Background: Bone substitutes such as hydroxyapatite (HA) ceramic and recombinant bone morphogenetic protein-2 (BMP-2) are essential in treating bone defects. However, the challenges of controlled and localized BMP-2 delivery necessitate the development of advanced bone graft substitutes. This study introduces and evaluates an innovative, ready-to-use bone substitute employing 3-dimensional-printed poly-L-lactic acid (PLLA) scaffolds combined with BMP-2 to enhance bone regeneration efficiency. Methods: We conducted a comparative study using C57BL/6 mice to evaluate the efficacy of rhBMP-2-coated PLLA scaffolds against traditional HA-based bone graft materials. The PLLA scaffolds were coated with varying concentrations of BMP-2 using an alginate-catechol method. Bone regeneration was assessed through micro-computed tomography (CT) imaging and histological analysis 4 weeks after implantation. The statistical significance of bone mass and formation differences across groups was determined using Student t-test and analysis of variance. Results: Micro-CT analysis revealed substantial bone formation in the group with PLLA scaffolds containing 0.1% BMP-2, exhibiting a bone volume ratio of 11.1% ± 2.8%, significantly higher than all other groups (p = 0.008). Histological analysis corroborated these findings, showing dense collagen deposition and active osteoblast presence in this group, indicating enhanced bone regeneration. Conclusions The novel PLLA scaffold with alginate-catechol-coated BMP-2 significantly enhances bone regeneration compared to traditional bone graft materials. This innovative approach holds promising potential for clinical applications in orthopedics, particularly for treating bone defects.

Background: Bone substitutes such as hydroxyapatite (HA) ceramic and recombinant bone morphogenetic protein-2 (BMP-2) are essential in treating bone defects. However, the challenges of controlled and localized BMP-2 delivery necessitate the development of advanced bone graft substitutes. This study introduces and evaluates an innovative, ready-to-use bone substitute employing 3-dimensional-printed poly-L-lactic acid (PLLA) scaffolds combined with BMP-2 to enhance bone regeneration efficiency. Methods: We conducted a comparative study using C57BL/6 mice to evaluate the efficacy of rhBMP-2-coated PLLA scaffolds against traditional HA-based bone graft materials. The PLLA scaffolds were coated with varying concentrations of BMP-2 using an alginate-catechol method. Bone regeneration was assessed through micro-computed tomography (CT) imaging and histological analysis 4 weeks after implantation. The statistical significance of bone mass and formation differences across groups was determined using Student t-test and analysis of variance. Results: Micro-CT analysis revealed substantial bone formation in the group with PLLA scaffolds containing 0.1% BMP-2, exhibiting a bone volume ratio of 11.1% ± 2.8%, significantly higher than all other groups (p = 0.008). Histological analysis corroborated these findings, showing dense collagen deposition and active osteoblast presence in this group, indicating enhanced bone regeneration. Conclusions The novel PLLA scaffold with alginate-catechol-coated BMP-2 significantly enhances bone regeneration compared to traditional bone graft materials. This innovative approach holds promising potential for clinical applications in orthopedics, particularly for treating bone defects.

Background: Bone substitutes such as hydroxyapatite (HA) ceramic and recombinant bone morphogenetic protein-2 (BMP-2) are essential in treating bone defects. However, the challenges of controlled and localized BMP-2 delivery necessitate the development of advanced bone graft substitutes. This study introduces and evaluates an innovative, ready-to-use bone substitute employing 3-dimensional-printed poly-L-lactic acid (PLLA) scaffolds combined with BMP-2 to enhance bone regeneration efficiency. Methods: We conducted a comparative study using C57BL/6 mice to evaluate the efficacy of rhBMP-2-coated PLLA scaffolds against traditional HA-based bone graft materials. The PLLA scaffolds were coated with varying concentrations of BMP-2 using an alginate-catechol method. Bone regeneration was assessed through micro-computed tomography (CT) imaging and histological analysis 4 weeks after implantation. The statistical significance of bone mass and formation differences across groups was determined using Student t-test and analysis of variance. Results: Micro-CT analysis revealed substantial bone formation in the group with PLLA scaffolds containing 0.1% BMP-2, exhibiting a bone volume ratio of 11.1% ± 2.8%, significantly higher than all other groups (p = 0.008). Histological analysis corroborated these findings, showing dense collagen deposition and active osteoblast presence in this group, indicating enhanced bone regeneration. Conclusions The novel PLLA scaffold with alginate-catechol-coated BMP-2 significantly enhances bone regeneration compared to traditional bone graft materials. This innovative approach holds promising potential for clinical applications in orthopedics, particularly for treating bone defects.

