Stratistics MRC¿¡ µû¸£¸é ¼¼°èÀÇ Á¶Á÷ Çظ® ½ÃÀåÀº 2025³â¿¡ 3¾ï 6,070¸¸ ´Þ·¯·Î ÃßÁ¤µÇ°í, ¿¹Ãø ±â°£ Áß CAGR 10.6%·Î ¼ºÀåÇÒ Àü¸ÁÀ̸ç, 2032³â¿¡´Â 7¾ï 3,010¸¸ ´Þ·¯¿¡ À̸¦ Àü¸ÁÀÔ´Ï´Ù.
Á¶Á÷ Çظ®´Â º¹ÀâÇÑ »ý¹°ÇÐÀû Á¶Á÷À» ¿¬±¸ ¹× Ä¡·á ¿ëµµ·Î °³º° »ýÁ¸ °¡´ÉÇÑ ¼¼Æ÷·Î ºÐÇØÇÏ´Â °úÁ¤ÀÔ´Ï´Ù. ÀÌ ±â¼úÀº ´ÜÀÏ ¼¼Æ÷ ºÐ¼®, ¼¼Æ÷ ¹è¾ç, À¯µ¿ ¼¼Æ÷ °èÃø¿¡ ÇʼöÀûÀÌ¸ç °úÇÐÀÚµéÀº ¼¼Æ÷ÀÇ °Åµ¿°ú ´Ù¾ç¼ºÀ» Á¤È®ÇÏ°Ô ¿¬±¸ÇÒ ¼ö ÀÖ½À´Ï´Ù. Ä¡·á¹ýÀº ±â°èÀû Æļâ, È¿¼ÒÀû ¼ÒÈ, ÈÇÐÀû ó¸® µîÀ» Æ÷ÇÔÇϸç, °¢°¢ ¼¼Æ÷ÀÇ ¹«°á¼º ¹× ±â´É¼ºÀ» À¯ÁöÇϵµ·Ï Á¶Á¤µË´Ï´Ù. ¼¼Æ÷¸¦ º»·¡ÀÇ Á¶Á÷ ȯ°æÀ¸·ÎºÎÅÍ ºÐ¸®ÇÔÀ¸·Î½á, ¿¬±¸ÀÚ´Â Áúº´ ¸ÞÄ¿´ÏÁò, ¾à¹° ¹ÝÀÀ ¹× Àç»ý Ä¡·á¿¡ ´ëÇÑ ´õ ±íÀº ÀλçÀÌÆ®¸¦ ¾òÀ» ¼ö ÀÖÀ¸¸ç, Á¶Á÷ Çظ®´Â Çö´ë »ý¹° ÀÇÇÐÀÇ ±âº» ´Ü°è°¡ µÇ¾ú½À´Ï´Ù.
¼¼°èº¸°Ç±â±¸(WHO)¿¡ µû¸£¸é ¸¸¼ºÁúȯÀÇ ¼¼°èÀû ºÎ´ãÀº 2030³â±îÁö Àüü »ç¸ÁÀÇ 70%¿¡ ´ÞÇÒ °ÍÀ¸·Î ¿¹ÃøµÇ°í ÀÖ½À´Ï´Ù.
