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Last Updated: March 27, 2026

Claims for Patent: 12,370,142

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Summary for Patent: 12,370,142

Title:	Manufacturing of bupivacaine multivesicular liposomes
Abstract:	Embodiments of the present disclosure relates to a new and improved large scale commercial manufacturing process of making bupivacaine multivesicular liposomes (MVLs). Batches of bupivacaine MVLs prepared by the new process have high yields, improved stabilities, and desired particle size distributions.
Inventor(s):	Eran Levy, Jeffrey S. Hall, John J. Grigsby, Jr.
Assignee:	Pacira Pharmaceuticals Inc
Application Number:	US19/077,685
Patent Litigation and PTAB cases:	See patent lawsuits and PTAB cases for patent 12,370,142
Patent Claims:	1. A batch comprising a composition of bupivacaine encapsulated multivesicular liposomes (MVLs), prepared by a process comprising: (a) mixing a first aqueous solution comprising phosphoric acid with a volatile water-immiscible solvent solution to form a water-in-oil first emulsion, wherein the volatile water-immiscible solvent solution comprises 1,2-dipalmitoyl-sn-glycero-3-phospho-rac-(1-glycerol) (DPPG) or a salt thereof, 1,2-dierucoylphosphatidylcholine (DEPC), tricaprylin and cholesterol, and wherein either the first aqueous solution or the volatile water-immiscible solvent solution comprises bupivacaine; (b) mixing the water-in-oil first emulsion with a second aqueous solution to form a water-in-oil-in-water second emulsion, wherein the second aqueous solution comprises lysine and at least one osmotic agent; (c) substantially removing the volatile water-immiscible solvent from the water-in-oil-in-water second emulsion by sparging the water-in-oil-in-water second emulsion to form a first aqueous suspension of bupivacaine encapsulated MVLs having a first volume; (d) reducing the first volume of the first aqueous suspension of bupivacaine encapsulated multivesicular liposomes by a first microfiltration to provide a second aqueous suspension of bupivacaine encapsulated MVLs having a second volume, wherein the first microfiltration feed flow rate is about 200 L/min to about 400 L/min; (e) exchanging the second aqueous suspension medium with a saline solution by diafiltration to provide a third aqueous suspension of bupivacaine encapsulated MVLs having a third volume, wherein the diafiltration feed flow rate is about 200 L/min to about 350 L/min; and (f) reducing the third volume of the third aqueous suspension by a second microfiltration to provide a batch of aqueous suspension of bupivacaine encapsulated MVLs having a target concentration of bupivacaine from 12 mg/mL to 17 mg/mL; wherein the batch has a volume of at least 100 liters to about 300 liters; wherein the batch has a cumulative percentage release of bupivacaine from 46% to 71% at a 24-hour time point, measured from two to six aliquots of the batch using a rotator-facilitated in vitro release assay for at least 48 hours, after storage of the aliquots at 2° C. to 8° C. for about 12 months from batch manufacture date; and wherein the rate of change in the cumulative percentage release of bupivacaine at the 24-hour time point is 0.05%/month to 0.5%/month after storage of the aliquots at 2° C. to 8° C. for about 12 months. 2. The batch of claim 1, wherein the rate of change in the cumulative percentage release of bupivacaine at the 24-hour time point is 0.08%/month to 0.5%/month. 3. The batch of claim 2, wherein the rate of change in the cumulative percentage release of bupivacaine at the 24-hour time point is 0.1%/month to 0.4%/month. 4. The batch of claim 1, wherein the cumulative percentage release of bupivacaine of the batch is measured as the average of six aliquots. 5. The batch of claim 4, wherein each aliquot has a cumulative percentage release of bupivacaine from 36% to 81% at the 24-hour time point, and a cumulative percentage release of bupivacaine from 50% to 95% at the 48-hour time point. 6. The batch of claim 1, wherein the total bupivacaine concentration in the composition is about 13.3 mg/mL. 7. The batch of claim 1, wherein the mixing in step (a) is performed at a high speed from about 1100 rpm to about 1300 rpm for about 65 minutes to about 75 minutes. 8. The batch of claim 7, wherein the mixing in step (b) is performed at a low speed from about 445 rpm to about 680 rpm for about 60 to about 85 seconds. 9. The batch of claim 1, wherein the batch has a volume of about 110 L to about 250 L. 10. The batch of claim 1, wherein the first microfiltration feed flow rate comprises a beginning first microfiltration feed flow rate from about 290 L/min to about 350 L/min, and an end first microfiltration feed flow rate from about 250 L/min to about 310 L/min. 11. The batch of claim 10, wherein the diafiltration feed flow rate comprises a first stage diafiltration feed flow rate from about 250 L/min to 310 L/min and a second stage feed flow rate from about 245 L/min to about 265 L/min. 12. A batch comprising a composition of bupivacaine encapsulated multivesicular liposomes (MVLs), prepared by a process comprising: (a) mixing a first aqueous solution comprising phosphoric acid with a volatile water-immiscible solvent solution to form a water-in-oil