CA2710107A1 - Recovering unreacted intermediate from desalinated and desolventized dimerisation reaction mixture by ultrafiltration - Google Patents
Recovering unreacted intermediate from desalinated and desolventized dimerisation reaction mixture by ultrafiltration Download PDFInfo
- Publication number
- CA2710107A1 CA2710107A1 CA 2710107 CA2710107A CA2710107A1 CA 2710107 A1 CA2710107 A1 CA 2710107A1 CA 2710107 CA2710107 CA 2710107 CA 2710107 A CA2710107 A CA 2710107A CA 2710107 A1 CA2710107 A1 CA 2710107A1
- Authority
- CA
- Canada
- Prior art keywords
- iodixanol
- compound
- bis
- reaction mixture
- ultrafiltration
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
Abstract
This invention relates generally to industrial preparation of iodixanol (1,3-bis(acetamido)-N,N'-bis[3,5-bis(2,3-dihydroxypropylaminocarbonyl)-2,4,6-triiodophenyl]-2-hydroxypropane), a non-ionic X-ray contrasting agent. It further relates to a method of recovering intermediate 5-acetamido-N,N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodoisophthalamide ("Compound A") from the desalinated and desolventized dimerisation reaction mixture. In particular, the present invention employs ultrafiltration to recover non-crystalline Compound A to reduce the overall cost of iodixanol manufacture, increase the yield of iodixanol, and facilitate the subsequent purification procedures to meet the regulatory purity requirement of iodixanol.
Description
Recovering Unreacted Intermediate From Desalinated and Desolventized Dimerisation Reaction Mixture By Ultrafiltration CROSS REFERENCE TO RELATED APPLICATIONS
The present application claims benefit of priority under 35 U.S.C. 119(e) to United States Provisional Application number 61/227,102 filed July 21, 2009, the entire disclosure of which is hereby incorporated by reference.
TECHNICAL FIELD
This invention relates generally to industrial preparation of iodixanol (1,3-bis(acetamido)-N,N'-bis[3,5-bis(2,3-dihydroxypropylaminocarbonyl)-2,4,6-triiodophenyl]-2-hydroxypropane), a non-ionic X-ray contrasting agent. It further relates to a method of recovering intermediate 5-acetamido-N,N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodoisophthalamide ("Compound A") from a desalinated and desolventized dimerisation reaction mixture. In particular, the present invention employs uitrafiltration prior to the crystallisation of iodixanol to recover non-crystalline Compound A where the permeate contains less than about 8 % of Compound A by weight relative to iodixanol.
BACKGROUND OF THE INVENTION
lodixanol is the non-proprietary name of the chemical drug substance, 1,3-bis(acetamido)-N,N'-bis[3,5-bis(2,3-dihydroxypropylaminocarbonyl)-2,4 ,6-triiodophenyl]-2-hydroxypropane). Marketed under the trade name Visipaque , Iodixanol is one of the most used agents in diagnostic X-ray procedures. It is produced in large quantities by GE
Healthcare in Lindesnes, Norway. The manufacture of Iodixanol requires the production of the chemical drug substance (referred to as primary production) followed by formulation into the drug product (referred to as secondary production). The primary production of Iodixanol involves a multistep chemical synthesis and a thorough purification process.
It is important for the primary production to be efficient and economical and to provide a drug substance fulfilling the regulatory specifications, such as those mandated by US
Pharmacopeia. In addition, the cost and efficiency of the secondary production depend on the synthesis and purification processes in the primary production. Thus, optimization is desired in each step of the primary production of Iodixanol.
The industrial synthesis of iodixanol involves dimerisation of intermediate 5-acetamido-N,N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodoisophthalamide ("Compound A") as the final synthetic step as shown in Scheme 1 below.
CH O O OH
HO 0 3 1-amino-2,3- HO N O
CH3OH / propanediol LNO offHO z CH30 \ NO2 HO,_ N \ I NO
0 0 NO, O
OH OH
~ ICI Acetic OH OH 1 i 1 Anhydride H
HON HO~~N
NH, NHz Compound B
OH
H 01l OH
HO N O Epichloro- HO ,J,, N O O N OH
HO OH { { hydrin 1 { 1 I H 11 OH OH
NH FIO ,),, N \ N \N \ N 011 O I
Compound A
lodixanol Scheme I
The dimerisation of Compound A to iodixanol leads to a conversion of about 55-60 %
of the starting material. Most of the unreacted Compound A is subsequently removed and recovered from the reaction solution by addition of hydrochloric acid, which allows for precipitation of neutral Compound A from the reaction solution. See U.S.