¼¼Æ÷ ±â¹Ý Ä¡·á¹ýÀÇ ±ÞÁõ
¼¼Æ÷ ±â¹Ý Ä¡·á¹ýÀÇ ±ÞÁõÀº °íÇ°ÁúÀÇ ´ÜÀÏ ¼¼Æ÷ ÇöŹ¾×¿¡ ´ëÇÑ ¼ö¿ä°¡ Áõ°¡ÇÔ¿¡ µû¶ó Á¶Á÷ Çظ® ½ÃÀåÀÇ °·ÂÇÑ ¼ºÀåÀ» °¡¼ÓÇÕ´Ï´Ù. Àç»ýÀÇ·á, ¸é¿ª¿ä¹ý, Áٱ⼼Æ÷ÀÇ ¿ëµµ°¡ È®´ëµÊ¿¡ µû¶ó Á¤¹ÐÇÏ°í È¿À²ÀûÀÎ Çظ® ±â¼úÀÌ ÇÏ·ùÀÇ ºÐ¼® ¹× Ä¡·á È¿°ú¿¡ ÇʼöÀûÀÌ µÇ°í ÀÖ½À´Ï´Ù. ÀÌ ±â¿îÀº È¿¼Ò ¹× ±â°èÀû Çظ® µµ±¸ÀÇ Çõ½ÅÀ» ÃËÁøÇÏ°í ¿¬±¸ ¿öÅ©Ç÷οì¿Í ÀÓ»ó È®À强À» °¡¼ÓÈÇÏ°í ÀÖ½À´Ï´Ù. ±Ã±ØÀûÀ¸·Î ÀÌ·¯ÇÑ Ãß¼¼´Â Á¶Á÷ 󸮸¦ Â÷¼¼´ë »ý¹° ÀÇÇÐÀû Çõ½ÅÀ» °¡´ÉÇÏ°Ô ÇÏ´Â ¸Å¿ì Áß¿äÇÑ °ÍÀ¸·Î ¹Ù²Ù°í ÀÖ½À´Ï´Ù.
È¿¼Ò ÆíÂ÷ ¹× ¹èÄ¡ ºÒÀÏÄ¡
È¿¼Ò ÆíÂ÷ ¹× ¹èÄ¡ ºÒÀÏÄ¡´Â ÀçÇö¼º, È®À强 ¹× ´Ù¿î½ºÆ®¸² µ¥ÀÌÅÍÀÇ ¹«°á¼ºÀ» ¼Õ»ó½ÃÄÑ Á¶Á÷ Çظ® ½ÃÀåÀ» ÇöÀúÇÏ°Ô ÀúÇØÇÕ´Ï´Ù. ÀÏ°ü¼ºÀÌ ¾ø´Â È¿¼Ò È°¼ºÀº ¿¹ÃøÇÒ ¼ö ¾ø´Â ¼¼Æ÷ ¼öÀ²°ú »ýÁ¸À²À» ÃÊ·¡ÇÏ¿© ¿¬±¸ °á°ú ¹× ÀÓ»ó ¿ëµµÀÇ ½Å·Ú¼ºÀ» ¼Õ»ó½Ãŵ´Ï´Ù. ÀÌ·¯ÇÑ º¯µ¿Àº °ËÁõ ºñ¿ëÀ» Áõ°¡½ÃÅ°°í Á¦Ç° °³¹ßÀ» Áö¿¬½ÃÅ°¸ç ±ÔÁ¦ ȯ°æ¿¡¼ Çظ® Å°Æ®ÀÇ Ã¤¿ëÀ» ¹æÇØÇÕ´Ï´Ù. ±Ã±ØÀûÀ¸·Î´Â Àç»ý ÀÇ·á, ´ÜÀϼ¼Æ÷ ºÐ¼® ¹× ¹ÙÀÌ¿ÀÇÁ·Î¼¼½ºÀÇ °¢ ºÐ¾ß¿¡¼ ½ÃÀåÀÇ ¼ºÀå°ú Çõ½ÅÀ» Á¦ÇÑÇÒ °ÍÀÔ´Ï´Ù.
