À¯»ö ¹× ¹é»ö Áö¸£ÄÚ´Ï¾Æ ¼¼¶ó¹Í ÄÚÇÎÀÇ ÄÚÇÎ µðÀÚÀο¡ µû¸¥ ÆÄÀý ÇÏÁß°ú º¯¿¬ ÀûÇÕ¼º
Fracture load and marginal fitness of zirconia ceramic coping by design and coloration
½Å¹Ì¶õ, ±è¹ÎÁ¤, ¿À»óõ,
¼Ò¼Ó »ó¼¼Á¤º¸
½Å¹Ì¶õ ( Shin Mee-Ran ) - ÇѸ²´ëÇб³ ÀÓ»óÄ¡ÀÇÇдëÇпø Ä¡°úº¸Ã¶°ú
±è¹ÎÁ¤ ( Kim Min-Jeong ) - ¿ø±¤´ëÇб³ Ä¡°ú´ëÇÐ Ä¡°úº¸Ã¶Çб³½Ç
¿À»óõ ( Oh Sang-Chun ) - ¿ø±¤´ëÇб³ Ä¡°ú´ëÇÐ Ä¡°úº¸Ã¶Çб³½Ç
KMID : 0362420090470040406
Abstract
¿¬±¸¸ñÀû: º» ¿¬±¸´Â À¯»ö ¹× ¹é»ö Áö¸£ÄÚ´Ï¾Æ ¼¼¶ó¹ÍÀ¸·Î Á¦ÀÛµÈ ÄÚÇÎÀÇ µðÀÚÀο¡ µû¸¥ Áö¸£ÄÚ´Ï¾Æ ¼¼¶ó¹Í ÄÚÇÎÀÇ ÆÄÀý ÇÏÁß°ú º¯¿¬ ÀûÇÕ¼ºÀ» Æò°¡ÇÑ °ÍÀ¸·Î ±× °á°ú¸¦ ÀÓ»ó¿¡ ÀÀ¿ëÇϴµ¥ µµ¿òÀ» ÁÖ°íÀÚ ÇÏ¿´´Ù.
¿¬±¸Àç·á ¹× ¹æ¹ý: CAD/CAM system (Everset, KAVO Dental GmbH, Biberach, Germany)À» ÀÌ¿ëÇÏ¿©, 80°³ÀÇ »ó¾Ç Á¦ 1 ¼Ò±¸Ä¡ ¼¼¶ó¹Í ÄÚÇÎÀ» Á¦ÀÛÇϵÇ, 1±×·ìÀº ÀüüÀûÀ¸·Î ±ÕÀÏÇÏ°Ô 0.3 mm·Î, 2±×·ìÀº Çù¸é 0.3 mm ¼³¸é 0.6 mm, 3±×·ìÀº Àüü 0.6 mm ±ÕÀÏÇÏ°Ô, 4±×·ìÀº Çù¸é 0.6 mm ¼³¸é 1.0 mm·Î µðÀÚÀÎÇÏ°í, À¯»ö (I) ¹× ¹é»ö (II) Áö¸£ÄÚ´Ï¾Æ ÄÚÇÎÀ» °¢ ±×·ì´ç 10°³°¡ µÇ°Ô ÇÏ¿´´Ù. ¼Ò¼ºÁ÷ÈÄ¿Í Á¶Á¤ ÈÄ ÄÚÇÎÀÇ º¯¿¬ ÀûÇÕ¼ºÀ» Video Microscope System (sv-35, Sometech, Seoul, Korea)¸¦ ÀÌ¿ëÇÏ¿© 100¹èÀ²·Î °üÂûÇÏ¿´°í, ±Ý¼Ó ÁÖ ¸ðÇü¿¡ ÄÚÇÎÀ» °ÈÇü ±Û·¡½º¾ÆÀÌ¿À³ë¸Ó ½Ã¸àÆ®·Î ÇÕÂø ÈÄ Universal Testing Machine (Instron 4467, Norwood, MA, USA)À» ÀÌ¿ëÇÏ¿© ÆÄÀý ÇÏÁßÀ» ÃøÁ¤ÇÏ¿©, one-way ANOVA test ¸¦ ½ÃÇàÇÏ¿© °á°ú¸¦ ºÐ¼®ÇÏ¿´´Ù.