Patent No.
6,974,882. Despite the initial removal and recovery of Compound A, a considerable amount of Compound A, about 14-18 % relative to iodixanol, remains in the reaction solution. There exists a need for a cost-effective industrial process for the recovery of this additional Compound A.
The present application claims benefit of priority under 35 U.S.C. 119(e) to United States Provisional Application number 61/227,102 filed July 21, 2009, the entire disclosure of which is hereby incorporated by reference.
TECHNICAL FIELD
This invention relates generally to industrial preparation of iodixanol (1,3-bis(acetamido)-N,N'-bis[3,5-bis(2,3-dihydroxypropylaminocarbonyl)-2,4,6-triiodophenyl]-2-hydroxypropane), a non-ionic X-ray contrasting agent. It further relates to a method of recovering intermediate 5-acetamido-N,N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodoisophthalamide ("Compound A") from a desalinated and desolventized dimerisation reaction mixture. In particular, the present invention employs uitrafiltration prior to the crystallisation of iodixanol to recover non-crystalline Compound A where the permeate contains less than about 8 % of Compound A by weight relative to iodixanol.
BACKGROUND OF THE INVENTION
lodixanol is the non-proprietary name of the chemical drug substance, 1,3-bis(acetamido)-N,N'-bis[3,5-bis(2,3-dihydroxypropylaminocarbonyl)-2,4 ,6-triiodophenyl]-2-hydroxypropane). Marketed under the trade name Visipaque , Iodixanol is one of the most used agents in diagnostic X-ray procedures. It is produced in large quantities by GE
Healthcare in Lindesnes, Norway. The manufacture of Iodixanol requires the production of the chemical drug substance (referred to as primary production) followed by formulation into the drug product (referred to as secondary production). The primary production of Iodixanol involves a multistep chemical synthesis and a thorough purification process.
It is important for the primary production to be efficient and economical and to provide a drug substance fulfilling the regulatory specifications, such as those mandated by US
Pharmacopeia. In addition, the cost and efficiency of the secondary production depend on the synthesis and purification processes in the primary production. Thus, optimization is desired in each step of the primary production of Iodixanol.
The industrial synthesis of iodixanol involves dimerisation of intermediate 5-acetamido-N,N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodoisophthalamide ("Compound A") as the final synthetic step as shown in Scheme 1 below.
CH O O OH
HO 0 3 1-amino-2,3- HO N O
CH3OH / propanediol LNO offHO z CH30 \ NO2 HO,_ N \ I NO
0 0 NO, O
OH OH
~ ICI Acetic OH OH 1 i 1 Anhydride H
HON HO~~N
NH, NHz Compound B
OH
H 01l OH
HO N O Epichloro- HO ,J,, N O O N OH
HO OH { { hydrin 1 { 1 I H 11 OH OH
NH FIO ,),, N \ N \N \ N 011 O I
Compound A
lodixanol Scheme I
The dimerisation of Compound A to iodixanol leads to a conversion of about 55-60 %
of the starting material. Most of the unreacted Compound A is subsequently removed and recovered from the reaction solution by addition of hydrochloric acid, which allows for precipitation of neutral Compound A from the reaction solution. See U.S.
Patent No.
6,974,882. Despite the initial removal and recovery of Compound A, a considerable amount of Compound A, about 14-18 % relative to iodixanol, remains in the reaction solution. There exists a need for a cost-effective industrial process for the recovery of this additional Compound A.
SUMMARY OF THE INVENTION
The present invention provides a process for recovering a key intermediate in the synthesis of iodixanol. It further relates to recycling residual non-crystalline Compound A
before the initiation of the crystallisation process for iodixanol.
Specifically, the instant invention is directed to the sequential steps of (1) reducing the salt and solvent content in a dimerisation reaction mixture containing Compound A and iodixanol to precipitate Compound A in a non-crystalline form; (2) passing the mixture of step (1) through an ultrafiltration membrane; (3) recovering non-crystalline Compound A in the retentate of step (2) for reuse in a subsequent dimerisation reaction to prepare iodixanol; and (4) crystallising iodixanol from the permeate of step (2) wherein the weight content of Compound A in the permeate is less than about 8% relative to that of iodixanol. A suitable ultrafiltration system may include tubular, spiral or hollow fibre based systems.
