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Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_18 | Pages 15 - 15
14 Nov 2024
Heumann M Feng C Benneker L Spruit M Mazel C Buschbaum J Gueorguiev B Ernst M
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Introduction

In daily clinical practice, progression of spinal fusion is typically monitored during clinical follow-up using conventional radiography and Computed Tomography scans. However, recent research has demonstrated the potential of implant load monitoring to assess posterolateral spinal fusion in an in-vivo sheep model. The question arises to whether such a strain sensing system could be used to monitor bone fusion following lumbar interbody fusion surgery, where the intervertebral space is supported by a cage. Therefore, the aim of this study was to test human cadaveric lumbar spines in two states: after a transforaminal lumbar interbody fusion (TLIF) procedure combined with a pedicle-screw-rod-construct (PSR) and subsequently after simulating bone fusion. The study hypothesized that the load on the posterior instrumentation decreases as the segment stiffens due to simulated fusion.

Method

A TLIF procedure with PSR was performed on eight human cadaveric spines at level L4-L5. Strain sensors were attached bilaterally to the rods to derive implant load changes during unconstrained flexion-extension (FE), lateral bending (LB) and axial rotation (AR) loads up to ±7.5Nm. The specimens were retested after simulating bone fusion between vertebrae L4-L5. In addition, the range of motion (ROM) was measured during each loading mode.


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_2 | Pages 31 - 31
2 Jan 2024
Ernst M Windolf M Varjas V Gehweiler D Gueorguiev-Rüegg B Richards R
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In absence of available quantitative measures, the assessment of fracture healing based on clinical examination and X-rays remains a subjective matter. Lacking reliable information on the state of healing, rehabilitation is hardly individualized and mostly follows non evidence-based protocols building on common guidelines and personal experience. Measurement of fracture stiffness has been demonstrated as a valid outcome measure for the maturity of the repair tissue but so far has not found its way to clinical application outside the research space. However, with the recent technological advancements and trends towards digital health care, this seems about to change with new generations of instrumented implants – often unfortunately termed “smart implants” – being developed as medical devices.

The AO Fracture Monitor is a novel, active, implantable sensor system designed to provide an objective measure for the assessment of fracture healing progression (1). It consists of an implantable sensor that is attached to conventional locking plates and continuously measures implant load during physiological weight bearing. Data is recorded and processed in real-time on the implant, from where it is wirelessly transmitted to a cloud application via the patient's smartphone. Thus, the system allows for timely, remote and X-ray free provision of feedback upon the mechanical competence of the repair tissue to support therapeutic decision making and individualized aftercare.

The device has been developed according to medical device standards and underwent extensive verification and validation, including an in-vivo study in an ovine tibial osteotomy model, that confirmed the device's capability to depict the course of fracture healing as well as its long-term technical performance. Currently a multi-center clinical investigation is underway to demonstrate clinical safety of the novel implant system. Rendering the progression of bone fracture healing assessable, the AO Fracture Monitor carries potential to enhance today's postoperative care of fracture patients.


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_2 | Pages 82 - 82
2 Jan 2024
Barcik J Ernst M Buchholz T Constant C Mys K Epari D Zeiter S Gueorguiev B Windolf M
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Secondary bone healing is impacted by the extent of interfragmentary motion at the fracture site. It provides mechanical stimulus that is required for the formation of fracture callus. In clinical settings, interfragmentary motion is induced by physiological loading of the broken bone – for example, by weight-bearing. However, there is no consensus about when mechanical stimuli should be applied to achieve fast and robust healing response. Therefore, this study aims to identify the effect of the immediate and delayed application of mechanical stimuli on secondary bone healing.

A partial tibial osteotomy was created in twelve Swiss White Alpine sheep and stabilized using an active external fixator that induced well-controlled interfragmentary motion in form of a strain gradient. Animals were randomly assigned into two groups which mimicked early (immediate group) and late (delayed group) weight-bearing. The immediate group received daily stimulation (1000 cycles/day) from the first day post-op and the delayed group from the 22nd day post-op. Healing progression was evaluated by measurements of the stiffness of the repair tissue during mechanical stimulation and by quantifying callus area on weekly radiographs. At the end of the five weeks period, callus volume was measured on the post-mortem high-resolution computer tomography (HRCT) scan.

Stiffness of the repair tissue (p<0.05) and callus progression (p<0.01) on weekly radiographs were significantly larger for the immediate group compared to the delayed group. The callus volume measured on the HRCT was nearly 3.2 times larger for the immediate group than for the delayed group (p<0.01).

This study demonstrates that the absence of immediate mechanical stimuli delays callus formation, and that mechanical stimulation already applied in the early post-op phase promotes bone healing.


Orthopaedic Proceedings
Vol. 105-B, Issue SUPP_17 | Pages 16 - 16
24 Nov 2023
Siverino C Gens L Ernst M Buchholz T Windolf M Richards G Zeiter S Moriarty F
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Aim

Debridement, Antibiotics, Irrigation, and implant Retention (DAIR) is a surgical treatment protocol suitable for some patients with fracture related infection (FRI). Clinically relevant pre-clinical models of DAIR are scarce and none have been developed in large animals. Therefore, this project aimed to develop a large animal model for FRI including a DAIR approach and compare outcomes after 2 or 5 weeks of infection.