Background: Bone substitutes such as hydroxyapatite (HA) ceramic and recombinant bone morphogenetic protein-2 (BMP-2) are essential in treating bone defects. However, the challenges of controlled and localized BMP-2 delivery necessitate the development of advanced bone graft substitutes. This study introduces and evaluates an innovative, ready-to-use bone substitute employing 3-dimensional-printed poly-L-lactic acid (PLLA) scaffolds combined with BMP-2 to enhance bone regeneration efficiency. Methods: We conducted a comparative study using C57BL/6 mice to evaluate the efficacy of rhBMP-2-coated PLLA scaffolds against traditional HA-based bone graft materials. The PLLA scaffolds were coated with varying concentrations of BMP-2 using an alginate-catechol method. Bone regeneration was assessed through micro-computed tomography (CT) imaging and histological analysis 4 weeks after implantation. The statistical significance of bone mass and formation differences across groups was determined using Student t-test and analysis of variance. Results: Micro-CT analysis revealed substantial bone formation in the group with PLLA scaffolds containing 0.1% BMP-2, exhibiting a bone volume ratio of 11.1% ± 2.8%, significantly higher than all other groups (p = 0.008). Histological analysis corroborated these findings, showing dense collagen deposition and active osteoblast presence in this group, indicating enhanced bone regeneration. Conclusions The novel PLLA scaffold with alginate-catechol-coated BMP-2 significantly enhances bone regeneration compared to traditional bone graft materials. This innovative approach holds promising potential for clinical applications in orthopedics, particularly for treating bone defects.

Background: Staged operations are commonly employed in the management of high-energy tibial plateau fractures (TPF) complicated by acute compartment syndrome (ACS); however, complications, such as nonunion, deep wound infection, and traumatic arthritis, often occur due to severe bone and soft-tissue damage. We aimed to report the radiological and clinical outcomes of staged surgical interventions performed following complete closure of the fasciotomy wound for the treatment of TPF complicated by ACS.Additionally, we analyzed factors associated with complications arising from these procedures. Methods: Thirty patients with TPF and ACS were included (23 men and 7 women; average age, 59.7 years). The mean followup period was 33.2 months (range, 12–85 months). An external fixator was initially applied with emergency fasciotomy, and open reduction and plate fixation were performed after complete closure of the fasciotomy wound and soft-tissue stabilization (mean, 31 days; range, 9–55 days). Radiological evaluation of bone union and alignment was conducted, functional evaluation of the knee and ankle joints was performed using the Knee Society and American Orthopedic Foot and Ankle Society (AOFAS) scores, and complications and related factors were analyzed. Results: Primary bone union was achieved in 29 of the 30 cases (96.7%) at an average of 20.8 weeks (range, 12–35 weeks). Malalignment was not observed in any case. At the final follow-up examination, the mean Knee Society and AOFAS scores were 92.5 (range, 65–100) and 95.5 (range, 74–100), respectively. Complications included 1 case of nonunion (3.3%), 2 cases of deep wound infection (6.7%), and 5 cases of traumatic arthritis (16.7%). A statistically significant correlation was noted between complications and patients who underwent dual approaches for the fixation of bicondylar TPFs. Conclusions A staged operation coupled with sufficient soft-tissue healing can achieve excellent bone union and functional outcomes in patients with TPF and ACS. However, complications may occur more often in patients undergoing dual approaches for bicondylar TPFs, necessitating vigilant monitoring and management.

