Patent Description:
Penem antibiotics, namely carbapenem antibiotics, belong to β-lactam antibacterial drugs, it has the strong antibacterial activity and a broad antibacterial spectrum. This drug is clinically suitable for treatment of the following moderate and severe infections caused by sensitive bacteria: complicated abdominal cavity infection, complicated skin and soft tissue infection, community-acquired pneumonia, complicated urinary tract infection, acute pelvic infection, severe enterobacteriaceae bacterial infection and the like. Therefore, the drug has a broad application prospect.

At present, an industrial scale-up production technology mainly uses batch chemical technology production (namely batch reaction production). A solvent, a raw material and a rhodium catalyst are put into a reaction kettle in sequence, and the temperature is raised to perform a cyclization reaction. After an obtained intermediate is cooled, a diphenyl chlorophosphate and a diisopropylethylamine are sequentially added to perform an esterification reaction at a low temperature. After the system is subjected to post-treatment operations such as quenching and crystallizing, a penem intermediate MAP is obtained. For example, Korean patent application with the patent application publication number <CIT>.

A discloses using rhodium acetate as a catalyst, catalysing the reaction of <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate to obtain an intermediate, then the intermediate is reacted with reaction raw materials such as phosphoryl chloride, etc. to obtain a Penan intermediate MAP, and the preparation method has the problem of relatively low reaction efficiency. The patent application with application publication number <CIT> discloses a process for continuous synthesis of a penem antibiotic parent nucleus MAP, in which methyl tert-butyl ketone is used as a solvent to dissolve (<NUM>,4R)-<NUM>(R)-<NUM>-hydroxyethyl)-<NUM>-((1R)-<NUM>-methyl-<NUM>-diazo-<NUM>-p-nitrobenzyloxyformyl-<NUM>-one-propyl)-<NUM>-azetidinone, rhodium octanoate dimer is used as a catalyst, and the intermediate is prepared by a continuous reaction in a first-level pipeline reactor; and the diphenyl chlorophosphate and N,N-diisopropylethyl ammonia are mixed to form a mixture II, and the intermediate is cooled and continuously reacts with the mixture II in a two-level pipeline reactor to prepare the penem antibiotic parent nucleus MAP. However, the reaction temperature in the one-level pipeline reactor of this process is <NUM>-<NUM> to achieve a higher product yield, but the reaction temperature in the two-level pipeline reactor is between -<NUM>~-<NUM>, and the temperature difference between the two is larger, therefore the intermediate needs to be cooled, so that the energy consumption is higher, especially while it is scaled up to an industrial application, it is caused that the production cost of MAP is larger, and the economic benefits for producers are reduced.

A main purpose of the present invention is to provide a continuous preparation method for a penem intermediate MAP, as to solve a problem in an existing technology that a process of continuously preparing the penem intermediate MAP is high in energy consumption.

In order to achieve the above purpose, according to one aspect of the present invention, a continuous preparation method for a penem intermediate MAP is provided, comprising: step S1, in a column-type continuous reactor, using a rhodium-loaded catalyst to catalyze <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate to generate a cyclization reaction so as to form a first intermediate, wherein the rhodium-loaded catalyst is loaded in the column-type continuous reactor, and the rhodium-loaded catalyst has the following structural formula:
<CHM>
wherein R<NUM> represents any one alkyl of C1-C10; P-COO-represents a residue of a polymer after dehydrogenation, and x represents an arbitrary number of <NUM>-<NUM>; step S2, performing an esterification reaction on the first intermediate, a diphenyl chlorophosphate and a diisopropylethylamine in a second continuous reactor, to obtain a product system containing the penem intermediate MAP; and step S3, performing crystallization treatment on the product system, to obtain the penem intermediate MAP;.

