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In vitro evaluation of the wear resistance of provisional resin materials fabricated by different methods
¾ÈÁ¾ÁÖ, ÇãÁߺ¸, ÃÖÀç¿ø,
¼Ò¼Ó »ó¼¼Á¤º¸
¾ÈÁ¾ÁÖ ( Ahn Jong-Ju ) - ºÎ»ê´ëÇб³ Ä¡ÀÇÇÐÀü¹®´ëÇпø Ä¡°úº¸Ã¶Çб³½Ç
ÇãÁߺ¸ ( Huh Jung-Bo ) - ºÎ»ê´ëÇб³ Ä¡ÀÇÇÐÀü¹®´ëÇпø Ä¡°úº¸Ã¶Çб³½Ç
ÃÖÀç¿ø ( Choi Jae-Won ) - ºÎ»ê´ëÇб³ Ä¡ÀÇÇÐÀü¹®´ëÇпø Ä¡°úº¸Ã¶Çб³½Ç
Abstract
¸ñÀû: º» ¿¬±¸ÀÇ ¸ñÀûÀº ÀûÃþ °¡°ø(additive manufacturing)¹ý, Àý»è °¡°ø(subtractive manufacturing)¹ý, ÀüÅëÀûÀÎ ¹æ¹ý¿¡ µû¸¥ Àӽà ¼öº¹¿ë ·¹ÁøÀÇ ¸¶¸ð ÀúÇ×¼ºÀ» Á¶»çÇÏ´Â °ÍÀÌ´Ù.
Àç·á ¹× ¹æ¹ý: Á¦ÀÛ¹æ¹ý¿¡ µû¶ó 4°³ÀÇ ±ºÀ¸·Î ³ª´©¾úÀ¸¸ç, °¢ ±ºÀº Àü¿ëÀÇ Àӽà ¼öº¹¿ë ·¹ÁøÀ» »ç¿ëÇÏ¿´´Ù: S3P±º, Stereolithography apparatus (SLA) 3D ÇÁ¸°ÅÍ ¹× Àü¿ëÀÇ ±¤°æȼº ¼öÁö·Î Á¦ÀÛÇÑ ±º; D3P±º, Digital Light Processing (DLP) 3D ÇÁ¸°ÅÍ ¹× Àü¿ëÀÇ ±¤°æȼº ¼öÁö·Î Á¦ÀÛÇÑ ±º; MIL±º, Milling machine ¹× ¹Ð¸µ¿ë ·¹Áø ºí·ÏÀ¸·Î Á¦ÀÛÇÑ ±º; CON±º, ÀüÅëÀûÀÎ ¹æ¹ý ¹× ÀÚ°¡ÁßÇÕÇü ·¹ÁøÀ¸·Î Á¦ÀÛÇÑ ±º. ÇÑÆí, 3D ÇÁ¸°ÆÃµÈ ·¹Áø ½ÃÆíÀ» Á¦ÀÛÇÔ¿¡ ÀÖ¾î ÀûÃþ °¢µµ¿Í Ãþ µÎ²²¸¦ °¢°¢ 0¡Æ¿Í 100 ¥ìm·Î ¼³Á¤ÇÏ¿´´Ù. ±¸°³» ȯ°æÀ» ÀçÇöÇϱâ À§ÇÏ¿© ¿¼øȯ ó¸®¿Í ¼öÆò, ¼öÁ÷¿îµ¿ÀÌ °¡´ÉÇÑ 2Ãà chewing simulator¸¦ »ç¿ëÇÏ¿´À¸¸ç, ÇϺο¡´Â ÇÑÂʸéÀÌ ÆíÆòÇÏ°Ô Á¦ÀÛµÈ Àӽà ¼öº¹¿ë ·¹ÁøÀ», »óºÎ¿¡´Â ³¡ÀÌ 3 mm Á÷°æÀ» °¡Áö´Â ¿ø»ÔÇüÀÇ steatite¸¦ °íÁ¤ÇÏ¿© ¸¶¸ð½ÃÇè ÁøÇàÇÏ¿´´Ù(5 kg, 30,000ȸ, 0.8 Hz, 5¡ÆC/55¡ÆC). Àӽà ¼öº¹¿ë ·¹ÁøÀÇ ¸¶¸ð·®Àº ¸¶¸ð ÀüÈÄÀÇ Standard Triangulated Language (STL) ÆÄÀÏ°ú Àü¿ëÀÇ CAD software¸¦ ÀÌ¿ëÇÏ¿© ºÎÇǸ¦ °è»êÇÏ¿´°í, ÁÖ»çÀüÀÚÇö¹Ì°æÀ¸·Î ¸¶¸ð ¾ç»óÀ» ºñ±³ÇÏ¿´´Ù.