The present procedure represents an optimal industrial process. In particular, the wastage of Compound A is minimized without adding excessive time or incurring substantial cost. In addition, the iodixanol solution before its crystallisation contains sufficiently less Compound A to enable the final iodixanol product to meet the regulatory requirement.
DETAILED DESCRIPTION OF THE INVENTION
Following the acid quenching of the dimerisation reaction from Compound A to iodixanol and the initial recovery of unreacted Compound A by precipitation, about 14-18 %
of Compound A (relative to iodixanol by weight) is still dissolved in solution. The dissolved Compound A, along with the iodixanol product in solution, could be fed to the next process step without any discrete recovery step for Compound A. This procedure however presents several problems.
First, the unrecovered Compound A represents a loss of valuable intermediate in the primary production of iodixanol. This waste of Compound A is significant because it is the last intermediate in the iodixanol manufacture and because it contains iodine, the most expensive reagent in the chemical synthesis. Any loss of Compound A increases the overall cost of the primary production of iodixanol.
Second, Compound A can be reused in a subsequent dimerisation reaction to prepare iodixanol. In other words, the additional Compound A in solution with iodixanol can be converted to iodixanol in a new dimerisation reaction. The unrecovered Compound A thus lowers the effective production yield of iodixanol.
Finally, we have found that a high content of Compound A in the feed to subsequent crystallisation steps of iodixanol makes it difficult to obtain the required purity of the final iodixanol product.
To address these issues, an effective and efficient method has been found to recover the additional soluble Compound A. Specifically, the reduction of salt content of the dimerisation reaction mixture causes the solubility of Compound A to decrease, which leads to the precipitation of Compound A. In addition, the amount of solvent is reduced along with the salt content, which again contributes to the precipitation of Compound A
due to its poor solubility in water.
We have found that the precipitated Compound A during the salt and solvent reduction process is largely non-crystalline. However, conventional filtration techniques, such as pressure or vacuum filtration, are not suitable for an industrial scale recovery of Compound A due to a variety of factors, such as the added cost and time, the compatibility with the existing iodixanol primary production operation, and the loss of iodixanol.
On the other hand, the additional Compound A precipitated during desalination and desolventization can be efficiently removed by ultrafiltration with minimal addition of time and cost. Further, the ultrafiltration cake can be combined with the precipitated Compound A
from the previous hydrochloric acid precipitation step. Pooling Compound A
from two separate recovery steps gives a net yield increase in the process of primary production of iodixanol and enhances the economy of production considerably.
Another improvement of the instant process is that the content of Compound A
in the process solution subjected to iodixanol crystallisation is reduced to a level that the residual Compound A in the ultrafiltration permeate does not interfere with the subsequent crystallisation of iodixanol. In certain embodiments, the level of compound A
in the crystallisation feed is between about 4 and about 8 w/w % relative to iodixanol. It has been found that this relative small amount of Compound A left in the permeate solution containing iodixanol after ultrafiltration can be removed in the crystallisation process for iodixanol without the need for expensive and time consuming reprocessing steps.
Yet another improvement of the instant process is that the loss of the main product iodixanol is kept at a minimal during ultrafiltration. The solubility of iodixanol in water has been found to be high enough such that it does not precipitate during the instant process of recovering additional Compound A.
The invention is illustrated further by the following examples that are not to be construed as limiting the invention in scope to the specific procedures described in them.
EXAMPLES
A reaction mixture containing about 340 kg iodixanol and substantial amounts of Compound A (about 14-18 w/w % relative to iodixanol) and iohexol (6-8 w/w %
relative to iodixanol) is subjected to nanofiltration. Water is added continuously to facilitate diafiltration followed by volume reduction. A final salt concentration of about 0.60 w/w %
relative to iodixanol (2.0 kg NaCI in 340 kg iodixanol) is obtained. At this stage, the reaction medium is aqueous with the pH between about 4 and 6. Compound A is precipitated on the retentate side of the nanofiltration membrane due to reduced salt and organic solvent content. The organic solvent is 2-methoxyethanol.
The precipitated Compound A is removed from the process solution by ultrafiltration using a PallsepTM PS400 vibrating membrane system at ambient temperature with the pH
between about 5 and 7.5. At the end of the ultrafiltration step water is added continuously to facilitate diafiltration in order to flush out any remaining iodixanol on the retentate side. The diafiltration step is terminated when almost pure water flows through the ultrafilter, detected by a density of the permeate of less than 1.005 kg/L. The last fraction of permeate is led to a different stream than the main process solution for later re-use in an earlier step to avoid dilution of the product mixture before crystallisation. The Compound A content in the main filtrate is about 4 to about 7 % (w/w) relative to iodixanol content. The filtrate is subjected to crystallisation and subsequent purification steps to obtain the necessary purity.