Further, the column-type continuous reactor comprises a reacting column, and installed from bottom to top, the reacting column comprises: a feeding section, provided with a liquid inlet, and a liquid distributing device is installed above the liquid inlet; a reacting section, wherein the reacting section is isolated from the feeding section through a porous bottom plate, the reacting section is internally filled with an inert filler and the rhodium-loaded catalyst and provided with multiple circumferentially arranged first separating plates, and each of the first separating plate is extended along a vertical direction so that a cavity of the reacting section is separated to multiple first reacting chambers; and a discharging section, wherein the discharging section is isolated from the reacting section through a porous top plate, and the discharging section is provided with a liquid-state product outlet and an exhaust port.

Further, a second separating plate is further installed in the cavity of the reacting section, the second separating plate is a cylinder-like separating plate coaxially installed with the reacting column, the cavity of the reacting section is separated to an inner reacting chamber and an outer reacting chamber by the second separating plate, and the first separating plate is installed in the outer reacting chamber so that the outer reacting chamber is separated to the multiple first reacting chambers.

Further, in the structural formula, R<NUM> represents the alkyl of C1-C10, preferably a methyl, an ethyl, a tertiary butyl, an n-hexyl or an n-heptyl.

Further, the step S1 comprises: enabling the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate to be dissolved in a first organic solvent so as to form first raw material solution, wherein the first organic solvent is selected from arbitrary one or more from a group of ethyl acetate, methyl acetate, tetrahydrofuran, dichloromethane, trichloromethane and methyl isobutyl ketone; and feeding the first raw material solution into the column-type continuous reactor, using the rhodium-loaded catalyst to catalyze the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate to generate the cyclization reaction in <NUM>-<NUM> so as to form a first intermediate system containing the first intermediate, wherein preferably retention time of the first raw material solution in the column-type continuous reactor is <NUM>-<NUM> mins, preferably <NUM>-<NUM> mins.

Further, the step S2 comprises: pre-cooling the second continuous reactor to -<NUM>-<NUM>; and respectively feeding the first intermediate system, solution of the diphenyl chlorophosphate and solution of the diisopropylethylamine into the pre-cooled second continuous reactor to perform the esterification reaction so as to obtain the product system containing the penem intermediate MAP, wherein a solvent in the solution of the diphenyl chlorophosphate and a solvent in the solution of the diisopropylethylamine are respectively and independently selected arbitrary one or more from a group consist of the ethyl acetate, methyl acetate, tetrahydrofuran, dichloromethane, trichloromethane and methyl isobutyl ketone, before performing the step S2, preferably enabling the first intermediate system obtained in the step S1 to be collected to a receiving device and pre-cooling to -<NUM>-<NUM>, wherein the receiving device is connected with the column-type continuous reactor and the second continuous reactor.

Further, the second continuous reactor is a one-level coiler continuous reactor or a multi-level coiler serially-connected continuous reactor, and the retention time of a reactant in the second continuous reactor is <NUM>-<NUM> mins, preferably <NUM>-<NUM> mins.

Further, the step S3 comprises: after feeding the product system into a quenching agent for quenching, feeding a crystallization liquid into the product system to perform the crystallization, to obtain a crystallization system, wherein the quenching agent is selected arbitrary one or more from a group of pure water, potassium dihydrogen phosphate buffer solution, potassium hydrogen phosphate buffer solution, sodium dihydrogen phosphate buffer solution, and sodium hydrogen phosphate buffer solution, and the crystallization liquid is selected arbitrary one or more from a group of hexane, heptane, octane, methyl cyclopentane and petroleum ether; and performing solid-liquid separation on the crystallization system, to obtain the penem intermediate MAP.

A technical scheme of the present invention is applied, and the present application uses the column-type continuous reactor as a place in which the cyclization reaction occurs. Since the cyclization reaction forms the first intermediate while forming a gas-state product, the gas-state product has a disturbing effect on the rhodium-loaded catalyst in a rising process thereof in the column-type continuous reactor, thereby it is beneficial to the efficient contact of <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate and the catalyst so as to improve the catalytic effect, and the rhodium-loaded catalyst of the present application uses the polymer as a carrier, so it has higher mechanical properties and catalytic activity, and is easy to recycle. Under the synergistic effect of the column-type continuous reactor and the rhodium-loaded catalyst, the cyclization reaction of the present application may be performed efficiently at a lower temperature, and the temperature difference between the cyclization reaction and the esterification reaction is reduced, thereby a cooling source required for the cooling of the first intermediate is reduced, and the energy consumption is reduced, so it is especially suitable for the industrial application.

