Continuous flow carboxylation reaction

Abstract

The present invention is related to a two-step carboxylation reaction of an aryl group using continuous flow reaction conditions. This process permits large scale synthesis of useful reaction products in high yield.

Claims

1. A process of preparing a compound of Formula I: ##STR00006## comprising: reacting a compound of Formula II: ##STR00007## with n-BuLi and TMEDA at −78° C. to afford a compound of Formula III: ##STR00008## quenching said compound of Formula III with gaseous carbon dioxide to afford a compound of Formula IV: ##STR00009##  and treating said compound of Formula IV with HCl to afford the compound of Formula I, wherein said method is performed using continuous flow reaction conditions, wherein said process is capable of obtaining at least 3.5 kg of Formula I at yield of greater than about 80%.

2. The process of claim 1, wherein said reacting a compound of Formula II with nBuLi and TMEDA at −78° C. is performed in a polar aprotic solvent.

3. The process of claim 2, wherein said polar aprotic solvent is THF.

4. The process of claim 1, wherein a reaction temperature is maintained at less than −65° C. during said quenching with gaseous carbon dioxide.

5. The process of claim 1, wherein said reacting a compound of Formula IV with HCl is performed in a polar solvent.

6. The process of claim 5, wherein said polar solvent is 1,4-dioxane.

7. The process of claim 1, wherein said HCl is 4N HCl.

8. The process of claim 1, wherein the compound of Formula I is an intermediate used in the synthesis of lifitegrast.

9. The process of claim 1, wherein said process is carried out in a continuous flow batch reactor.

10. The process of claim 9, wherein said continuous flow batch reactor comprises stainless steel reactor tubes.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a reactor of the invention.

(2) FIG. 2(A) shows a mixing unit for use in a reactor of the invention. FIG. 2(B) shows an expanded view of the mixing unit.

(3) FIG. 3(A) shows stainless steel tubes for use in a reactor of the invention. FIG. 3(B) shows a cooling compartments for the steel tubles.

DETAILED DESCRIPTION

(4) The present invention provides an improved process for preparing the compound of Formula I using continuous flow chemistry. Applicants have surprisingly discovered that the inventive process facilitates: a) ease of performing low temperature reactions b) high mixing of the gas-liquid phase and c) excellent heat transfer capacity under flow conditions and d) consistent yield irrespective of the scale.

(5) Batch Reaction

(6) In one embodiment, the batch procedure for the carboxylation reaction involves the addition of BuLi (2.5 M solution) to a THF solution of 2 in the presence of TMEDA at −78° C. The lithium anion 3 is then quenched with gaseous carbon dioxide to afford the product. The addition of CO.sub.2 to the reaction mixture is an exothermic reaction and controlled addition to maintain the batch temperature to <−65° C. can be used to minimize decomposition of the lithiated species and improve selectivity. In order to avoid temperature spikes with subsurface additions, a blanket of CO.sub.2 is maintained. Since an in-process analysis of the anion is not practical, conversion can be monitored after quench with CO.sub.2 Kinetic studies prior to translating to conditions can be done using an In-Situ ReactIR probe to ensure that both the anion formation and CO.sub.2 quench are instantaneous.

(7) Initial Reactor Design

(8) In one embodiment, a reactor for use in the inventive process is shown in FIG. 1. As shown in FIG. 1, the reactor can contain three loops (A, B and C) where loop A is used to cool a mixture of 2 and TMEDA in THF to −78° C. Just after loop A, the base can be added and loop B can provide the necessary residence time for the anion formation after which carbon dioxide can be added as a gas which is passed through loop C to give the product. The entire reactor can be submerged into a dry ice acetone bath. In one embodiment, the loops are made of 1/16.sup.th inch high density polyethylene (HDPE) tubing with two HPLC pumps for the reagents.

(9) In some embodiments, as shown in FIG. 2, the mixing units can consist of ¼″ ID diameter tubing with two small stir bars trapped within. The stir bars can be agitated using a magnetic stir plate, providing turbulence sufficient for mixing of the reagents. In some embodiments, the back pressure unit at the end of the product stream can be set to 10 psi.

(10) In some embodiments, the residence times for the trial runs are based on reaction monitoring in a batch mode (determined by HPLC analysis). Interestingly, addition of the base to 2 in THF is marked with a color change from pale orange to dark red, which decolorizes upon quench with carbon dioxide. The flow rates can be adjusted to achieve a base stoichiometry twice as the starting material. For the first few experiments, a small CO.sub.2 cylinder can be directly connected to the flow reactor. The product stream can be collected after steady stage is achieved (the first one or two fractions can be discarded due to poor conversion) and worked up in a batch mode by quenching with 2N HCl, extraction with ethyl acetate and telescoping it to the next step to isolate 1.

EXAMPLE 1

Optimizing Reaction Conditions of Carboxylation Reaction

(11) This example was performed using the reactor and mixer units shown in FIGS. 1 and 2. As shown in Table 1, an experiment was carried out to optimize the flow rates and residence times during the carboxylation reaction. Increasing the residence time for the carbon dioxide quench from 1 minute to 5 minutes was found to provide a dramatic increase in the conversion. Commercially available 1.5 MBuLi varied significantly in quality from lot to lot and flow rate had to be adjusted accounting for the lower potency of the reagent. This issue was overcome using a 2.5 M solution which was much more consistent in quality. Conditions were further optimized by increasing the concentration of 2 in THF to 10% and lowering the residence time for the anion formation to 10 minutes which showed >90% conversion. In attempts to further improve the throughput to process larger quantities of material, the same set up was designed using ¼ inch ID HDPE tubing. The conditions optimized for the 1/16.sup.th inch tubing were repeated and identical results were obtained.