°á°ú: S3P±º, D3P±º, MIL±ºÀÇ ¸¶¸ð·®Àº CON±ºº¸´Ù À¯ÀÇÇÏ°Ô ÀÛ¾ÒÀ¸¸ç (P < .05), S3P±º, D3P±º, MIL±º »çÀÌ¿¡´Â Åë°èÇÐÀûÀ¸·Î À¯ÀÇÇÑ Â÷ÀÌ°¡ ¾ø¾ú´Ù (P > .05). ÁÖ»çÀüÀÚÇö¹Ì°æÀ¸·Î ¸¶¸ð¸éÀ» °üÂûÇÑ °á°ú, S3P±º°ú D3P±º¿¡¼´Â ´ëÇÕÄ¡ÀÇ ¿îµ¿ ¹æÇâ¿¡ ´ëÇØ ¼öÁ÷ÀûÀ¸·Î °¥¶óÁø ÈçÀûÀÌ ¹ß°ßµÇ¾ú´Ù. MIL±º¿¡¼´Â Àü¹ÝÀûÀ¸·Î ±ÕÀÏÇÑ ¸¶¸ð¸éÀÌ º¸ÀÎ ¹Ý¸é, CON±º¿¡¼´Â ´ëÇÕÄ¡ ¿îµ¿ ¹æÇâÀ¸·ÎÀÇ ¶Ñ·ÇÇÑ ¸¶¸ð ÈçÀû°ú ´Ù¼öÀÇ ±âÆ÷°¡ °üÂûµÇ¾ú´Ù.
°á·Ð: º» ¿¬±¸ÀÇ ÇÑ°è ³»¿¡¼, 3D ÇÁ¸°ÆÃµÈ Àӽà ¼öº¹¿ë ·¹ÁøÀº Ä¡°ú¿ëÀ¸·Î¼ ÀûÀýÇÑ ¸¶¸ðÀúÇ×¼ºÀ» º¸¿´´Ù.
Purpose: This study was to evaluate the wear resistance of 3D printed, milled, and conventionally cured provisional resin materials.
Materials and methods: Four types of resin materials made with different methods were examined: Stereolithography apparatus (SLA) 3D printed resin (S3P), digital light processing (DLP) 3D printed resin (D3P), milled resin (MIL), conventionally self-cured resin (CON). In the 3D printed resin specimens, the build orientation and layer thickness were set to 0¡Æ and 100 ¥ìm, respectively. The specimens were tested in a 2-axis chewing simulator with the steatite as the antagonist under thermocycling condition (5 kg, 30,000 cycles, 0.8 Hz, 5¡ÆC/55¡ÆC). Wear losses of the specimens were calculated using CAD software and scanning electron microscope (SEM) was used to investigate wear surface of the specimens. Statistical significance was determined using One-way ANOVA and Dunnett T3 analysis (¥á = .05).
Results: Wear losses of the S3P, D3P, and MIL groups significantly smaller than those of the CON group (P < .05). There was no significant difference among S3P, D3P, and MIL group (P > .05). In the SEM observations, in the S3P and D3P groups, vertical cracks were observed in the sliding direction of the antagonist. In the MIL group, there was an overall uniform wear surface, whereas in the CON group, a distinct wear track and numerous bubbles were observed.
Conclusion: Within the limits of this study, provisional resin materials made with 3D printing show adequate wear resistance for applications in dentistry.
Å°¿öµå
3D ÇÁ¸°ÆÃ; ÀûÃþ °¡°ø; Àý»è °¡°ø; ·¹Áø; ¸¶¸ð
3D printing; Additive manufacturing; Subtractive manufacturing; Resin; Wear
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