Drawings of the description for constituting a part of the present application are used to provide further understanding of the present invention. Exemplary embodiments of the present invention and descriptions thereof are used to explain the present invention, and do not constitute improper limitation to the present invention. In the drawings: cyclization reaction so as to form a first intermediate, wherein the rhodium-loaded catalyst is loaded in the column-type continuous reactor, and the rhodium-loaded catalyst has the following structural formula: (P-COO)x-Rh<NUM>(OOCR<NUM>)<NUM>-x wherein R<NUM> represents any one alkyl of C1-C10; P-COO-represents a residue of a polymer after dehydrogenation, and x represents an arbitrary number of <NUM>-<NUM>; step S2, performing an esterification reaction on the first intermediate, a diphenyl chlorophosphate and a diisopropylethylamine in a second continuous reactor, to obtain a product system containing the penem intermediate MAP; and step S3, performing crystallization treatment on the product system, to obtain the penem intermediate MAP.

Main reaction formulas of the cyclization reaction and the esterification reaction of the preparation method are as follows:
<CHM>.

The present application uses the column-type continuous reactor as a place in which the cyclization reaction occurs. Since the cyclization reaction forms the first intermediate while forming a gas-state product, the gas-state product has a disturbing effect on the rhodium-loaded catalyst in a rising process thereof in the column-type continuous reactor, thereby it is beneficial to the efficient contact of <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate and the catalyst so as to improve the catalytic effect, and the rhodium-loaded catalyst of the present application uses the polymer as a carrier, so it has higher mechanical properties and catalytic activity, and is easy to recycle. Under the synergistic effect of the column-type continuous reactor and the rhodium-loaded catalyst, the cyclization reaction of the present application may be performed efficiently at a lower temperature, and the temperature difference between the cyclization reaction and the esterification reaction is reduced, thereby a cooling source required for the cooling of the first intermediate is reduced, and the energy consumption is reduced, so it is especially suitable for the industrial application.

In some embodiments of the present application, as shown in <FIG> and <FIG>, the column-type continuous reactor comprises a reacting column, and installed from bottom to top, the reacting column comprises a feeding section <NUM>, a reacting section <NUM> and a discharging section <NUM>, the feeding section <NUM> is provided with a liquid inlet <NUM>, and a liquid distributing device is installed above the liquid inlet <NUM>; the reacting section <NUM> is isolated from the feeding section <NUM> through a porous bottom plate <NUM>, the reacting section <NUM> is internally filled with an inert filler <NUM> and the rhodium-loaded catalyst and provided with multiple circumferentially arranged first separating plates <NUM>, and each of the first separating plate <NUM> is extended along a vertical direction so that a cavity of the reacting section <NUM> is separated to multiple first reacting chambers; and the discharging section <NUM> is isolated from the reacting section <NUM> through a porous top plate <NUM>, and the discharging section <NUM> is provided with a liquid-state product outlet <NUM> and an exhaust port <NUM>.

The reacting column of the column-type continuous reactor may achieve continuous feeding and discharging, thereby the continuous reaction is achieved; the liquid distributing device is arranged above the liquid inlet <NUM>, so that a reaction material is fed in a uniform manner; the first separating plate <NUM> arranged in the reacting section <NUM> divides the reacting cavity into reacting chambers with a small volume, the filler arranged in the reacting chamber disperses the rhodium-loaded catalyst placed in the reacting chamber during the reaction, and a gas by-product is avoided from being upwards flowed to drive the rhodium-loaded catalyst to accumulate upwards so as to cause a problem that a pressure drop in the reacting column is excessive; and while a liquid reaction material enters each reacting chamber, because the volume of the reacting chamber is small, the gas-state by-product produced by the reaction may not be excessively concentrated, as to cause a transitional impact on the filler and the rhodium-loaded catalyst to form a large area of cavities, and the presence of the filler may further prevent the rhodium-loaded catalyst from forming channeling and bypass due to the impact effect, thereby the mass transfer between a liquid phase and a solid phase is uniform during the reaction, the flowing of a gas phase in the liquid phase and the solid phase is also uniform, and the catalytic efficiency of the rhodium-loaded catalyst is improved, so that <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate may efficiently perform the cyclization reactions at a lower temperature.