´ÜÀÏ ¼¼Æ÷ ºÐ¼®ÀÇ Áøº¸
´ÜÀÏ ¼¼Æ÷ ºÐ¼®ÀÇ Áøº¸´Â Á¤¹Ð¼º, È®À强 ¹× ÀÚµ¿È ¼ö¿ä¸¦ ÃËÁøÇÔÀ¸·Î½á Á¶Á÷ Çظ® ½ÃÀå¿¡ Çõ¸íÀ» °¡Á®¿À°í ÀÖ½À´Ï´Ù. ¸¶ÀÌÅ©·ÎÇ÷çÀ̵ñ½º ±â¼ú°ú È¿¼Ò ±â¼úÀÌ °ÈµÊÀ¸·Î½á, ¼¼Æ÷ Ä¡·á ¹× ¸ÂÃãÇü ÀÇ·á µî ÇÏ·ùÀÇ ¿ëµµ¿¡ ÇʼöÀûÀÎ °í¼öÀ²·Î »ýÁ¸ °¡´ÉÇÑ ¼¼Æ÷ÀÇ ºÐ¸®°¡ °¡´ÉÇØÁ³½À´Ï´Ù. AI¿Í ÀÚµ¿È Ç÷§Æû°úÀÇ ÅëÇÕÀº ¿öÅ©Ç÷ο츦 °¡¼ÓÈÇÏ°í, ÆíÂ÷¸¦ ÁÙÀ̸ç, ÀçÇö¼ºÀ» ³ôÀÔ´Ï´Ù. ÀÌ·¯ÇÑ Çõ½ÅÀº ƯÈ÷ ¾Æ½Ã¾ÆÅÂÆò¾çÀÇ ¹ÙÀÌ¿À ÀǾàÇ° ¹× ¿¬±¸ ºÐ¾ß ÀüüÀÇ ¼ºÀåÀ» °¡¼ÓÇÏ°í Áö¿ø Á¤Ã¥ ¹× ¹ÙÀÌ¿À Å×Å©³î·ÎÁö¿¡ ´ëÇÑ ÅõÀÚ°¡ ½ÃÀå È®´ë¸¦ °¡¼ÓÈÇÏ°í ÀÖ½À´Ï´Ù.
÷´Ü ±â¼úÀÇ °í°¡
÷´Ü Á¶Á÷ Çظ® ±â¼úÀº ºñ¿ëÀÌ ¸¹ÀÌ µé±â ¶§¹®¿¡ ¼Ò±Ô¸ð ¿¬±¸ ±â°ü ¹× ½ÅÈï »ý¸í °øÇÐ ±â¾÷¿¡°Ô´Â »ç¿ëÇϱ⠾î·Æ°í ½ÃÀå ¼ºÀåÀ» ¹æÇØÇÏ°í ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ºñ¿ëÀº ¿î¿µ ¿¹»êÀ» ÆØâ½ÃÅ°°í º¸±ÞÀ» Á¦ÇÑÇÏ¸ç ¼¼Æ÷ ±â¹Ý Ä¡·á¹ý°ú Áø´Ü¹ýÀÇ ±â¼ú Çõ½ÅÀ» ´ÊÃß°í ÀÖ½À´Ï´Ù. ¶ÇÇÑ ºñ¿ë À庮Àº ½ÅÈï±¹ ½ÃÀå¿¡ ´ëÇÑ ÅõÀÚ¸¦ ¹æÇØÇÏ°í »ý¹°ÀÇÇÐ ¿¬±¸ ´É·ÂÀÇ ¼¼°èÀû °ÝÂ÷¸¦ ¾ÇȽÃÅ°¸ç Á¶Á÷ Çظ® ¼Ö·ç¼ÇÀÇ Àü¹ÝÀûÀÎ È®À强 ¹× »ó¾÷Àû ½ÇÇà °¡´É¼ºÀ» ÀúÇϽÃÅ°¹Ç·Î ½ÃÀå È®´ë°¡ Á¦Çѵ˴ϴÙ.
