0.6 ml) to be dissolved therein at 60ØC. The resulting solution was cooled from 60ØC to 48ØC over a period of 1 hour, and then seeded with seed crystals. The mixture was cooled from 48ØC to 20ØC over a period of 3 hours and then stirred for 2 hours, followed by filtering. The crystals collected by filtering were washed with a 1:1 mixed solution of methanol and water (3 ml). The washed crystals were dried, and the (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer was obtained in a recovery yield of 69.4% (0.686 g). The (2R,3S): (2S,3S) ratio was 100:0, and the (2R,3S) diastereomer purity was 99.5%, as determined by the HPLC area ratio.
Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (5): A crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer product (1.000 g) as prepared in the same manner as that of Reference Example 2, and containing 0.981 g and 0.016 g of the (2R,3S) and (2S,3S) diastereomers, respectively ((2R,3S):(2S,3S) ratio being 98.4:1.6, and the (2R,35) diastereomer purity being 98.1%, as determined by the HPLC area ratio), was added with ethylene glycon (6 ml), 2-propanol (2.4 ml) and water (1.7 ml) to be dissolved therein at 60ØC. The resulting solution was cooled from 60ØC to 30ØC over a period of 3 hours, and then seeded with seed crystals. The mixture was cooled from 30ØC to 20ØC over a period of 1 hour and then stirred for 2 hours, followed by filtering. The crystals collected by filtering were washed with a 1:1 mixed solution of methanol and water (3 ml). The washed crystals were dried, and the (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer was obtained in a recovery yield of 58.2% (0.574 g). The (2R,3S):(2S,3S) ratio was 100:0, and the (2R,3S) diastereomer purity was 99.5%, as determined by the HPLC area ratio.
Purification of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (6): A mother liquor (3.68 g) as prepared in the same manner as that of Reference Example 2, ((2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane) and containing 0.982 g and 0.017 g of the (2R,3S) and (2S,3S) diastereomers, respectively ((2R,3S):(2S,3S) ratio being 98.3:1.7, and the (2R,3S) diastereomer purity being 97.9%, as determined by the HPLC area ratio), was heated to 40ØC and added with ethylene glycol (6 ml) and water (1.2 ml). The resulting solution was cooled from 40ØC to 30ØC over a period of 1 hour, and then seeded with seed crystals, followd by stirring for 1 hour. The mixture was cooled from 30ØC to 20ØC over a period of 1 hour, and then stirred for 2 hours, followed by filtering. The crystals collected by filtering were washed with a 1: 1 mixed solution of methanol and water (3 ml). The washed crystals were dried, and the (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane diastereomer was obtained in a recovery yield of 58.5% (0.576 g). The (2R,3S): (2S,3S) ratio was 100:0, and the (2R,3S) diastereomer purity was 99.8%, as determined by the HPLC area ratio.
0.4% [1(S)-benzyl-2(R)-hydroxy-3-chloropropyl]carbamic acid t-butyl ester: 1.2 mg (0.004 mmol); yield 0.4%. [1(S)-benzyl-2-oxo-3-chloropropyl]carbamic acid t-butyl ester: 246 mg (0.83 mmol); recovery 86.3%.

  • 15
  • [ 67-63-0 ]
  • [ 162536-40-5 ]
  • [ 98760-08-8 ]
YieldReaction ConditionsOperation in experiment
With sodium hydroxide; citric acid; Example 9 Production of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane 2-Propanol (342 ml) and aqueous 2.5 mol/l sodium hydroxide solution (85.8 ml) were added to (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane {(2R,3S) content of 40.6 g; (2S,3S) content of 1.66 g} obtained in the same manner as in Example 1, for agitation at 0 C. for 1.5 hours. Aqueous 13.8% citric acid solution (99.5 g) was added to the resulting mixture, and then, 2-propanol was evaporated under reduced pressure. To the resulting residue was added toluene (342 ml) for extraction; and the organic layer was concentrated under reduced pressure, to afford (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane (37.2 g) {the total yield of (2R,3S) and (2S,3S): 98.3%}, which was then analyzed by HPLC. (2R,3S): (2S,3R)=96.1:3.9.