A reaction mixture containing about 340 kg iodixanol and substantial amounts of Compound A (about 14-18 w/w % relative to iodixanol) and iohexol (6-8 w/w %
relative to iodixanol) is subjected to nanofiltration. Water is added continuously to facilitate diafiltration followed by volume reduction. A final salt concentration of about 0.60 w/w %
relative to iodixanol (2.0 kg NaCl in 340 kg iodixanol) is obtained. At this stage, the reaction medium is aqueous with the pH between about 4 and 6. Compound A is precipitated on the retentate side of the nanofiltration membrane due to reduced salt and organic solvent content. The organic solvent is methanol.
The precipitated Compound A is removed from the process solution by ultrafiltration using a PallsepT"' PS400 vibrating membrane system at ambient temperature with the pH
between about 5 and 7.5. At the end of the ultrafiltration step water is added continuously to facilitate diafiltration in order to flush out any remaining iodixanol on the retentate side. The diafiltration step is terminated when almost pure water flows through the ultrafilter, detected by a density of the permeate of less than 1.005 kg/L. The last fraction of permeate is led to a different stream than the main process solution for later re-use in an earlier step to avoid dilution of the product mixture before crystallisation. The Compound A content in the main filtrate is about 4 to about 7 % (w/w) relative to iodixanol content. The filtrate is subjected to crystallisation and subsequent purification steps to obtain the necessary purity.
All patents, journal articles, publications and other documents discussed and/or cited above are hereby incorporated by reference.
The present invention provides a process for recovering a key intermediate in the synthesis of iodixanol. It further relates to recycling residual non-crystalline Compound A
before the initiation of the crystallisation process for iodixanol.
Specifically, the instant invention is directed to the sequential steps of (1) reducing the salt and solvent content in a dimerisation reaction mixture containing Compound A and iodixanol to precipitate Compound A in a non-crystalline form; (2) passing the mixture of step (1) through an ultrafiltration membrane; (3) recovering non-crystalline Compound A in the retentate of step (2) for reuse in a subsequent dimerisation reaction to prepare iodixanol; and (4) crystallising iodixanol from the permeate of step (2) wherein the weight content of Compound A in the permeate is less than about 8% relative to that of iodixanol. A suitable ultrafiltration system may include tubular, spiral or hollow fibre based systems.
The present procedure represents an optimal industrial process. In particular, the wastage of Compound A is minimized without adding excessive time or incurring substantial cost. In addition, the iodixanol solution before its crystallisation contains sufficiently less Compound A to enable the final iodixanol product to meet the regulatory requirement.
DETAILED DESCRIPTION OF THE INVENTION
Following the acid quenching of the dimerisation reaction from Compound A to iodixanol and the initial recovery of unreacted Compound A by precipitation, about 14-18 %
of Compound A (relative to iodixanol by weight) is still dissolved in solution. The dissolved Compound A, along with the iodixanol product in solution, could be fed to the next process step without any discrete recovery step for Compound A. This procedure however presents several problems.
First, the unrecovered Compound A represents a loss of valuable intermediate in the primary production of iodixanol. This waste of Compound A is significant because it is the last intermediate in the iodixanol manufacture and because it contains iodine, the most expensive reagent in the chemical synthesis. Any loss of Compound A increases the overall cost of the primary production of iodixanol.
Second, Compound A can be reused in a subsequent dimerisation reaction to prepare iodixanol. In other words, the additional Compound A in solution with iodixanol can be converted to iodixanol in a new dimerisation reaction. The unrecovered Compound A thus lowers the effective production yield of iodixanol.
Finally, we have found that a high content of Compound A in the feed to subsequent crystallisation steps of iodixanol makes it difficult to obtain the required purity of the final iodixanol product.
To address these issues, an effective and efficient method has been found to recover the additional soluble Compound A. Specifically, the reduction of salt content of the dimerisation reaction mixture causes the solubility of Compound A to decrease, which leads to the precipitation of Compound A. In addition, the amount of solvent is reduced along with the salt content, which again contributes to the precipitation of Compound A
due to its poor solubility in water.