COVID-19ÀÇ ¿µÇâ
COVID-19ÀÇ À¯ÇàÀº ±ä±Þ ¹é½Å ¹× Ä¡·á¹ý °³¹ß¿¡ °ßÀεǾî Á¶Á÷ Çظ® ½ÃÀå ¼ö¿ä¸¦ °¡¼ÓÈÇß½À´Ï´Ù. Ãʱ⠿¬±¸¼ÒÀÇ È¥¶õ¿¡µµ ºÒ±¸ÇÏ°í ¿ø°Ý ¿¬±¸¿Í ºÐ»ê ¿öÅ©Ç÷οì´Â ±â¼¼¸¦ Áö¼ÓÇß½À´Ï´Ù. Á¶Á÷ Çظ® È¿¼Ò¿Í ±â±¸´Â ´ÜŬ·Ð Ç×ü »ý»ê°ú ¼¼Æ÷ ±â¹Ý ºÐ¼®¿¡ »ç¿ëµÇ´Â ¼¼Æ÷ ºÐ¸®¿¡ ÇʼöÀûÀÌ µÇ¾ú½À´Ï´Ù. ÀÌ·¯ÇÑ ¹ÙÀÌ¿À¸ÞµðÄà ¿¬±¸°³¹ß, ƯÈ÷ Àç»ýÀÇ·á ¹× ¸é¿ª¿ä¹ýÀÇ ±ÞÁõÀ¸·Î ½ÃÀåÀº ÆÒµ¥¹Í ÈÄ °·ÂÇÑ ¼ºÀåÀ» ÇâÇØ ÀÚ¸®¸Å±èÇß½À´Ï´Ù.
¿¹Ãø ±â°£ Áß Àç»ý ÀÇ·á ºÐ¾ß°¡ ÃÖ´ë°¡ µÉ Àü¸Á
Àç»ý ÀÇ·á ºÐ¾ß´Â Ã·´Ü È¿¼Ò ¹× ±â°èÀû Çظ® µµ±¸ ¼ö¿ä·Î ÀÎÇØ ¿¹Ãø ±â°£ µ¿¾È ÃÖ´ë ½ÃÀå Á¡À¯À²À» Â÷ÁöÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ¼¼Æ÷±â¹Ý Ä¡·á, Áٱ⼼Æ÷ ¿¬±¸, ¿À°¡³ëÀÌµå °³¹ßÀÌ ±ÞÁõÇÔ¿¡ µû¶ó Á¤È®ÇÑ Á¶Á÷ 󸮰¡ Áß¿äÇØÁý´Ï´Ù. ÀÌ µ¿ÇâÀº Çظ® ½Ã¾à°ú ±â±¸ÀÇ ±â¼ú Çõ½ÅÀ» ÃËÁøÇÏ¿© ¼¼Æ÷ ¼öÀ² ¹× »ýÁ¸À²À» ³ôÀÔ´Ï´Ù. Àç»ý ÀÇ·á°¡ Á¾¾çÇÐ, Á¤Çü¿Ü°úÇÐ, ½Å°æÇÐÀ¸·Î È®´ëµÇ´Â °¡¿îµ¥, ½ÃÀåÀº Áö¼ÓÀûÀÎ ±â¼¼¸¦ º¸ÀÌ°í ÀÖÀ¸¸ç, Á¶Á÷ Çظ®´Â Â÷¼¼´ë Ä¡·áÀÇ µ¹Æı¸¸¦ °¡´ÉÇÏ°Ô ÇÏ´Â ±â¹ÝÀ¸·Î ÀÚ¸®Àâ°í ÀÖ½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È µ¿¹° Á¶Á÷ ºÎ¹®ÀÇ CAGRÀÌ °¡Àå ³ôÀ» °ÍÀ¸·Î ¿¹»ó
¿¹Ãø ±â°£ µ¿¾È µ¿¹° Á¶Á÷ ºÎ¹®Àº °¡Àå ³ôÀº ¼ºÀå·üÀ» ³ªÅ¸³¾ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ÀÌ´Â ¿¬±¸ ¹× Ä¡·á ¿ëµµÀÇ °íÇ°Áú ´ÜÀÏ ¼¼Æ÷ ÇöŹ¾×ÀÇ Á¦Á¶¿¡ Áß¿äÇÑ ¿ªÇÒÀ» Çϱ⠶§¹®ÀÔ´Ï´Ù. È¿¼ÒÀû Çظ® ±â¼ú¿¡¼ÀÇ »ç¿ëÀº ¼¼Æ÷ ¿Ü ±âÁúÀÇ Á¤È®ÇÑ ºÐÇظ¦ Çã¿ëÇÏ°í ¼¼Æ÷ÀÇ »ýÁ¸À²°ú ¼öÀ²À» Çâ»ó½Ãŵ´Ï´Ù. ÀÌ°ÍÀº Á¾¾çÇÐ, ¸é¿ªÇÐ, Àç»ý ÀÇ·á µîÀÇ ºÐ¾ß¿¡¼ ƯÈ÷ Áß¿äÇÕ´Ï´Ù. °³ÀÎÈµÈ Ä¡·á ¹× ÷´Ü ¼¼Æ÷ ±â¹Ý ºÐ¼®¿¡ ´ëÇÑ ¼ö¿ä°¡ Áõ°¡ÇÔ¿¡ µû¶ó µ¿¹° Á¶Á÷ ±â¹Ý Çظ® µµ±¸°¡ ÇʼöÀûÀÌ µÇ¾î ½ÃÀå È®´ë ¹× Çõ½Å¿¡ ¹ÚÂ÷¸¦ °¡ÇÏ°í ÀÖ½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ¾Æ½Ã¾ÆÅÂÆò¾çÀÌ °¡Àå Å« ½ÃÀå Á¡À¯À²À» Â÷ÁöÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ÀÌ Áö¿ªÀº ¼¼Æ÷ ±â¹Ý Ä¡·á, ¾Ï ¿¬±¸, Á¤¹Ð ÀÇ·á¿¡ ´ëÇÑ ÅõÀÚ°¡ Áõ°¡ÇÏ°í ÀÖÀ¸¸ç, È¿¼ÒÀû ¹× ±â°èÀû Çظ® ±â¼úÀÇ ±Þ¼ÓÇÑ µµÀÔÀ» º¼ ¼ö ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ±â¼ú Çõ½ÅÀº È¿À²ÀûÀÎ ´ÜÀÏ ¼¼Æ÷ ºÐ¸®¸¦ °¡´ÉÇÏ°Ô ÇÏ°í Áٱ⠼¼Æ÷ ¿ëµµ ¹× â¾àÀÇ È¹±âÀûÀÎ °¡¼Óȸ¦ °¡´ÉÇÏ°Ô ÇÕ´Ï´Ù. ÀÇ·á ÀÎÇÁ¶óÀÇ ¼ºÀå ¹× »ý¸í°øÇÐ Á¤Ã¥ÀÇ Áö¿øÀ¸·Î ¾Æ½Ã¾ÆÅÂÆò¾çÀº Á¶Á÷ Çظ®ÀÇ ¼¼°èÀûÀÎ Çãºê·Î ºÎ»óÇÏ°í °úÇÐÀÇ Áøº¸¿Í Ä¡·á Çõ½ÅÀ» ÃËÁøÇÏ°í ÀÖ½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ºÏ¹Ì´Â °¡Àå ³ôÀº CAGRÀ» ³ªÅ¸³¾ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ´ÜÀÏ ¼¼Æ÷ Çؼ® ¹× Á¤¹Ð Áø´Ü ¼ö¿ä¿¡ ÀÇÇØ ÀÌ Áö¿ªÀº È¿¼ÒÀû ¹× ±â°èÀû Çظ® ±â¼úÀÇ Çõ½ÅÀ» ÃËÁøÇÏ°í ÀÖ½À´Ï´Ù. ÀÌ ±â¼¼´Â Á¾¾çÇÐ, ½Å°æ°úÇÐ, Áٱ⼼Æ÷ Ä¡·á¿¡¼ µ¹Æı¸¸¦ Áö¿øÇÏ¿© ¿¬±¸ È¿À²¼º°ú ÀÓ»ó ¼º°ú¸¦ Çâ»ó½Ãŵ´Ï´Ù. ¹ÙÀÌ¿ÀÅ×Å©³î·¯Áö ±â¾÷ ¹× Çмú±â°ü °£ÀÇ Àü·«Àû Á¦ÈÞ´Â ºÏ¹Ì¸¦ ¼¼Æ÷ ±â¹Ý ¿ëµµ ¹× ¸ÂÃãÇü ÀÇ·á ¼Ö·ç¼ÇÀÇ Áøº¸¿¡ ÀÖ¾î ¼¼°è ¸®´õ·Î ÀÚ¸®¸Å±èÇÏ¿© ä¿ëÀ» ´õ¿í °¡¼ÓÈÇÏ°í ÀÖ½À´Ï´Ù.