2.4 g (96.2%) With sodium hydroxide; citric acid; In water; Example 18 Production of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane 2-Propanol (12.9 ml) and aqueous 6.08 mol/l sodium hydroxide solution (2.94 g) were added to a solution containing (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane obtained in Example 17 {(2R,3S) content of 2.79 g; (2S,3S) content of 83.9 mg}, for agitation at 4 C. for 15 hours. The resulting solution was analyzed by HPLC, which indicates that the objective (2R,3S) compound was at 94.0% (HPLC area ratio). After the reaction was quenched by the addition of aqueous 4.4% citric acid solution (20.9 g), the reaction solution was cooled from 25 C. to -10 C. over 2.3 hours; then, the seed crystal was added, followed by addition of water (19.2 ml) for overnight agitation, to crystallize (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane. By filtration of the resulting slurry, the crystal of the objective (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane was obtained {(2R,3S) yield: 2.4 g (96.2%)}. The dried crystal was then analyzed by HPLC. (2R,3S): (2S,3S)=97.9:2.1. Additionally, the purity of (2R,3S) was at 95.4% (HPLC area ratio).
With sodium hydroxide; citric acid; In water; Example 26 Production of Crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane The solution of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane {(2R,3S) content of 5.99 g; (2S,3S)content of 80 mg} obtained in the same manner as in Example 22 was concentrated, and then 2-propanol (30.8 ml) and water (10.3 ml) were added to the resulting residue. After cooling to 4 C., 4 mol/l sodium hydroxide solution (7.7 ml) was added, followed by agitation at 4 C. for 70 minutes. The reaction solution was analyzed by HPLC. The objective (2R,3S) compound was at 97.1% (HPLC area ratio). After the reaction was quenched by the addition of aqueous 1.5% citric acid solution, the resulting mixture was cooled to -3 C., followed by the addition of the seed crystal and agitation for 30 minutes. The mixture was cooled to -10 C. over 1 hour and was agitated for 2 hours, to crystallize (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane. After filtration of the resulting slurry, water (61.6 ml) was added to the resulting crystal, for preparing slurry, which was then agitated at ambient temperature for 30 minutes, to filtrate the slurry. The resulting crystal was dried to obtain the objective crystal of (2R,3S)-3-tert-butoxycarbonylamino-1,2-epoxy-4-phenylbutane {the yield of (2R,3S): 4.92 g (93.5%)}. The dry crystal was analyzed by HPLC. (2R,3S):(2S,3S)=97.9:2.1. Additionally, the purity of (2R,3S) was 98.3% (HPLC area ratio).
Reference: [1]Patent: US2002/72621,2002,A1
[2]Patent: US2002/72621,2002,A1
[3]Patent: US2002/72621,2002,A1
  • 16
  • lithium tri-t-butoxyaluminum hydride [ No CAS ]
  • [ 102123-74-0 ]
  • [ 112739-73-8 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
95% With potassium hydrogen sulphate; In diethyl ether; ethyl acetate; Reference Example 1 Production of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane Lithium aluminum tri-tert-butoxyhydride (999 mg) was added to dehydrated diethyl ether (29.3 ml); and the resulting mixture was cooled to 0° C. Subsequently, a diethyl ether solution (10 ml) of (3S)-3-tert-butoxycarbonylamino-1-chloro-4-phenyl-2-butanone (1.06 g) was dropwise added to the resulting mixture, for agitation at 0° C. for 2 hours and 20 minutes. To the reaction solution was added aqueous 5percent potassium hydrogen sulfate solution, to quench the reaction, which was then subjected to extraction twice in ethyl acetate; the organic layer was washed by aqueous saturated sodium chloride solution and dried over anhydrous magnesium sulfate. After magnesium sulfate was removed, the resulting ethyl acetate solution was analyzed by HPLC. It was confirmed that the diastereomer mixture of 3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane was obtained in 95percent yield. The ratio of the objective (2R,3S) compound and the diastereomer (2S,3S) was (2R,3S): (2S,3S)=84.7:15.3. The resulting solution was evaporated under reduced pressure, to afford crude (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (1.01 g).