The feeding section <NUM>, the reacting section <NUM> and the discharging section <NUM> of the reacting column may be integrally arranged in the reacting column, or the sections may be connected by connecting pieces. In addition, in order to increase the productivity, the column-type continuous reactor may be used in multi-level serially.

Further, preferably as shown in <FIG>, a second separating plate <NUM> is further installed in the cavity of the reacting section <NUM>, the second separating plate <NUM> is a cylinder-like separating plate coaxially installed with the reacting column, the cavity of the reacting section <NUM> is separated to an inner reacting chamber and an outer reacting chamber by the second separating plate <NUM>, and the first separating plate <NUM> is installed in the outer reacting chamber so that the outer reacting chamber is separated to multiple the first reacting chambers. Through a combination of the second separating plate <NUM> and first separating plate <NUM>, the cavity of the reacting section <NUM> is further separated, so that the mass transfer between the liquid phase and the solid phase is more uniform. Preferably, the second separating plate <NUM> is the cylinder-like separating plate parallel to a side wall of the reacting section <NUM>. For example, as shown in <FIG>, the cylinder-like second separating plate <NUM> is used to combine with the first separating plate <NUM>, so that the formed first reacting chamber does not have a dead corner, the material in each reacting chamber flows more smoothly, and the phase contact is more uniform.

In addition, preferably an inner diameter of the inner reacting chamber is <NUM>/<NUM>-<NUM>/<NUM> of an inner diameter of the reacting section <NUM>. In order to make the volumes of the inner reacting chamber and each first reacting chamber relatively uniform, the reactions in each reacting chamber are relatively synchronized.

In order to maintain a stable pressure drop in each reacting chamber of the reacting column <NUM>, preferably the reacting section <NUM> adopts a pipeline of DN10-DN800, and a length-to-diameter ratio of the reacting section <NUM> is <NUM>:<NUM>-<NUM>:<NUM>; preferably <NUM>:<NUM>-<NUM>: <NUM>.

Preferably, in the tructural formula, R<NUM> represents the alkyl of C1-C10, preferably a methyl, an ethyl, a tertiary butyl, an n-hexyl or an n-heptyl, as to reduce the difficulty of the synthesis of a catalyst carrier.

The rhodium-loaded catalyst of the present application may adopt a rhodium-loaded catalyst in an existing technology or adopt a preparation method of the existing technology to prepare the rhodium-loaded catalyst, for example, a rhodium-loaded catalyst disclosed in a patent with a patent number ZL201410459708. <NUM> is adopted or a method thereof is adopted to prepare the rhodium-loaded catalyst.

There are many ways to achieve the cyclization reaction by using the above column-type continuous reactor. Preferably, the step S1 comprises: the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate is dissolved in a first organic solvent so as to form first raw material solution, wherein the first organic solvent is selected from arbitrary one or more from a group of ethyl acetate, methyl acetate, tetrahydrofuran, dichloromethane, trichloromethane and methyl isobutyl ketone. The first raw material solution is formed by using a mode of stirring at <NUM> to <NUM>. The first raw material solution is fed into the column-type continuous reactor, the rhodium-loaded catalyst is used to catalyze the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate to generate the cyclization reaction in <NUM> to <NUM> so as to form a first intermediate system containing the first intermediate, wherein preferably retention time of the first raw material solution in the column-type continuous reactor is <NUM> to <NUM> mins, preferably <NUM> to <NUM> mins. The <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate is prepared into solution in advance, and sent into the column-type continuous reactor, it is convenient for the control of a cyclization reaction process. The cyclization reaction may occur at <NUM> to <NUM>, it is greatly reduced compared to <NUM> to <NUM> of the existing technology; and in addition, due to the improvement of the catalytic efficiency, the retention time of the first raw material solution in the column-type continuous reactor may also be relatively shortened, such as in the range of <NUM> mins, or even it is shortened to the range of <NUM>-<NUM> mins, a higher yield of the first intermediate may be obtained.