According to Stratistics MRC, the Global Tissue Dissociation Market is accounted for $360.7 million in 2025 and is expected to reach $730.1 million by 2032 growing at a CAGR of 10.6% during the forecast period. Tissue dissociation is the process of breaking down complex biological tissues into individual, viable cells for research or therapeutic applications. This technique is essential for single-cell analysis, cell culture, and flow cytometry, allowing scientists to study cellular behavior and diversity with precision. Methods include mechanical disruption, enzymatic digestion, and chemical treatments, each tailored to preserve cell integrity and functionality. By isolating cells from their native tissue environment, researchers gain deeper insights into disease mechanisms, drug responses, and regenerative therapies, making tissue dissociation a foundational step in modern biomedical science.
According to the World Health Organization (WHO), the global burden of chronic diseases is projected to reach 70% of all deaths by 2030.
Surge in Cell-Based Therapies
The surge in cell-based therapies is catalyzing robust growth in the tissue dissociation market, driven by rising demand for high-quality single-cell suspensions. As regenerative medicine, immunotherapy, and stem cell applications expand, precise and efficient dissociation techniques become critical for downstream analysis and therapeutic efficacy. This momentum is fostering innovation in enzymatic and mechanical dissociation tools, accelerating research workflows and clinical scalability. Ultimately, the trend is transforming tissue processing into a pivotal enabler of next-generation biomedical breakthroughs.
Enzyme Variability and Batch Inconsistency
Enzyme variability and batch inconsistency significantly hinder the tissue dissociation market by compromising reproducibility, scalability, and downstream data integrity. Inconsistent enzymatic activity leads to unpredictable cell yields and viability, undermining confidence in research outcomes and clinical applications. This variability increases validation costs, delays product development, and deters adoption of dissociation kits in regulated environments. Ultimately, it restricts market growth and innovation across regenerative medicine, single-cell analysis, and bioprocessing sectors.
Advancements in Single-Cell Analysis
Advancements in single-cell analysis are revolutionizing the tissue dissociation market by driving demand for precision, scalability, and automation. Enhanced microfluidic and enzymatic techniques now enable high-yield, viable cell isolation, crucial for downstream applications like cell therapy and personalized medicine. Integration with AI and automated platforms accelerates workflows, reduces variability, and boosts reproducibility. These innovations are catalyzing growth across biopharma and research sectors, especially in Asia-Pacific, where supportive policies and biotech investments are amplifying market expansion.
High Costs of Advanced Technologies
The high costs of advanced tissue dissociation technologies significantly hinder market growth by limiting accessibility for smaller research institutions and emerging biotech firms. These expenses inflate operational budgets; restrict widespread adoption, and slow innovation in cell-based therapies and diagnostics. Additionally, cost barriers deter investment in developing regions, exacerbating global disparities in biomedical research capabilities and reducing the overall scalability and commercial viability of tissue dissociation solutions, thus it limits market expansion.