Reference: [1]Patent: US2002/72621,2002,A1
  • 17
  • lithium tri-t-butoxyaluminum hydride [ No CAS ]
  • [ 102123-74-0 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
With hydrogenchloride; In diethyl ether; Reference Example 3 Production of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane Lithium aluminum tri-tert-butoxyhydride (28.2 g) was added to dehydrated diethyl ether (600 ml) in argon atmosphere, and the resulting mixture was cooled to 0° C., followed by addition of (3S)-3-tert-butoxycarbonylamino-1-chloro-4-phenyl-2-butanone (30.0 g), for agitation at 0° C. for 2.5 hours. To the reaction solution was added aqueous 1N hydrochloric acid solution (222 ml), to quench the reaction; the organic layer was washed by aqueous 1N hydrochloric acid solution and aqueous saturated sodium chloride solution; and the resulting organic layer was analyzed by HPLC. It was confirmed that the diastereomer mixture of 3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane was obtained in 92.0percent yield. The ratio of the objective (2R,3S) and the diastereomer (2S,3S) generated was (2R,3S): (2S,3S)=87.4:12.6. From the resulting solution was evaporated the solvent under reduced pressure, to afford crude (2R,3S)-3-tertbutoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (33.2 g).
Reference: [1]Patent: US2002/72621,2002,A1
  • 18
  • tri-tert-butoxy lithium aluminum hydride [ No CAS ]
  • [ 102123-74-0 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
In hydrogenchloride; methanol; diethyl ether; water; REFERENCE EXAMPLE 3 Production of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane Under an argon atmosphere, tri-tert-butoxy lithium aluminum hydride (4.7 g) was added to anhydrous diethyl ether (100 ml). The mixture was cooled to 0° C. and (3S)-3-tert-butoxycarbonylamino-1-chloro-4-phenyl-2-butanone (5.0 g) was added. The mixture was stirred at 0° C. for 3 hr. The reaction was quenched by adding 1N aqueous hydrochloric acid solution (37 ml) to the reaction mixture. The mixture was partitioned and the organic layer was washed with iN aqueous hydrochloric acid solution and saturated brine. The solvent was evaporated under reduced pressure and the residue was taken up into methanol (23.2 ml) added at room temperature. The obtained solution was analyzed by HPLC, and as a result, it was confirmed that a diastereomeric mixture of 3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane was obtained in a total yield of 92.1percent. The product ratio of the objective (2R,3S) compound: (2S,3S) compound (diastereomer thereof) was (2R,3S):(2S,3S)=87.4:12.6. The methanol solution was cooled to 0° C., and water (6 ml) was added. After inoculation of seed crystals, water (22.2 ml) was added dropwise over 1 hr, and the mixture was stirred for 2 hrs. The crystals were collected by filtration, washed twice with heptane (15 ml) and washed twice with water (25 ml). The obtained crystals were dried to give (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (4.30 g) in a yield of 85.4percent. The product ratio of the objective (2R,3S) compound: (2S,3S) compound (diastereomer thereof) was (2R,3S):(2S,3S)=87.0:13.0.
Reference: [1]Patent: US2002/151722,2002,A1
  • 19
  • [ 934971-02-5 ]
  • [ 24424-99-5 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