We have found that the precipitated Compound A during the salt and solvent reduction process is largely non-crystalline. However, conventional filtration techniques, such as pressure or vacuum filtration, are not suitable for an industrial scale recovery of Compound A due to a variety of factors, such as the added cost and time, the compatibility with the existing iodixanol primary production operation, and the loss of iodixanol.
On the other hand, the additional Compound A precipitated during desalination and desolventization can be efficiently removed by ultrafiltration with minimal addition of time and cost. Further, the ultrafiltration cake can be combined with the precipitated Compound A
from the previous hydrochloric acid precipitation step. Pooling Compound A
from two separate recovery steps gives a net yield increase in the process of primary production of iodixanol and enhances the economy of production considerably.
Another improvement of the instant process is that the content of Compound A
in the process solution subjected to iodixanol crystallisation is reduced to a level that the residual Compound A in the ultrafiltration permeate does not interfere with the subsequent crystallisation of iodixanol. In certain embodiments, the level of compound A
in the crystallisation feed is between about 4 and about 8 w/w % relative to iodixanol. It has been found that this relative small amount of Compound A left in the permeate solution containing iodixanol after ultrafiltration can be removed in the crystallisation process for iodixanol without the need for expensive and time consuming reprocessing steps.
Yet another improvement of the instant process is that the loss of the main product iodixanol is kept at a minimal during ultrafiltration. The solubility of iodixanol in water has been found to be high enough such that it does not precipitate during the instant process of recovering additional Compound A.
The invention is illustrated further by the following examples that are not to be construed as limiting the invention in scope to the specific procedures described in them.
EXAMPLES
A reaction mixture containing about 340 kg iodixanol and substantial amounts of Compound A (about 14-18 w/w % relative to iodixanol) and iohexol (6-8 w/w %
relative to iodixanol) is subjected to nanofiltration. Water is added continuously to facilitate diafiltration followed by volume reduction. A final salt concentration of about 0.60 w/w %
relative to iodixanol (2.0 kg NaCI in 340 kg iodixanol) is obtained. At this stage, the reaction medium is aqueous with the pH between about 4 and 6. Compound A is precipitated on the retentate side of the nanofiltration membrane due to reduced salt and organic solvent content. The organic solvent is 2-methoxyethanol.
The precipitated Compound A is removed from the process solution by ultrafiltration using a PallsepTM PS400 vibrating membrane system at ambient temperature with the pH
between about 5 and 7.5. At the end of the ultrafiltration step water is added continuously to facilitate diafiltration in order to flush out any remaining iodixanol on the retentate side. The diafiltration step is terminated when almost pure water flows through the ultrafilter, detected by a density of the permeate of less than 1.005 kg/L. The last fraction of permeate is led to a different stream than the main process solution for later re-use in an earlier step to avoid dilution of the product mixture before crystallisation. The Compound A content in the main filtrate is about 4 to about 7 % (w/w) relative to iodixanol content. The filtrate is subjected to crystallisation and subsequent purification steps to obtain the necessary purity.
A reaction mixture containing about 340 kg iodixanol and substantial amounts of Compound A (about 14-18 w/w % relative to iodixanol) and iohexol (6-8 w/w %
relative to iodixanol) is subjected to nanofiltration. Water is added continuously to facilitate diafiltration followed by volume reduction. A final salt concentration of about 0.60 w/w %
relative to iodixanol (2.0 kg NaCl in 340 kg iodixanol) is obtained. At this stage, the reaction medium is aqueous with the pH between about 4 and 6. Compound A is precipitated on the retentate side of the nanofiltration membrane due to reduced salt and organic solvent content. The organic solvent is methanol.
The precipitated Compound A is removed from the process solution by ultrafiltration using a PallsepT"' PS400 vibrating membrane system at ambient temperature with the pH
between about 5 and 7.5. At the end of the ultrafiltration step water is added continuously to facilitate diafiltration in order to flush out any remaining iodixanol on the retentate side. The diafiltration step is terminated when almost pure water flows through the ultrafilter, detected by a density of the permeate of less than 1.005 kg/L. The last fraction of permeate is led to a different stream than the main process solution for later re-use in an earlier step to avoid dilution of the product mixture before crystallisation. The Compound A content in the main filtrate is about 4 to about 7 % (w/w) relative to iodixanol content. The filtrate is subjected to crystallisation and subsequent purification steps to obtain the necessary purity.
All patents, journal articles, publications and other documents discussed and/or cited above are hereby incorporated by reference.
