Background/Aims: Constipation is a common gastrointestinal disease that reduces the quality of life and incurs considerable medical expenses. Bisacodyl and sodium docusate are generally used to treat constipation. This study assessed the effectiveness and safety of Goodmorning S Granule® (Hanpoong Pharm. Co., Ltd., Wanju, Korea) in functional constipation by a comparison with bisacodyl. Methods: A 2-week randomized, double-blind, active-controlled exploratory clinical trial was conducted to compare the treatment (Goodmorning S Granule® ) with the control (bisacodyl). The efficacy was measured by the changes in transition, Bristol stool type, stomachache, clinical manifestation, defecation time after drug consumption, 36-item short-form survey (SF-36), and the results of improvement evaluation. The safety was evaluated by the incidence of adverse drug events and vital signs. Additional analyses were conducted by dividing the severity according to the proportion of Bristol Stool Scale types 1 and 2. Results: Subjects were randomized to the treatment (n=24) or control (n=26) groups. No significant differences were observed in demographics. After 2 weeks from the baseline, the changes in the complete spontaneous bowel movement (CSBM) were higher in the treatment (4.00±2.62) group than in the control group (1.40±2.34) (p<0.05). The treatment group exhibited significant improvement in the score on the SF-36 questionnaire. The clinical side effects, such as stomachache and borborygmus, were reduced in the moderate constipation patients in the treatment group, according to additional analyses. Conclusions Goodmorning S Granule® , a herbal medicine, was more effective in improving quality of life and CSBM per week and safer in the moderate constipation groups because of the reduced clinical side effects.

Objective: This study aimed to investigate the effect of three-dimensional (3D) printed clear aligners (CA) with different designs on the extrusion of mandibular premolars using a force/moment measurement system and digital image correlation (DIC). Methods: The forces and moments applied to the mandibular canines, first and second premolars were measured using a multi-axis force/ moment transducer when an extrusion of 0.5 mm was planned, assuming the mandibular first premolars were intruded by 1 mm. In addition, displacement and strain changes in the CA were analyzed using the DIC method. CA designs were categorized based on the presence of first premolar attachment and subdivided into equigingival margins, 1-mm extended margins, equi-margins with 1-mm thickness and height, and equi-margins with 1-mm reduced buccolingual width.The CA was printed directly at a thickness of 0.5 mm, and the experiments were conducted at 37°C. Results: The results showed that attachment played an important role in the extrusion of first premolars in both the force/moment measurement system and the DIC method. Intrusion was observed without attachment, even though extrusion was planned. CA designs apply greater force to the cervical region by extending the margin or reducing the buccolingual width, thereby improving extrusion efficiency. Conclusions Force and moment changes in direct 3D printed CA are complex and difficult to predict; however, modifying aligner designs, such as extending the margin or reducing buccolingual width, and using appropriate attachments could minimize unwanted tooth movement, optimize planned treatment, and increase treatment predictability.

Objective: This study aimed to investigate the effect of three-dimensional (3D) printed clear aligners (CA) with different designs on the extrusion of mandibular premolars using a force/moment measurement system and digital image correlation (DIC). Methods: The forces and moments applied to the mandibular canines, first and second premolars were measured using a multi-axis force/ moment transducer when an extrusion of 0.5 mm was planned, assuming the mandibular first premolars were intruded by 1 mm. In addition, displacement and strain changes in the CA were analyzed using the DIC method. CA designs were categorized based on the presence of first premolar attachment and subdivided into equigingival margins, 1-mm extended margins, equi-margins with 1-mm thickness and height, and equi-margins with 1-mm reduced buccolingual width.The CA was printed directly at a thickness of 0.5 mm, and the experiments were conducted at 37°C. Results: The results showed that attachment played an important role in the extrusion of first premolars in both the force/moment measurement system and the DIC method. Intrusion was observed without attachment, even though extrusion was planned. CA designs apply greater force to the cervical region by extending the margin or reducing the buccolingual width, thereby improving extrusion efficiency. Conclusions Force and moment changes in direct 3D printed CA are complex and difficult to predict; however, modifying aligner designs, such as extending the margin or reducing buccolingual width, and using appropriate attachments could minimize unwanted tooth movement, optimize planned treatment, and increase treatment predictability.