98.7% With triethylamine; In dichloromethane; at 20℃; under 760.051 Torr; for 2h; To a solution of (2R, 3S) -1-chloro-3-amino-4-phenyl-2-butanol 8 (74.7 g, 0.375 mol)Triethylamine (150 ml),Dichloromethane (150 ml)To the mixture was added dropwise a solution of di-tert-butyl dicarbonate (102.1 g, 0.468 mol)The reaction was carried out under normal temperature and pressure for 2 h.After completion of the reaction, the mixture was extracted, dried, filtered and concentrated under reduced pressure to give a white solid 9 (111 g, 98.7%)
95.3% With sodium hydroxide; In methanol; dichloromethane; water; at 25℃; for 2h;pH 7.0;Product distribution / selectivity; To the aqueous solution obtained in the above-mentioned step (3f) was added dichloromethane (10 ml), and 29% aqueous sodium hydroxide solution was further added to adjust the mixture to pH 7. Di-tert-butyldicarbonate (2.75 g) was added to the mixture, and the mixture was stirred at 25C for 2 hours. Stirring was stopped, the mixture was partitioned, and the organic layer was washed with water (10 ml). Dichloromethane was evaporated under reduced pressure, and methanol (17 ml) and water (4.4 ml) were added to the organic layer. The mixture was cooled to 0C, and a seed crystal of (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane was added. After stirring the organic layer at 0C for 1 hour, water (16.3 ml) was added dropwise over 30 minutes, and the mixture was further stirred for 1 hour. The slurry solution was filtered, and wet crystals were washed with a mixed solvent of ethyl acetate (0.2 ml) and heptane (10 ml). The obtained wet crystals were dried under reduced pressure at room temperature to give the object (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane as white crystals (2.99 g, 100 wt%, yield 95.3%). As a result of HPLC analysis, it was found that the peak area ratio of the compound was 99.7%, and its diastereomer ((2S,3S)-form) was not detected. 1H-NMR (CDCl3, 300 MHz); deltappm 1.38 (s, 9H), 2.91 (dd, J=8.1, 13.2Hz, 1H), 3.01 (dd, J=7.1, 13.2Hz, 1H), 3.14 (d, J=4.0Hz, 1H), 3.53 (s, 1H), 3.55 (d, J=2.3Hz, 1H), 3.70-3.77 (m, 1H), 3.79-3.89 (m, 1H), 4.88 (bd, 1H), 7.19-7.35 (m, 5H) mass spectrum m/e; 322 (M+Na+) [alpha]D20 = -28.3 (c = 0.50, CH2Cl2)
Reference: [1]Patent: CN105152978,2017,B .Location in patent: Paragraph 0035; 0038; 0053; 0054; 0088
[2]Patent: EP1777213,2007,A1 .Location in patent: Page/Page column 20
  • 20
  • [ 369362-96-9 ]
  • [ 24424-99-5 ]
  • [ 165727-45-7 ]
  • [ 162536-40-5 ]
YieldReaction ConditionsOperation in experiment
With sodium hydroxide; In methanol; water; toluene; at 25℃; for 3h;pH 7;Product distribution / selectivity; To an aqueous solution of (2R,3S)-3-amino-1-chloro-2-hydroxy-4-phenylbutane hydrochloride (74.4 g) containing its (2S,3S)-form as a diastereomer thereof, which had been obtained in the above-mentioned step (2'f), was added toluene (378 ml), and the mixture was vigorously stirred. The mixture was adjusted to pH 7 with 4 M aqueous sodium hydroxide solution. Keeping pH 7 with 4 M aqueous sodium hydroxide solution, the mixture was added to a mixed solution of di-tert-butyldicarbonate (68.7 g) and toluene (94 ml), and the mixture was vigorously stirred at 25C for 3 hours. The organic layer (606.4 g) was separated, cooled to 0C and filtered. As a result of HPLC analysis, it was found that the filtrate contained (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane (64.9 g, yield 68%), and the diastereomer ratio (2R,3S)/(2S,3S) was 95/5. In addition, the peak area ratio of other byproduct was 19.5% relative to (2R,3S)-3-tert-butoxycarbonylamino-1-chloro-2-hydroxy-4-phenylbutane.