Preferably, the content of the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate in the first raw material solution is <NUM> to <NUM> mmol/mL.

In another embodiment of the present application, since the temperature of the esterification reaction is lower, in order to improve the preparation efficiency, preferably the step S2 comprises: pre-cooling the second continuous reactor to -<NUM>-<NUM> ; and respectively feeding the first intermediate system, solution of the diphenyl chlorophosphate and solution of the diisopropylethylamine a into the pre-cooled second continuous reactor to perform the esterification reaction so as to obtain the product system containing the penem intermediate MAP, wherein, the retention time of a reactant in the second continuous reactor is <NUM>-<NUM> mins, preferably <NUM>-<NUM> mins, and preferably a solvent in the solution of the diphenyl chlorophosphate and a solvent in the solution of the diisopropylethylamine are respectively and independently selected from arbitrary one or more from a group consist of the ethyl acetate, methyl acetate, tetrahydrofuran, dichloromethane, trichloromethane and methyl isobutyl ketone. The second continuous reactor is pre-cooled to -<NUM>-<NUM> n advance, so that the material may enter the second continuous reactor (PFR) to quickly enter a reaction state, thereby the preparation efficiency is improved.

In order to simplify an operation, preferably the solvent in the solution of the diphenyl chlorophosphate is the same as the first organic solvent for dissolving the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate. Preferably, the content of diphenyl chlorophosphate in the solution of the diphenyl chlorophosphate is <NUM> to <NUM> mmol/mL; the content of diisopropylethylamine in the solution of diisopropylethylamine is <NUM> to <NUM> mmol/mL. In order to improve a utilization rate of each substance, preferably a flow ratio of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate and the solution of diisopropylethylamine is <NUM>:<NUM>~<NUM>:<NUM>~<NUM>:<NUM>~<NUM>.

The second continuous reactor is a one-level coiler continuous reactor or a multi-level coiler serially-connected continuous reactor. Herein, the multi-level coiler serially-connected continuous reactor may improve the production efficiency. The esterification reaction in the use of the coiler continuous reactor may be applied to a wider temperature range and easier to control, and the retention time may also be relatively shortened to <NUM>-<NUM> mins, or even <NUM>-<NUM> mins.

Before the step S2 is performed, the first intermediate system obtained in step S1 may be collected to a receiving device such as a storage tank or an enamel kettle and pre-cooled to -<NUM> ~ <NUM> (preferably -<NUM> to <NUM>), and the receiving device is connected to the column-type continuous reactor and the second continuous reactor, after a certain amount is collected, the reaction in the step S2 is performed to further guarantee the continuity and stability of the process.

The step S3 of the present application is to separate the product MAP by crystallization. A crystallization mode that may be used in the present application may be continuous crystallization or batch crystallization. In one embodiment, the step S3 comprises: feeding the product system, a quenching agent and crystallization liquid into a third continuous reactor for continuous crystallization, to obtain a crystallization system, wherein the quenching agent is selected arbitrary one or more from a group of pure water, potassium dihydrogen phosphate buffer solution, potassium hydrogen phosphate buffer solution, sodium dihydrogen phosphate buffer solution, and sodium hydrogen phosphate buffer solution, and the crystallization liquid is selected arbitrary one or more from a group of hexane, heptane, octane, methyl cyclopentane and petroleum ether; and the crystallization system is subjected to solid-liquid separation, to obtain the penem intermediate MAP. The buffer solution, such as potassium dihydrogen phosphate buffer solution, adopts a conventional mass concentration such as <NUM>-<NUM>%.

A continuous crystallization mode may be used to improve the production efficiency. At the beginning of the step S3, the product system and the quenching agent may be sent to the third continuous reactor for quenching, and then the crystallization solution is sent in. During a normal operation, the three are sent at the same time, the feeding speeds of the three may be controlled to control the effect and rate of quenching and crystallization. For example, a flow ratio of the first raw material solution, the control product system, the quenching agent and the crystallization liquid is <NUM>:<NUM>~<NUM>:<NUM>~<NUM>:<NUM>~<NUM>. The third continuous reactor is the one-level coiler continuous reactor or the multi-level coiler serially-connected continuous reactor.

In another embodiment, the step S3 comprises: the product system is sent into the quenching agent for quenching, and then the crystallization liquid is sent into the product system for crystallization, to obtain the crystallization system, herein the quenching agent is selected arbitrary one or more from a group of pure water, potassium dihydrogen phosphate buffer solution, potassium hydrogen phosphate buffer solution, sodium dihydrogen phosphate buffer solution, and sodium hydrogen phosphate buffer solution, and the crystallization liquid is selected arbitrary one or more from a group consist of hexane, heptane, octane, methyl cyclopentane and petroleum ether; and the crystallization system is subjected to the solid-liquid separation, to obtain the penem intermediate MAP. The batch crystallization mode is adopted, and the mode of first quenching and then crystallization is beneficial to improve the efficiency of crystallization and the purity of the product.

The solid-liquid separation modes in the above two embodiments may be filtration, suction filtration or centrifugation, and the specific operating conditions may refer to the existing technology and not be repeatedly described here.

The beneficial effects of the present application are further described below with reference to embodiments and contrast examples.

Or (<NUM>) Batch crystallization: the product system flowing out of the multi-level coiler-type continuous reactor is quenched in <NUM>-<NUM>% of the potassium dihydrogen phosphate buffer solution prepared in advance, and then the heptane is added to it for crystallization. The crystallization system is obtained, and the crystallization system undergoes the centrifugal separation to finally obtain the product penem intermediate MAP((4R,5R,<NUM>)-<NUM>-[(diphenoxyphosphinyl)oxy]-<NUM> -[(1R)-<NUM>-hydroxyethyl]-<NUM>-methyl-<NUM>-oxo-<NUM>-azabicyclo[<NUM>. <NUM>]hept-<NUM>-ene-<NUM>-carboxylic acid (<NUM>-nitrophenyl)methyl ester).

The flow ratio per unit time of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate, the solution of diisopropylethylamine, the product system, the potassium dihydrogen phosphate buffer solution, and the heptane is <NUM>:<NUM>-<NUM>: <NUM>~<NUM>:<NUM>~<NUM>: <NUM>~<NUM>:<NUM>~<NUM>:<NUM>~<NUM>.

The penem intermediate MAP is prepared by the above process, herein, in the step (<NUM>), the content of the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate solution was <NUM> mmol/mL; the concentration of diphenyl chlorophosphate was <NUM> mmol/mL; the solution concentration of diisopropylethylamine was <NUM> mmol/mL. The rhodium-load catalyst was
<CHM>
namely a compound <NUM> in a patent with a patent number <CIT>. The retention time of the step (<NUM>) was <NUM>, the reaction temperature was <NUM>, the inner diameter of the inner reacting chamber of the column-type continuous reactor is <NUM>/<NUM> of the inner diameter of the reacting section, and the length-to-diameter ratio of the reacting section is <NUM>:<NUM>. In the step (<NUM>), the coiler continuous reactor was used, the retention time was controlled to be <NUM>, and the reaction temperature was -<NUM>. The concentration of the potassium dihydrogen phosphate buffer solution in the step (<NUM>) was <NUM>%. The flow ratio per unit time of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate, the solution of diisopropylethylamine, the product system, the potassium dihydrogen phosphate buffer solution, and the heptanes was <NUM>:<NUM>: <NUM>: <NUM>: <NUM>: <NUM>: <NUM>.