first emulsion, wherein the volatile water-immiscible solvent solution comprises 1,2-dipalmitoyl-sn-glycero-3-phospho-rac-(1-glycerol) (DPPG) or a salt thereof, 1,2-dierucoylphosphatidylcholine (DEPC), tricaprylin and cholesterol, and wherein either the first aqueous solution or the volatile water-immiscible solvent solution comprises bupivacaine; (b) mixing the water-in-oil first emulsion with a second aqueous solution to form a water-in-oil-in-water second emulsion, wherein the second aqueous solution comprises lysine and at least one osmotic agent; (c) substantially removing the volatile water-immiscible solvent from the water-in-oil-in-water second emulsion by sparging the water-in-oil-in-water second emulsion to form a first aqueous suspension of bupivacaine encapsulated MVLs having a first volume; (d) reducing the first volume of the first aqueous suspension of bupivacaine encapsulated multivesicular liposomes by a first microfiltration to provide a second aqueous suspension of bupivacaine encapsulated MVLs having a second volume, wherein the first microfiltration feed flow rate is about 200 L/min to about 400 L/min; (e) exchanging the second aqueous suspension medium with a saline solution by diafiltration to provide a third aqueous suspension of bupivacaine encapsulated MVLs having a third volume, wherein the diafiltration feed flow rate is about 200 L/min to about 350 L/min; and (f) reducing the third volume of the third aqueous suspension by a second microfiltration to provide a batch of aqueous suspension of bupivacaine encapsulated MVLs having a target concentration of bupivacaine from 12 mg/mL to 17 mg/mL; wherein the batch has a volume of at least 100 liters to about 300 liters; wherein the batch has a cumulative percentage release of bupivacaine from 60% to 85% at a 48-hour time point, measured from two to six aliquots of the batch using a rotator-facilitated in vitro release assay for at least 48 hours, after storage of the aliquots at 2° C. to 8° C. for about 12 months from batch manufacture date; and wherein the rate of change in the cumulative percentage release of bupivacaine of the batch at the 48-hour time point is-0.18%/month to 0.33%/month after storage of the aliquots at 2° C. to 8° C. for about 12 months. 13. The batch of claim 12, wherein the rate of change in the cumulative percentage release of bupivacaine at the 48-hour time point is-0.15%/month to 0.30%/month. 14. The batch of claim 13, wherein the rate of change in the cumulative percentage release of bupivacaine at the 48-hour time point is from −0.12%/month to 0.28%/month. 15. The batch of claim 12, wherein the cumulative percentage release of bupivacaine of each batch is measured as the average of six aliquots. 16. The batch of claim 15, wherein each aliquot has a cumulative percentage release of bupivacaine from 36% to 81% at the 24-hour time point, and a cumulative percentage release of bupivacaine from 50% to 95% at the 48-hour time point. 17. The batch of claim 12, wherein the total bupivacaine concentration in the composition is about 13.3 mg/mL. 18. The batch of claim 12, wherein the mixing in step (a) is performed at a high speed from about 1100 rpm to about 1300 rpm for about 65 minutes to about 75 minutes. 19. The batch of claim 18, wherein the mixing in step (b) is performed at a low speed from about 445 rpm to about 680 rpm for about 60 to about 85 seconds. 20. The batch of claim 12, wherein the batch has a volume of about 110 L to about 250 L. 21. The batch of claim 12, wherein the first microfiltration feed flow rate comprises a beginning first microfiltration feed flow rate from about 290 L/min to about 350 L/min, and an end first microfiltration feed flow rate from about 250 L/min to about 310 L/min. 22. The batch of claim 21, wherein the diafiltration feed flow rate comprises a first stage diafiltration feed flow rate from about 250 L/min to 310 L/min and a second stage feed flow rate from about 245 L/min to about 265 L/min. 23. A method of treating or ameliorating pain in a subject in need thereof, comprising administering the composition of claim 6 to the subject. 24. The method of claim 23, wherein the administration is via local infiltration to a surgical site to provide local analgesia. 25. The method of claim 23, wherein the administration is via an interscalene brachial plexus nerve block, a femoral nerve block, an adductor canal block, or a sciatic nerve block in the popliteal fossa to provide regional analgesia. 26. The method of claim 23, wherein the composition has a volume of about 10 mL or 20 mL for a single-dose administration. 27. A method of treating or ameliorating pain in a subject in need thereof, comprising administering the composition of claim 17 to the subject. 28. The method of claim 27, wherein the administration is via local infiltration to a surgical site to provide local analgesia. 29. The method of claim 27, wherein the administration is via an interscalene brachial plexus nerve block, a femoral nerve block, an adductor canal block, or a sciatic nerve block in the popliteal fossa to provide regional analgesia. 30. The method of claim 27, wherein the composition has a volume of about 10 mL or 20 mL for a single-dose administration.

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