Reference: [1]Patent: EP1777213,2007,A1 .Location in patent: Page/Page column 21
  • 21
  • [ 162536-40-5 ]
  • [ 1192510-20-5 ]
Reference: [1]Patent: WO2013/14633,2013,A1
[2]Patent: US2014/343290,2014,A1
  • 22
  • [ 162536-40-5 ]
  • [ 198905-04-3 ]
Reference: [1]Patent: WO2013/14633,2013,A1
[2]Patent: US2014/343290,2014,A1
  • 23
  • [ 162536-40-5 ]
  • 1-[4-(pyridine-2-yl)-phenyl]-4(S)-hydroxy-2-amino-5(S)-N-(N-methoxycarbonyl-(L)-tert-leucyl)amino-6-phenyl-2-azahexane dihydrochioride [ No CAS ]
Reference: [1]Patent: WO2013/14633,2013,A1
[2]Patent: US2014/343290,2014,A1
  • 24
  • [ 162536-40-5 ]
  • [ 198904-31-3 ]
Reference: [1]Patent: WO2013/14633,2013,A1
[2]Patent: US2014/343290,2014,A1
  • 25
  • [ 162536-40-5 ]
  • atazanavir sulphate [ No CAS ]
Reference: [1]Patent: WO2013/14633,2013,A1
[2]Patent: US2014/343290,2014,A1
  • 26
  • [ 162536-40-5 ]
  • [ 369362-96-9 ]
YieldReaction ConditionsOperation in experiment
32 g With hydrogenchloride; water; In tetrahydrofuran; at 50 - 55℃; for 4h; Example 1(A): Preparation of f2S.3RV2-Amino-4-chloro-l-phenylbutan-3-ol hydrochloride Formula III To 1 , 1 -dimethylethyl [(2S,3R)-4-chloro-3-hydroxy- l-phenylbutan-2-yl]carbamate (Formula II, 40 g), tetrahydrofuran (200 mL) was added at ambient temperature under stirring. Concentrated hydrochloric acid (27 mL) was slowly added to the mixture. The resultant reaction mixture was heated at 50C to 55C for 4 hours. Tetrahydrofuran was recovered under vacuum from the reaction mixture at 50C to 55C. Water was removed by adding additional tetrahydrofuran (200 mL) to get the semi-solid product. The semisolid product was crystallized with a mixture of ethyl acetate (80 mL) and diisopropyl ether (200 mL) and further stirred for 2 hours at 20C to 25C. The solid so obtained was filtered and dried under vacuum at 40C to 45C to afford the title compound. Weight: 32.0 g Yield (w/w): 0.8
With hydrogenchloride; In tetrahydrofuran; water; at 50 - 55℃; for 4h; Example 1(A) Preparation of (2S,3R)-2-Amino-4-chloro-1-phenylbutan-3-ol hydrochloride To 1,1-dimethylethyl[(2S,3R)-4-chloro-3-hydroxy-1-phenylbutan-2-yl]carbamate (Formula II, 40 g), tetrahydrofuran (200 mL) was added at ambient temperature under stirring. Concentrated hydrochloric acid (27 mL) was slowly added to the mixture. The resultant reaction mixture was heated at 50 C. to 55 C. for 4 hours. Tetrahydrofuran was recovered under vacuum from the reaction mixture at 50 C. to 55 C. Water was removed by adding additional tetrahydrofuran (200 mL) to get the semi-solid product. The semi-solid product was crystallized with a mixture of ethyl acetate (80 mL) and diisopropyl ether (200 mL) and further stirred for 2 hours at 20 C. to 25 C. The solid so obtained was filtered and dried under vacuum at 40 C. to 45 C. to afford the title compound. Weight: 32.0 g
Reference: [1]Patent: WO2013/14633,2013,A1 .Location in patent: Page/Page column 13
[2]Patent: US2014/343290,2014,A1 .Location in patent: Paragraph 0055; 0056; 0057; 0058
  • 27
  • [ 162536-40-5 ]
  • methyl [(2S)-1-[(2S,3R)-4-chloro-3-hydroxy-1-phenylbutan-2-yl]amino}-3,3-dimethyl-1-oxobutan-2-yl]carbamate [ No CAS ]
Reference: [1]Patent: WO2013/14633,2013,A1
  • 28
  • C26H27NO4 [ No CAS ]
  • [ 162536-40-5 ]
Reference: [1]Patent: CN105152978,2017,B
  • 29
  • C24H23N3O [ No CAS ]
  • [ 162536-40-5 ]
Reference: [1]Patent: CN105152978,2017,B
  • 30
  • [ 171815-94-4 ]
  • [ 162536-40-5 ]
Reference: [1]Patent: CN105152978,2017,B
  • 31
  • [ 63-91-2 ]
  • [ 162536-40-5 ]
Reference: [1]Patent: CN105152978,2017,B
  • 32
  • [ 111138-83-1 ]
  • [ 162536-40-5 ]
Reference: [1]Patent: CN105152978,2017,B
  • 33
  • N,N-dibenzyl-L-phenylalanine hydrochloride [ No CAS ]
  • [ 162536-40-5 ]
Reference: [1]Patent: CN105152978,2017,B

Tags: 162536-40-5 synthesis path| 162536-40-5 SDS| 162536-40-5 COA| 162536-40-5 purity| 162536-40-5 application| 162536-40-5 NMR| 162536-40-5 COA| 162536-40-5 structure

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