The penem intermediate MAP is prepared by the above process, herein, in the step (<NUM>), the content of the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate solution was <NUM> mmol/mL; the concentration of diphenyl chlorophosphate was <NUM> mmol/mL; the solution concentration of diisopropylethylamine was <NUM> mmol/mL. The rhodium-load catalyst was
<CHM>
namely a compound <NUM> in a patent with a patent number <CIT>. The retention time of the step (<NUM>) was <NUM>, the reaction temperature was <NUM>, the inner diameter of the inner reacting chamber of the column-type continuous reactor was <NUM>/<NUM> of the inner diameter of the reacting section, and the length-to-diameter ratio of the reacting section was <NUM>:<NUM>. In the step (<NUM>), the coiler continuous reactor was used, the retention time was controlled to be <NUM>, and the reaction temperature was -<NUM>. The concentration of the potassium dihydrogen phosphate buffer solution in the step (<NUM>) was <NUM>%. The flow ratio per unit time of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate, the solution of diisopropylethylamine, the product system, the potassium dihydrogen phosphate buffer solution, and the heptanes is <NUM>:<NUM>: <NUM>: <NUM>: <NUM>: <NUM>: <NUM>.

The penem intermediate MAP is prepared by the above process, herein, in the step (<NUM>), the content of the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate solution was <NUM> mmol/mL; the concentration of diphenyl chlorophosphate was <NUM> mmol/mL; the solution concentration of diisopropylethylamine is <NUM> mmol/mL. The rhodium-load catalyst was
<CHM>
namely a compound <NUM> in a patent with a patent number <CIT>. The retention time of the step (<NUM>) was <NUM>, the reaction temperature was <NUM>, the inner diameter of the inner reacting chamber of the column-type continuous reactor was <NUM>/<NUM> of the inner diameter of the reacting section, and the length-to-diameter ratio of the reacting section was <NUM>:<NUM>. In the step (<NUM>), the coiler continuous reactor was used, the retention time was controlled to be <NUM>, and the reaction temperature was -<NUM>. The concentration of the potassium dihydrogen phosphate buffer solution in the step (<NUM>) was <NUM>%. The flow ratio per unit time of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate, the solution of diisopropylethylamine, the product system, the potassium dihydrogen phosphate buffer solution, and the heptanes was <NUM>:<NUM>: <NUM>: <NUM>: <NUM>: <NUM>: <NUM>.

The penem intermediate MAP was prepared by the above process, herein, in the step (<NUM>), the content of the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate solution was <NUM> mmol/mL; the concentration of diphenyl chlorophosphate was <NUM> mmol/mL; the solution concentration of diisopropylethylamine was <NUM> mmol/mL. The rhodium-load catalyst was
<CHM>
namely a compound <NUM> in a patent with a patent number <CIT>. The retention time of the step (<NUM>) was <NUM>, the reaction temperature was <NUM>, the inner diameter of the inner reacting chamber of the column-type continuous reactor was <NUM>/<NUM> of the inner diameter of the reacting section, and the length-to-diameter ratio of the reacting section was <NUM>:<NUM>. In the step (<NUM>), the coiler continuous reactor was used, the retention time was controlled to be <NUM>, and the reaction temperature was -<NUM>. The concentration of the potassium dihydrogen phosphate buffer solution in the step (<NUM>) was <NUM>%. The flow ratio per unit time of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate, the solution of diisopropylethylamine, the product system, the potassium dihydrogen phosphate buffer solution, and the heptanes was <NUM>:<NUM>: <NUM>: <NUM>: <NUM>: <NUM>: <NUM>.