°á °ú: 1. CAD/CAM Áö¸£ÄÚ´Ï¾Æ ÄÚÇÎÀÇ ÆÄÀý ÇÏÁßÀº 1±×·ì, 2¿Í 3±×·ì, ±×¸®°í 4±×·ì°£¿¡ À¯ÀǼºÀÖ´Â Â÷À̸¦ º¸¿´À¸¸ç I4, II4ÀÇ ÆÄÀý ÇÏÁß°ªÀÌ °¡Àå ÄÇ´Ù. 2. ÄÚÇÎÀÇ µðÀÚÀÎÀÌ °°°í »öÀÌ ´Ù¸¥ ±×·ì°£ÀÇ ºñ±³¿¡¼´Â Àü ±×·ì ¸ðµÎ ÆÄÀý ÇÏÁß°ªÀÇ À¯ÀǼºÀº ¾ø¾ú´Ù. 3. ¼Ò¼º Á÷ÈÄ º¯¿¬ ¿ÀÂ÷ ÃøÁ¤°ªÀº I2±×·ìÀ» Á¦¿ÜÇÑ Àü ±×·ì¿¡¼ ÇùÃø ÃøÁ¤Á¡¿¡¼ º¯¿¬¿ÀÂ÷°¡ °¡Àå Å« °æÇâÀ» º¸¿´´Ù. 4. ¼Ò¼º Á÷ÈÄ º¯¿¬ ¿ÀÂ÷ ÃøÁ¤°ªÀº I ±×·ì Áö¸£ÄÚ´Ï¾Æ ±×·ì¿¡¼ ±×·ìº° ÀüüÀûÀÎ º¯¿¬ÀûÇÕµµ¸¦ º¸¾ÒÀ» ¶§ ±×·ì°£¿¡ À¯ÀÇÇÑ Â÷ÀÌ´Â ¾ø¾ú´Ù (P > .05). 5. ¼Ò¼ºÁ÷ÈÄ º¯¿¬ ¿ÀÂ÷ ÃøÁ¤°ªÀº ¹é»ö Áö¸£ÄÚ´Ï¾Æ ±×·ì¿¡¼ ±×·ìº° ÀüüÀûÀÎ º¯¿¬ ÀûÇÕµµ¸¦ º¸¾ÒÀ» ¶§ II1±×·ìÀÇ º¯¿¬ ¿ÀÂ÷°¡ °¡Àå ÄÇ´Ù (P < .05). 6. ¼Ò¼ºÁ÷ÈÄ º¯¿¬¿ÀÂ÷ ÃøÁ¤°ªÀº µðÀÚÀÎÀÌ °°Àº ±×·ìÀÇ À¯»ö, ¹é»ö ºñ±³¿¡¼, I1¿Í II1±×·ìÀ» Á¦¿ÜÇÑ ³ª¸ÓÁö ±×·ì¿¡¼ ¹é»ö Áö¸£ÄڴϾÆÀÇ º¯¿¬ ÀûÇÕµµ°¡ ´õ ÁÁ¾Ò´Ù (P < .05). 7. ³»¸é Á¶Á¤ ÈÄ¿¡´Â »ö»óÈ ¹× Áö¸£ÄÚ´Ï¾Æ ÄÚ¾î µðÀÚÀο¡ µû¸¥ Àü ±×·ì°£ º¯¿¬ ÀûÇÕµµÀÇ Â÷ÀÌ´Â ¾ø¾ú´Ù (P > .05).