Claims
1. A process for recovering 5-acetamido-N,N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodoisophthalamide ("Compound A") after desalination and desolventization of a dimerisation reaction mixture of Compound A to iodixanol comprising the sequential steps of:
(1) reducing salt and solvent content in the dimerisation reaction mixture containing Compound A and iodixanol to precipitate Compound A in a non-crystalline form;
(2) passing the mixture of step (1) through an ultrafiltration membrane;
(3) recovering non-crystalline Compound A in the retentate of step (2) for reuse in a subsequent dimerisation reaction to prepare iodixanol; and (4) crystallising iodixanol from the permeate of step (2) wherein the weight content of Compound A in the permeate is less than about 8 % relative to that of iodixanol.
(1) reducing salt and solvent content in the dimerisation reaction mixture containing Compound A and iodixanol to precipitate Compound A in a non-crystalline form;
(2) passing the mixture of step (1) through an ultrafiltration membrane;
(3) recovering non-crystalline Compound A in the retentate of step (2) for reuse in a subsequent dimerisation reaction to prepare iodixanol; and (4) crystallising iodixanol from the permeate of step (2) wherein the weight content of Compound A in the permeate is less than about 8 % relative to that of iodixanol.
Applications Claiming Priority (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US22710209P | 2009-07-21 | 2009-07-21 | |
US61/227,102 | 2009-07-21 | ||
US12/620,691 | 2009-11-18 | ||
US12/620,691 US20110021828A1 (en) | 2009-07-21 | 2009-11-18 | Recovering unreacted intermediate from desalinated and desolventized dimerisation reaction mixture by ultrafiltration |
Publications (1)
Publication Number | Publication Date |
---|---|
CA2710107A1 true CA2710107A1 (en) | 2011-01-21 |
Family
ID=43495939
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA 2710107 Abandoned CA2710107A1 (en) | 2009-07-21 | 2010-07-20 | Recovering unreacted intermediate from desalinated and desolventized dimerisation reaction mixture by ultrafiltration |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA2710107A1 (en) |
-
2010
- 2010-07-20 CA CA 2710107 patent/CA2710107A1/en not_active Abandoned
Similar Documents
Publication | Publication Date | Title |
---|---|---|
JP4545945B2 (en) | Production of iodixanol | |
EP1960349B1 (en) | Purification of iodixanol | |
AU2005272229B2 (en) | Preparation of iodixanol | |
US20110021828A1 (en) | Recovering unreacted intermediate from desalinated and desolventized dimerisation reaction mixture by ultrafiltration | |
US7968745B2 (en) | Purification process of iodixanol | |
EP2281623A1 (en) | Processing crude iodixanol mixture by nanofiltration | |
EP2281811A1 (en) | A continuous deacetylation and purification process in the synthesis of non-ionic X-ray contrast agents | |
JP6506759B2 (en) | Alternative process for purifying intermediates in the synthesis of non-ionic X-ray contrast agents | |
JP2018115193A (en) | Purification of x-ray contrast agents | |
EP3077368B1 (en) | Alternative process for the purification of an intermediate in the synthesis of non-ionic x-ray contrast agents | |
CA2710107A1 (en) | Recovering unreacted intermediate from desalinated and desolventized dimerisation reaction mixture by ultrafiltration | |
EP2277859A1 (en) | Acetylation using reduced concentration of acetic acid anhydride for synthesizing non-ionic X-ray contrast agents | |
CA2707173C (en) | Crystallization of iodixanol in isopropanol and methanol | |
EP2277851A1 (en) | Acetylation using reduced volume of acetic acid anhydride for synthesizing non-ionic X-ray contrast agents | |
EP2281803A1 (en) | Improvements in crystallization of 5-amino-N,N'-bis(2,3-dihydroxypropyl)-2,4,6,-triiodo-isophthalamide, an intermediate for synthesizing non-ionic X-ray contrast agents | |
CA2710489A1 (en) | Processing crude iodixanol mixture by nanofiltration | |
CA2710090A1 (en) | Acetylation using reduced volume of acetic acid anhydride for synthesizing non-ionic x-ray contrast agents | |
CA2710102A1 (en) | Improvements in crystallization of an intermediate for synthesizing non-ionic x-ray contrast agents | |
CA2710570A1 (en) | Acetylation using reduced concentration of acetic acid anhydride for synthesizing non-ionic x-ray contrast agents | |
CA2710594A1 (en) | A continuous deacetylation and purification process in synthesis of non-ionic x-ray contrast agents |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
FZDE | Dead |
Effective date: 20130722 |