(12) TABLE-US-00001 TABLE 1 Optimization of the Carboxylation Reaction Concen- Residence tration time (min) Scale of 2 in BuLi ID Anion CO.sub.2 HPLC (g) THF (%) (M) (inches) formation quench Conversion 5 6.7 1.5 1/16 17 1 55 5 6.7 1.5 1/16 17 5 90 30 10 2.5 1/16 10 5 93 100 10 2.5 ¼ 10 5 96

(13) However, it was noted that a HDPE tubing dipped in dry ice was not ideal for longer processing times as material leached out of the tubes to the coolant bath within a few hours of processing. Additionally, the lower temperatures made the tubing brittle and significant leaks were observed in the joints. Often butyl lithium froze in the addition port and caused significant back pressure. These issues along with the urgent need to process several kilogram quantities of material led us to redesign a more robust reactor that addressed these issues with a higher throughput capable of processing several kilogram quantities of material.

EXAMPLE 2

Optimization of Reactor Design

(14) In this Example, the reactor described in Example 1 was optimized. An identical unit as in Example 1 was prepared with the exception that stainless steel tubes were used instead of HDPE tubes. Since the heat exchange in the case of stainless steel is higher than HDPE tubes it was envisioned that a much lower residence time (t.sub.1) would be required. The minimum tube length at maximum operatable flow rate required for complete heat dissipation was determined If l.sub.1 is the length needed to achieve the desired residence time and l.sub.2 is the length needed for complete heat dissipation, then the tube length is considered as the higher of the two. The length l.sub.1 is calculated based on the flow rate and the tube diameter. The length needed for complete heat dissipation (l.sub.2) for a known flow rate can be calculated from the following equation:
Q=UA ΔT.sub.lm Q—Heat Rate, BTU/hr; Q can be calculated according to the thermal properties of the process fluid (for process that has no reaction going on in the loop) or the enthalpy of the reaction occurred within the loop. U—Heat Transfer Coefficient, BTU/(h-ft^2-F); U can be obtained according to literature data for known material construction of the tubing and the nature of the heat transfer media and the process fluid in the tubing. A—Surface area, (ft^2); A can be expressed using the tubing length and the tubing internal diameter. ΔT.sub.lm—logarithmic temperature difference between process fluid (t.sub.in and t.sub.out) and the coolant (T.sub.in and T.sub.out), ° F.

(15) $\Delta T_{lm}=\frac{\left(t_{in}-T_{\mathrm{out}}\right)-\left(t_{\mathrm{out}}-T_{in}\right)}{\ln \left(\frac{t_{in}-T_{\mathrm{out}}}{t_{\mathrm{out}}-T_{in}}\right)}$

(16) Loop A is only a cooling loop and no heat is released from this operation. The length required to cool from ambient temperature to −78° C. was calculated. However, for the anion formation, heat of the reaction needs to be dissipated before the carbon dioxide quench. In the absence of this length, the carbon dioxide quench may be done at a higher temperature, out of the stability window for the anion. The heat of reaction was calculated by running an RC1 experiment. Based on the heat that needs to be removed for loop A and B, the minimum length at the maximum flow rate to completely dissipate the heat was found to be 14 feet and 22 feet. The quench with CO.sub.2 was the length needed for the reaction.

(17) TABLE-US-00002 TABLE 2 Tube Length Calculations. Flow Rate U Q A Length Loop (ml/min) (btu/h-ft{circumflex over ( )}2-F) (BTU/hr) (Ft.sup.2) (Ft) A (Cooling) 102 10 766 1.14 14 B (Anion 120 10 282.7 1.8 22 Formation) C (CO.sub.2 >120 — — — — Quench)

(18) Three tubes 5/16″ diameter made of stainless steel were built (FIG. 3A), coiled and immersed into a carboy filled with dry ice acetone (FIG. 3B. Six static mixers were inserted into the tubes after both the anion formation and carbon dioxide quench to provide the required mixing.

EXAMPLE 3

Scale Up Reaction Using Optimized Reactor. Generation Reactor Set-Up

(19) In this Example, large-scale reactions were performed using the reactor prepared in Example 2. Since the mixing using static mixer was more efficient, Applicants were able to further reduce the residence time by increasing the flow rates. Table 3 summarizes the details of the scale up runs.

(20) TABLE-US-00003 TABLE 3 Results of Scale-Up Runs. Residence Time (min) Yield Over Scale Anion CO.sub.2 Purity Two Steps Entry (kg) Formation Quench (% AUC) (%) 1 5.4 2.0 0.9 91.6 81 2 3.5 2.0 0.9 94.4 3 5 3.6 1.6 97.2 88 4 4 3.6 1.6 98.2 91 5 4 3.6 1.6 97.8

(21) As shown in Table 3, the residence time for the anion formation was reduced 3.6 minutes and carbon dioxide quench to 1.6 minutes which gave the highest purity of 1.

(22) Only two minor issues with the synthesis were observed. For example, (1) during the synthesis, valeric acid (a byproduct of the reaction of BuLi with carbon dioxide whose freezing point is −20° C.) froze in the lines and stopped the flow. However, this occurred only when there was variation in the pumping rate of the reactants. This depended on the capacity of the pump on prolonged pumping. As long a study state was maintained, this issue was not observed; (2) commercially available BuLi contained significant amounts of residue and in the lack of a filter, the reagent ceased the pumps.

(23) In conclusion, a two-step continuous flow carboxylation was developed and twenty two kilograms of material was successfully produced.