°á ·Ð: Áö¸£ÄÚ´Ï¾Æ ÄÚÇÎ µðÀÚÀΰú »ö»óÈ¿¡ µû¸¥ º¯¿¬ ÀûÇÕ¼ºÀº ¼Ò¼º Á÷ÈÄ¿¡´Â ´Ù¼Ò Â÷ÀÌ°¡ ÀÖ¾úÀ¸³ª ³»¸é Á¶Á¤À» Çϸé ÀÓ»ó »ç¿ë¿¡´Â ¹«¸®°¡ ¾øÀ» °ÍÀ¸·Î ÆǴܵǾú°í, ÆÄÀý°µµ °È¸¦ À§ÇØ ÄÚÇÎÀÇ µÎ²²´Â °¡±ÞÀû µÎ²¨¿ö¾ß Çϳª, °¡½Ã¸é (¼ø¸é, Çù¸é)ÀÇ ½É¹Ì¼º(¹ÝÅõ¸í¼º)À» °í·ÁÇÒ °æ¿ì °¡½Ã¸éÀ» 0.3 mm·Î ¾ã°Ô Çصµ ÆÄÀý °µµ¿¡ Å« ¿µÇâÀ» ÁÖÁö ¾Ê´Â °ÍÀ¸·Î »ç·áµÇ¾ú´Ù.
Purpose: The purpose of this study was to compare the marginal fitness and fracture load of the zirconia copings according to the design with different thickness and coloration.
Material and Methods: The evaluation was based on 80 zirconia copings. Zirconia copings were fabricated in design with different thicknesses using CAD/CAM system (Everset, KAVO dental GmbH, Biberach, Germany). The designs of copings were divided into four groups. The first group consisted of copings with uniform thickness of 0.3 mm. The thickness in the second group was 0.3 mm on the buccal surface and 0.6 mm on the lingual surface. The third group consisted of coping with uniform thickness of 0.6 mm. The thickness in the fourth group was 0.6 mm on the buccal surface and 1mm on the lingual surface. Each group consisted of 10 colored and 10 uncolored copings. Half of the copings (40) processed with a milling system according to the specific design were sent to be given a color (A3) through saturation in special dye by a manufacturing company. Just after sintering, the marginal discrepancies of copings were measured on the buccal, lingual, mesial and distal surfaces of metal die, under a Video Microscope System (sv-35, Sometech, Seoul, Korea) at a magnification of ¡¿ 100. It was remeasured after the adjusting of the inner surface. Next, all copings were luted to the metal dies using reinforced cement {GC FujiCEM (GC Corp. Tokyo, Japan)} and mounted on the testing jig in a Universal Testing Machine (Instron 4467, Norwood, MA, USA). The results were analyzed statistically using the one-way ANOVA test.
Results: The obtained results were as follow: 1. The measured value of marginal discrepancy right after sintering was the greatest in the contraction of the buccal area in all groups, except for group I2. 2. There was no significant difference of marginal fitness among the groups in the colored zirconia group (P < .05). 3. When the marginal fitness among the groups in the uncolored zirconia group was considered, group II2 had the smallest marginal discrepancy. 4. When the colored and uncolored groups with the same design were compared, there was a significant difference between I1 and II1 groups. In group 2, 3, and 4, the uncolored zirconia had the greatest marginal fitness (P < .05). 5. After adjustment of inner surface, there was no significant difference in the marginal fitness in all groups when color and design of the zirconia coping were compared. 6. The fracture load of CAD/CAM zirconia copings showed significant difference in group 1, 2, 3, and 4. I4 and II4 had the strongest fracture load. 7. When groups with different color and same design were compared, all colored groups showed greater fracture load (P > .05), with no significance.
Conclusion: There was difference in the marginal fitness according to the design and coloration of zirconia copings right after sintering, but it was decided that the copings may well be used clinically if the inner surface are adjusted. The copings should be thick enough for the reinforcement of fracture strength. But considering the esthetics of the visible surfaces (labial and buccal surface), the thickness of copings may be a little thin, without giving any significant effect on the fracture strength. This type of design may be considered when giving priority to preservation of tooth or esthetics.
Å°¿öµå
Áö¸£ÄÚ´Ï¾Æ ¼¼¶ó¹Í ÄÚÇÎ;µðÀÚÀÎ;»ö»ó;CAD/CAM;º¯¿¬ ÀûÇÕ¼º;ÆÄÀý ÇÏÁß
Zirconia ceramic copings;Design;Coloration;CAD/CAM;Marginal fitness;Fracture strength
¿ø¹® ¹× ¸µÅ©¾Æ¿ô Á¤º¸
µîÀçÀú³Î Á¤º¸