Auto Strut: A novel smart robotic system for external fixation device for bone deformity correction, a preliminary experience

Gigi, Roy; Mor, Jacob; Lidor, Inbar; Ovadia, Dror; Segev, Eitan

doi:10.1302/1863-2548.15.210063

Cited by 10 publications

(7 citation statements)

References 18 publications

(31 reference statements)

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“…But conventional Ilizarov external fixator is not proper for multiplanar deformities correction because it was major for lengthening and axial correction. Hexapod external fixator has been proven to be effective in multiplanar deformities correction with high precision [18,19].…”

Section: Discussionmentioning

confidence: 99%

Combination of external fixation using digital six-axis fixator and internal fixation to treat severe complex knee deformity

Dong-sheng

Opoku

et al. 2023

J Orthop Surg Res

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Background Severe knee valgus/varus or complex multiplanar deformities are common in clinic. If not corrected in time, cartilage wear will be aggravated and initiate the osteoarthritis due to lower limb malalignment. Internal fixation is unable to correct severe complex deformities, especially when combined with lower limb discrepancy (LLD). Based on the self-designed digital six-axis external fixator Q spatial fixator (QSF), which can correct complex multiplanar deformities without changing structures, accuracy of correction can be improved significantly. Methods This retrospective study included 24 patients who suffered from complex knee deformity with LLD treated by QSF and internal fixation at our institution from January 2018 to February 2021. All patients had a closing wedge distal femoral osteotomy with internal fixation for immediate correction and high tibia osteotomy with QSF fixation for postoperative progressive correction. Data of correction prescriptions were computed by software from postoperative CT scans. Results Mean discrepancy length of operative side was 2.39 ± 1.04 cm (range 0.9–4.4 cm) preoperatively. The mean difference of lower limb was 0.32 ± 0.13 cm (range 0.11–0.58 cm) postoperatively. The length of limb correction had significant difference (p < 0.05). The mean MAD and HKA decreased significantly (p < 0.05), and the mean MPTA and LDFA increased significantly (p < 0.05). There were significant increase (p < 0.05) in the AKSS-O, AKSS-F and Tegner Activity Score. The lower limb alignment was corrected (p < 0.05). The mean time of removing external fixator was 112.8 ± 17.9 days (range 83–147 days). Conclusions Complex knee deformity with LLD can be treated by six-axis external fixator with internal fixation without total knee arthroplasty. Lower limb malalignment and discrepancy can be corrected precisely and effectively by this approach.

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Section: Discussionmentioning

confidence: 99%

Combination of external fixation using digital six-axis fixator and internal fixation to treat severe complex knee deformity

Dong-sheng

Opoku

et al. 2023

J Orthop Surg Res

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“…5-7, 11 A notable example is the Maxframe Autostrut system where full automatisation is achieved by adjusting the strut lengths with the installed electric motors according to the treatment recipe. 9 A path correction is proposed in the TSF frame to prevent the collision of the bony ends of the bone fragments during treatment. 32 Such approaches can be applied to the lambda fixator in the future.…”

Section: Simulation Of Lambda Fixatormentioning

confidence: 99%

“…2,3 It is used not only for stabilising the bone fragments in a fracture but also very convenient for the treatment of angular deformities and limb-length discrepancies. 4 Ring fixators have been the subject of many studies with regard to their usage for the treatment of specific pathologies, [5][6][7][8] their automation via supporting software 9,10 or increasing their durability. 11 Another advantage of ring fixators is that their geometry can be configured in many different ways providing flexibility in treatment.…”

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confidence: 99%

A new ring fixator system for automated bone fixation

Aydi(ı)n,

U(Ü)n

2024

Robotics Computer Surgery

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BackgroundIn the field of orthopaedics, external fixators are commonly employed for treating extremity fractures and deformities. Computer‐assisted systems offer a promising and less error‐prone treatment alternative to manual fixation by utilising a software to plan treatments based on radiological and clinical data. Nevertheless, existing computer‐assisted systems have limitations and constraints.MethodsThis work represents the culmination of a project aimed at developing a new automatised fixation system and a corresponding software to minimise human intervention and associated errors, and the developed system incorporates enhanced functionalities and has fewer constraints compared to existing systems.ResultsThe automatised fixation system and its graphical user interface (GUI) demonstrate promising results in terms of accuracy, efficiency, and reliability.ConclusionThe developed fixation system and its accompanying GUI represent an improvement in computer‐assisted fixation systems. Future research may focus on further refining the system and conducting clinical trials.

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“…Fenton et al compared the biomechanical properties of several hexapod frame constructs with the traditional Ilizarov construct and determined that the hexapod frames were more rigid under bending and torsional loading but less so under axial loading 70 . Preliminary results of deformity correction using a novel, motorized, hexapod frame revealed successful achievement of preoperative goals 71 . The device precludes the need for manual strut adjustments and thus may potentially decrease the risk of inaccurate adjustments.…”

Section: External Fixator Biomechanicsmentioning

confidence: 99%