Covid-19 Impact
The Covid-19 pandemic accelerated demand in the tissue dissociation market, driven by urgent vaccine and therapeutic development. Despite initial lab disruptions, remote research and decentralized workflows sustained momentum. Tissue dissociation enzymes and instruments became vital for isolating cells used in monoclonal antibody production and cell-based assays. This surge in biomedical R&D, especially in regenerative medicine and immunotherapy, positioned the market for robust post-pandemic growth.
The regenerative medicine segment is expected to be the largest during the forecast period
The regenerative medicine segment is expected to account for the largest market share during the forecast period, due to demand for advanced enzymatic and mechanical dissociation tools. As cell-based therapies, stem cell research, and organoid development surge, precise tissue processing becomes critical. This trend fosters innovation in dissociation reagents and instruments, enhancing cell yield and viability. With regenerative medicine expanding across oncology, orthopedics, and neurology, the market is witnessing sustained momentum, positioning tissue dissociation as a foundational enabler of next-gen therapeutic breakthroughs.
The animal tissue segment is expected to have the highest CAGR during the forecast period
Over the forecast period, the animal tissue segment is predicted to witness the highest growth rate, due to its critical role in producing high-quality single-cell suspensions for research and therapeutic applications. Its use in enzymatic dissociation techniques enables precise breakdown of extracellular matrices, enhancing cell viability and yield. This is especially vital for fields like oncology, immunology, and regenerative medicine. As demand for personalized therapies and advanced cell-based assays rises, animal tissue-based dissociation tools are becoming indispensable, fueling market expansion and innovation.
During the forecast period, the Asia Pacific region is expected to hold the largest market share due to rising investments in cell-based therapies, cancer research, and precision medicine, the region is witnessing rapid adoption of enzymatic and mechanical dissociation technologies. These innovations enable efficient single-cell isolation, accelerating breakthroughs in stem cell applications and drug discovery. With growing healthcare infrastructure and supportive biotech policies, Asia Pacific is emerging as a global hub for tissue dissociation, fostering scientific advancement and therapeutic innovation.
Over the forecast period, the North America region is anticipated to exhibit the highest CAGR, owing to demand for single-cell analysis and precision diagnostics, the region fosters innovation in enzymatic and mechanical dissociation technologies. This momentum supports breakthroughs in oncology, neuroscience, and stem cell therapies, enhancing research efficiency and clinical outcomes. Strategic collaborations between biotech firms and academic institutions further accelerate adoption, positioning North America as a global leader in advancing cell-based applications and personalized healthcare solutions.
Key players in the market
Some of the key players profiled in the Tissue Dissociation Market include Thermo Fisher Scientific Inc., Miltenyi Biotec, Worthington Biochemical Corporation, Roche Diagnostics, Sigma-Aldrich, BD Biosciences, STEMCELL Technologies Inc., Corning Incorporated, Takara Bio Inc., Bio-Rad Laboratories, Inc., PromoCell GmbH, CellSystems Biotechnologie Vertrieb GmbH, PanReac AppliChem GmbH, Enzymatics Inc., Creative Bioarray, Cell Biolabs, Inc., Biovision, Inc., Cyagen Biosciences Inc., Genlantis and HiMedia Laboratories Pvt. Ltd.
In July 2025, Thermo Fisher deepens its bond with Sanofi by acquiring a sterile fill-finish site in New Jersey. Over 200 local employees will join the fold, bolstering U.S. drug manufacturing capacity and honoring a tradition of domestic, dependable production. The move strengthens domestic manufacturing and is expected to close in H2 2025.
In July 2025, Takara Bio Europe and MACHEREY-NAGEL have joined forces in a bold distribution pact, delivering MN's precise RNA, DNA, and protein purification tools across ten European nations-melding upstream extraction with downstream PCR and NGS workflows, empowering scientists with seamless reliability.
In March 2025, Roche and Zealand Pharma unite, weaving a promising alliance to co-develop petrelintide-an amylin analog-for standalone use and in fusion with Roche's CT-388. This bold fusion may reshape obesity treatment, confronting its vast complexity and unmet needs with refined innovation.