Background: Staged operations are commonly employed in the management of high-energy tibial plateau fractures (TPF) complicated by acute compartment syndrome (ACS); however, complications, such as nonunion, deep wound infection, and traumatic arthritis, often occur due to severe bone and soft-tissue damage. We aimed to report the radiological and clinical outcomes of staged surgical interventions performed following complete closure of the fasciotomy wound for the treatment of TPF complicated by ACS.Additionally, we analyzed factors associated with complications arising from these procedures. Methods: Thirty patients with TPF and ACS were included (23 men and 7 women; average age, 59.7 years). The mean followup period was 33.2 months (range, 12–85 months). An external fixator was initially applied with emergency fasciotomy, and open reduction and plate fixation were performed after complete closure of the fasciotomy wound and soft-tissue stabilization (mean, 31 days; range, 9–55 days). Radiological evaluation of bone union and alignment was conducted, functional evaluation of the knee and ankle joints was performed using the Knee Society and American Orthopedic Foot and Ankle Society (AOFAS) scores, and complications and related factors were analyzed. Results: Primary bone union was achieved in 29 of the 30 cases (96.7%) at an average of 20.8 weeks (range, 12–35 weeks). Malalignment was not observed in any case. At the final follow-up examination, the mean Knee Society and AOFAS scores were 92.5 (range, 65–100) and 95.5 (range, 74–100), respectively. Complications included 1 case of nonunion (3.3%), 2 cases of deep wound infection (6.7%), and 5 cases of traumatic arthritis (16.7%). A statistically significant correlation was noted between complications and patients who underwent dual approaches for the fixation of bicondylar TPFs. Conclusions A staged operation coupled with sufficient soft-tissue healing can achieve excellent bone union and functional outcomes in patients with TPF and ACS. However, complications may occur more often in patients undergoing dual approaches for bicondylar TPFs, necessitating vigilant monitoring and management.

Background: Staged operations are commonly employed in the management of high-energy tibial plateau fractures (TPF) complicated by acute compartment syndrome (ACS); however, complications, such as nonunion, deep wound infection, and traumatic arthritis, often occur due to severe bone and soft-tissue damage. We aimed to report the radiological and clinical outcomes of staged surgical interventions performed following complete closure of the fasciotomy wound for the treatment of TPF complicated by ACS.Additionally, we analyzed factors associated with complications arising from these procedures. Methods: Thirty patients with TPF and ACS were included (23 men and 7 women; average age, 59.7 years). The mean followup period was 33.2 months (range, 12–85 months). An external fixator was initially applied with emergency fasciotomy, and open reduction and plate fixation were performed after complete closure of the fasciotomy wound and soft-tissue stabilization (mean, 31 days; range, 9–55 days). Radiological evaluation of bone union and alignment was conducted, functional evaluation of the knee and ankle joints was performed using the Knee Society and American Orthopedic Foot and Ankle Society (AOFAS) scores, and complications and related factors were analyzed. Results: Primary bone union was achieved in 29 of the 30 cases (96.7%) at an average of 20.8 weeks (range, 12–35 weeks). Malalignment was not observed in any case. At the final follow-up examination, the mean Knee Society and AOFAS scores were 92.5 (range, 65–100) and 95.5 (range, 74–100), respectively. Complications included 1 case of nonunion (3.3%), 2 cases of deep wound infection (6.7%), and 5 cases of traumatic arthritis (16.7%). A statistically significant correlation was noted between complications and patients who underwent dual approaches for the fixation of bicondylar TPFs. Conclusions A staged operation coupled with sufficient soft-tissue healing can achieve excellent bone union and functional outcomes in patients with TPF and ACS. However, complications may occur more often in patients undergoing dual approaches for bicondylar TPFs, necessitating vigilant monitoring and management.

Background: Staged operations are commonly employed in the management of high-energy tibial plateau fractures (TPF) complicated by acute compartment syndrome (ACS); however, complications, such as nonunion, deep wound infection, and traumatic arthritis, often occur due to severe bone and soft-tissue damage. We aimed to report the radiological and clinical outcomes of staged surgical interventions performed following complete closure of the fasciotomy wound for the treatment of TPF complicated by ACS.Additionally, we analyzed factors associated with complications arising from these procedures. Methods: Thirty patients with TPF and ACS were included (23 men and 7 women; average age, 59.7 years). The mean followup period was 33.2 months (range, 12–85 months). An external fixator was initially applied with emergency fasciotomy, and open reduction and plate fixation were performed after complete closure of the fasciotomy wound and soft-tissue stabilization (mean, 31 days; range, 9–55 days). Radiological evaluation of bone union and alignment was conducted, functional evaluation of the knee and ankle joints was performed using the Knee Society and American Orthopedic Foot and Ankle Society (AOFAS) scores, and complications and related factors were analyzed. Results: Primary bone union was achieved in 29 of the 30 cases (96.7%) at an average of 20.8 weeks (range, 12–35 weeks). Malalignment was not observed in any case. At the final follow-up examination, the mean Knee Society and AOFAS scores were 92.5 (range, 65–100) and 95.5 (range, 74–100), respectively. Complications included 1 case of nonunion (3.3%), 2 cases of deep wound infection (6.7%), and 5 cases of traumatic arthritis (16.7%). A statistically significant correlation was noted between complications and patients who underwent dual approaches for the fixation of bicondylar TPFs. Conclusions A staged operation coupled with sufficient soft-tissue healing can achieve excellent bone union and functional outcomes in patients with TPF and ACS. However, complications may occur more often in patients undergoing dual approaches for bicondylar TPFs, necessitating vigilant monitoring and management.