The penem intermediate MAP was prepared by the above process, herein, in the step (<NUM>), the content of the <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate solution was <NUM> mmol/mL; the concentration of diphenyl chlorophosphate was <NUM> mmol/mL; the solution concentration of diisopropylethylamine was <NUM> mmol/mL. The rhodium-load catalyst was
<CHM>
namely a compound <NUM> in a patent with a patent number <CIT>. The retention time of the step (<NUM>) was <NUM>, the reaction temperature was <NUM>, the inner diameter of the inner reacting chamber of the column-type continuous reactor was <NUM>/<NUM> of the inner diameter of the reacting section, and the length-to-diameter ratio of the reacting section was <NUM>:<NUM>. In the step (<NUM>), the coiler continuous reactor was used, the retention time was controlled to be <NUM>, and the reaction temperature was <NUM>. The concentration of the potassium dihydrogen phosphate buffer solution in the step (<NUM>) was <NUM>%. The flow ratio per unit time of the first raw material solution, the first intermediate system, the solution of diphenyl chlorophosphate, the solution of diisopropylethylamine, the product system, the potassium dihydrogen phosphate buffer solution, and the heptanes was <NUM>:<NUM>: <NUM>: <NUM>: <NUM>: <NUM>: <NUM>.

The products of the above embodiments are identified, and it is determined that the target product MAP is obtained, and the yield thereof is recorded in Table <NUM>. The product obtained in each embodiment is subjected to HPLC detection to determine purity and isomers, an infrared test is performed on the product to identify the structure thereof, thermogravimetric analysis is performed to further analyze the purity of the product, and X-ray diffraction analysis is performed to determine the crystal structure thereof. A GC test is performed to analyze the residual solvent in the product. Herein, the purity and isomer HPLC test results of Embodiment <NUM> are shown in <FIG> and <FIG>, the infrared test results are shown in <FIG>, the thermogravimetric analysis result TG and DTG curves are shown in <FIG>, the XRD spectrum is shown in <FIG>, and the GC spectrum is shown in <FIG>, herein data descriptions corresponding to <FIG> is shown in Table <NUM>.

Data descriptions corresponding to <FIG> are shown in Table <NUM>.

According to the test results in <FIG>, it may be seen that while heated to <NUM>, the weight loss is <NUM>, and a weight loss rate is <NUM>%.

According to the results of the above embodiments, it may be seen that due to the column-type reactor of the present application and the rhodium-load catalyst used, the cyclization reaction in the first step may be performed at the lower temperature (<NUM>-<NUM>) and the high yield of the final product MAP may also be guaranteed.

It may be seen from the above descriptions that the above embodiments of the present invention achieve the following technical effects.

Claim 1:
A continuous preparation method for a penem intermediate MAP, comprising:
step S1, in a column-type continuous reactor, using a rhodium-loaded catalyst to catalyze <NUM>-nitrobenzyl(R) -<NUM>-diazo-<NUM>-((2R,<NUM>)-<NUM>-((R)-<NUM>-hydroxyethyl)-<NUM>-oxoazetidin-<NUM>-yl)-<NUM>-oxopentanoate to generate a cyclization reaction so as to form a first intermediate, wherein the rhodium-loaded catalyst is loaded in the column-type continuous reactor, and the rhodium-loaded catalyst has the following structural formula:
<CHM>
wherein R<NUM> represents any one alkyl of C1-C10; P-COO-represents a residue of a polymer after dehydrogenation, and x represents an arbitrary number of <NUM>-<NUM>;
step S2, performing an esterification reaction on the first intermediate, a diphenyl chlorophosphate and a diisopropylethylamine in a second continuous reactor, to obtain a product system containing the penem intermediate MAP; and
step S3, performing crystallization treatment on the product system, to obtain the penem intermediate MAP;
the structure formula of the penem intermediate MAP being as follows:
<CHM>
the step S3 comprising:
feeding the product system, a quenching agent and crystallization liquid into a third continuous reactor to perform continuous crystallization, to obtain a crystallization system, wherein the quenching agent is selected arbitrary one or more from a group of pure water, potassium dihydrogen phosphate buffer solution, potassium hydrogen phosphate buffer solution, sodium dihydrogen phosphate buffer solution, and sodium hydrogen phosphate buffer solution, and the crystallization liquid is selected arbitrary one or more from a group consist of hexane, heptane, octane, methyl cyclopentane and petroleum ether; and
performing solid-liquid separation on the crystallization system, to obtain the penem intermediate MAP;
the third continuous reactor being a one-level coiler continuous reactor or a multi-level coiler serially-connected continuous reactor.