Objective: This study aimed to investigate the effect of three-dimensional (3D) printed clear aligners (CA) with different designs on the extrusion of mandibular premolars using a force/moment measurement system and digital image correlation (DIC). Methods: The forces and moments applied to the mandibular canines, first and second premolars were measured using a multi-axis force/ moment transducer when an extrusion of 0.5 mm was planned, assuming the mandibular first premolars were intruded by 1 mm. In addition, displacement and strain changes in the CA were analyzed using the DIC method. CA designs were categorized based on the presence of first premolar attachment and subdivided into equigingival margins, 1-mm extended margins, equi-margins with 1-mm thickness and height, and equi-margins with 1-mm reduced buccolingual width.The CA was printed directly at a thickness of 0.5 mm, and the experiments were conducted at 37°C. Results: The results showed that attachment played an important role in the extrusion of first premolars in both the force/moment measurement system and the DIC method. Intrusion was observed without attachment, even though extrusion was planned. CA designs apply greater force to the cervical region by extending the margin or reducing the buccolingual width, thereby improving extrusion efficiency. Conclusions Force and moment changes in direct 3D printed CA are complex and difficult to predict; however, modifying aligner designs, such as extending the margin or reducing buccolingual width, and using appropriate attachments could minimize unwanted tooth movement, optimize planned treatment, and increase treatment predictability.

Objective: This study aimed to investigate the effect of three-dimensional (3D) printed clear aligners (CA) with different designs on the extrusion of mandibular premolars using a force/moment measurement system and digital image correlation (DIC). Methods: The forces and moments applied to the mandibular canines, first and second premolars were measured using a multi-axis force/ moment transducer when an extrusion of 0.5 mm was planned, assuming the mandibular first premolars were intruded by 1 mm. In addition, displacement and strain changes in the CA were analyzed using the DIC method. CA designs were categorized based on the presence of first premolar attachment and subdivided into equigingival margins, 1-mm extended margins, equi-margins with 1-mm thickness and height, and equi-margins with 1-mm reduced buccolingual width.The CA was printed directly at a thickness of 0.5 mm, and the experiments were conducted at 37°C. Results: The results showed that attachment played an important role in the extrusion of first premolars in both the force/moment measurement system and the DIC method. Intrusion was observed without attachment, even though extrusion was planned. CA designs apply greater force to the cervical region by extending the margin or reducing the buccolingual width, thereby improving extrusion efficiency. Conclusions Force and moment changes in direct 3D printed CA are complex and difficult to predict; however, modifying aligner designs, such as extending the margin or reducing buccolingual width, and using appropriate attachments could minimize unwanted tooth movement, optimize planned treatment, and increase treatment predictability.

Objective: This study aimed to investigate the effect of three-dimensional (3D) printed clear aligners (CA) with different designs on the extrusion of mandibular premolars using a force/moment measurement system and digital image correlation (DIC). Methods: The forces and moments applied to the mandibular canines, first and second premolars were measured using a multi-axis force/ moment transducer when an extrusion of 0.5 mm was planned, assuming the mandibular first premolars were intruded by 1 mm. In addition, displacement and strain changes in the CA were analyzed using the DIC method. CA designs were categorized based on the presence of first premolar attachment and subdivided into equigingival margins, 1-mm extended margins, equi-margins with 1-mm thickness and height, and equi-margins with 1-mm reduced buccolingual width.The CA was printed directly at a thickness of 0.5 mm, and the experiments were conducted at 37°C. Results: The results showed that attachment played an important role in the extrusion of first premolars in both the force/moment measurement system and the DIC method. Intrusion was observed without attachment, even though extrusion was planned. CA designs apply greater force to the cervical region by extending the margin or reducing the buccolingual width, thereby improving extrusion efficiency. Conclusions Force and moment changes in direct 3D printed CA are complex and difficult to predict; however, modifying aligner designs, such as extending the margin or reducing buccolingual width, and using appropriate attachments could minimize unwanted tooth movement, optimize planned treatment, and increase treatment predictability.