TY - JOUR
T1 - Experimentally induced abutment strains in three types of single-molar implant restorations
AU - Seong, Wook Jin
AU - Korioth, Tom W.P.
AU - Hodges, James S.
PY - 2000/9
Y1 - 2000/9
N2 - Statement of problem. The choice of single-molar implant design is difficult because of a lack of controlled, quantitative biomechanical analyses. Purpose. This study determined the effect of 3 single-molar implant designs on implant strains under a variety of homologous loading conditions. Material and methods. On each implant abutment, 4 strain gauges were placed axially at 90 degrees to each other on the buccal, lingual, mesial, and distal surfaces. Effects of implant design, load location, direction, and magnitude were tested on axial and bending (buccolingual and mesiodistal) strains of 3 single-molar implant designs: (1) single, 3.75-mm (regular) diameter implant, (2) single, 5-mm (wide) diameter implant, and (3) two 3.75-mm diameter (double) implants connected through a single-molar crown. Results were analyzed with ANOVA. Results. Variations in loading conditions induced 3-dimensionally complex abutment strains on the tested implant designs. Peak absolute strains in mesiodistal direction were 6493 με for design 1 and 3958 με on design 2, and 3160 με in bucco lingual direction on design 3. For all loading conditions, the single 3.75-mm diameter implant consistently experienced the largest strains compared with wide-diameter and double implant designs. Changes in centric contact location affected implant abutment strains differently among the 3 designs. Angulated force direction resulted in larger bending strains. Conclusion. For single-molar implant designs, an increase in implant number and diameter may effectively reduce experimental implant abutment strains.
AB - Statement of problem. The choice of single-molar implant design is difficult because of a lack of controlled, quantitative biomechanical analyses. Purpose. This study determined the effect of 3 single-molar implant designs on implant strains under a variety of homologous loading conditions. Material and methods. On each implant abutment, 4 strain gauges were placed axially at 90 degrees to each other on the buccal, lingual, mesial, and distal surfaces. Effects of implant design, load location, direction, and magnitude were tested on axial and bending (buccolingual and mesiodistal) strains of 3 single-molar implant designs: (1) single, 3.75-mm (regular) diameter implant, (2) single, 5-mm (wide) diameter implant, and (3) two 3.75-mm diameter (double) implants connected through a single-molar crown. Results were analyzed with ANOVA. Results. Variations in loading conditions induced 3-dimensionally complex abutment strains on the tested implant designs. Peak absolute strains in mesiodistal direction were 6493 με for design 1 and 3958 με on design 2, and 3160 με in bucco lingual direction on design 3. For all loading conditions, the single 3.75-mm diameter implant consistently experienced the largest strains compared with wide-diameter and double implant designs. Changes in centric contact location affected implant abutment strains differently among the 3 designs. Angulated force direction resulted in larger bending strains. Conclusion. For single-molar implant designs, an increase in implant number and diameter may effectively reduce experimental implant abutment strains.
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U2 - 10.1067/mpr.2000.109124
DO - 10.1067/mpr.2000.109124
M3 - Article
C2 - 11005905
AN - SCOPUS:0034277539
SN - 0022-3913
VL - 84
SP - 318
EP - 326
JO - Journal of Prosthetic Dentistry
JF - Journal of Prosthetic Dentistry
IS - 3
ER -