Background: The angular stable locking system (ASLS) was developed to provide additional stability to the distal interlocking screw of the intramedullary (IM) nail. Effects of ASLS on the treatment of femoral diaphyseal fractures in the elderly remain unknown. The aim of this study was to compare radiological outcomes of IM nailing using ASLS screws to IM nails with conventional interlocking screws in elderly patients with femoral shaft fractures. Methods: A multicenter retrospective review of 129 patients (average age, 73.5 years; 98 women and 31 men) aged 65 years or older who underwent IM nail fixation for femoral diaphyseal fractures (AO/Orthopaedic Trauma Association [OTA] classification 32) was conducted. Demographic information of patients, fracture site (subtrochanteric or shaft), fracture type (traumatic or atypical), and AO/OTA fracture classification were investigated. Reduction status was evaluated by postoperative plain radiography. Presence of union and time to union were evaluated through serial plain radiograph follow-up. Reoperation due to nonunion or implant failure was also evaluated. Results: ASLS was used in 65 patients (50.3%). A total of 118 patients (91.5%) achieved union without additional surgery and the mean union time was 31.8 ± 13.0 weeks. In terms of reduction status, angulation was greater in the group using ASLS. There were no statistically significant differences of union rate, time to union, and reoperation rate according to the use of ASLS (p > 0.05). There was no difference in the outcomes according to the use of ASLS even when the analysis was divided in terms of fracture site or fracture type (p > 0.05). In further subgroup analysis, only the traumatic subtrochanteric area group showed statistically significantly shorter time to union when ASLS was used (p = 0.038). Conclusions In geriatric patients with femoral diaphyseal fractures, the use of ASLS was not considered to have a significant effect on fracture healing. Fracture healing seemed to be more affected by surgical techniques such as minimizing the gap and fracture characteristics such as atypical femoral fractures, rather than implants.

BACKGROUND: Bone growth factors, particularly bone morphogenic protein-2 (BMP-2), are required for effective treatment of significant bone loss. Despite the extensive development of bone substitutes, much remains to be desired for wider application in clinical settings. The currently available bone substitutes cannot sustain prolonged BMP-2 release and are inconvenient to use. In this study, we developed a ready-to-use bone substitute by sequential conjugation of BMP to a three-dimensional (3D) poly(L-lactide) (PLLA) scaffold using novel molecular adhesive materials that reduced the operation time and sustained prolonged BMP release. METHODS: A 3D PLLA scaffold was printed and BMP-2 was conjugated with alginate-catechol and collagen. PLLA scaffolds were conjugated with different concentrations of BMP-2 and evaluated for bone regeneration in vitro and in vivo using a mouse calvarial model. The BMP-2 release kinetics were analyzed using ELISA. Histological analysis and microCT image analysis were performed to evaluate new bone formation. RESULTS: The 3D structure of the PLLA scaffold had a pore size of 400 lm and grid thickness of 187–230 lm. BMP-2 was released in an initial burst, followed by a sustained release for 14 days. Released BMP-2 maintained osteoinductivity in vitro and in vivo. Micro-computed tomography and histological findings demonstrate that the PLLA scaffold conjugated with 2 lg/ml of BMP-2 induced optimal bone regeneration. CONCLUSION The 3D-printed PLLA scaffold conjugated with BMP-2 enhanced bone regeneration, demonstrating its potential as a novel bone substitute.