Method

Swiss Alpine sheep (n=8), (2–6 years, 50–80 kg) were included in this study. This study was approved by cantonal Ethical authorities in Chur, Switzerland. A 2 mm osteotomy was created in the tibia and fixed with a 10-hole 5.5 mm steel plate. Subsequently, 2.5 mL of saline solution containing 106 CFU/mL of Staphylococcus aureus MSSA (ATCC 25923) was added over the plate. Sheep were observed for 2 (n=3) or 5 weeks (n=5) until revision surgery, during which visibly infected or necrotic tissues were removed, and the wound flushed with saline. All samples were collected for bacterial quantification. After revision surgery, the sheep were treated systemically for 2 weeks with flucloxacillin and for 4 weeks with rifampicin and cotrimoxazole. After 2 further weeks off antibiotics, the animals were euthanized. Bacteriological culture was performed at the end of the study. Bone cores were isolated from the osteotomy site and processed for Giemsa & Eosin and Brown and Brenn staining. A radiographical examination was performed every second week.


Orthopaedic Proceedings
Vol. 103-B, Issue SUPP_13 | Pages 49 - 49
1 Nov 2021
Barcik J Ernst M Buchholz T Constant C Zeiter S Gueorguiev B Windolf M
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Introduction and Objective

It is widely accepted that interfragmentary strain stimulus promotes callus formation during secondary bone healing. However, the impact of the temporal variation of mechanical stimulation on fracture healing is still not well understood. Moreover, the minimum strain value that initiates callus formation is unknown. The goal of this study was to develop an active fixation system that allows for in vivo testing of varying temporal distribution of mechanical stimulation and that enables detection of the strain limit that initiates callus formation.

Materials and Methods

We employed a previously established wedge defect model at the sheep tibia. The model incorporates two partial osteotomies directed perpendicularly to each other, thus creating a bone fragment in the shape of a wedge. The defect was instrumented with an active fixator that tilts the wedge around its apex to create a gradient of interfragmentary strain along the cutting line. The active fixator was equipped with a force and displacement sensors to measure the stiffness of the repair tissue during the course of healing. We developed a controller that enabled programming of different stimulation protocols and their autonomous execution during the in vivo experiment. The system was implanted in two sheep for a period of five weeks. The device was configured to execute immediate stimulation for one animal (stimulation from Day 1), and delayed stimulation for the other (stimulation from Day 22). The daily stimulation protocol consisted of 1’000 loading events evenly distributed over 12 hours from 9:00 am to 9:00 pm. The healing progression was monitored by the in vivo stiffness measurements provided by the fixator and by weekly radiographs. The impact of the local strain magnitude on bone formation was qualitatively evaluated on a post-mortem high-resolution CT scan of the animal with immediate stimulation.


Orthopaedic Proceedings
Vol. 103-B, Issue SUPP_4 | Pages 11 - 11
1 Mar 2021
Barcik J Ernst M Balligand M Dlaska CE Drenchev L Todorov S Gueorguiev B Skulev H Zeiter S Epari D Windolf M
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The course of secondary fracture healing typically consists of four major phases including inflammation, soft and hard callus formation, and bone remodeling. Callus formation is promoted by mechanical stimulation, yet little is known about the healing tissue response to strain stimuli over shorter timeframes on hourly and daily basis. The aim of this study was to explore the hourly, daily and weekly variations in bone healing progression and to analyze the short-term response of the repair tissue to well-controlled mechanical stimulation.

A system for continuous monitoring of fracture healing was designed for implantation in sheep tibia. The experimental model was adapted from Tufekci et al. 2018 and consisted of 3 mm transverse osteotomy and 30 mm bone defect resulting in an intermediate mobile bone fragment in the tibial shaft. Whereas the distal and proximal parts of the tibia were fixed with external fixator, the mobile fragment was connected to the proximal part via a second, active fixator. A linear actuator embedded in the active fixator moved the mobile fragment axially, thus stimulating mechanically the tissue in the osteotomy gap via well-controlled displacement being independent from the sheep's functional weightbearing. A load sensor was integrated in the active fixation to measure the force acting in the osteotomy gap. During each stimulation cycle the displacement and force magnitudes were recorded to determine in vivo fracture stiffness. Following approval of the local ethics committee, experiments were conducted on four skeletally mature sheep. Starting from the first day after surgery, the daily stimulation protocols consisted of 1000 loading events equally distributed over 12 hours from 9:00 to 21:00 resulting in a single loading event every 44 seconds. No stimulation was performed overnight.

One animal had to be excluded due to inconsistencies in the load sensor data. The onset of tissue stiffening was detected around the eleventh day post-op. However, on a daily basis, the stiffness was not steadily increasing, but instead, an abrupt drop was observed in the beginning of the daily stimulations. Following this initial drop, the stiffness increased until the last stimulation cycle of the day.

The continuous measurements enabled resolving the tissue response to strain stimuli over hours and days. The presented data contributes to the understanding of the influence of patient activity on daily variations in tissue stiffness and can serve to optimize rehabilitation protocols post fractures.


Orthopaedic Proceedings
Vol. 103-B, Issue SUPP_4 | Pages 7 - 7
1 Mar 2021
Barcik J Ernst M Freitag L Dlaska CE Drenchev L Todorov S Gueorguiev B Skulev H Zeiter S Epari D Windlof M
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In the course of uneventful secondary bone healing, a fracture gap is progressively overgrown by callus which subsequently calcifies and remodels into new bone. It is widely accepted that callus formation is promoted by mechanical stimulation of the tissue in the fracture gap. However, the optimal levels of the interfragmentary motion's amplitude, frequency and timing remain unknown. The aim of this study was to develop an active fixation system capable of installing a well-controlled mechanical environment in the fracture gap with continuous monitoring of the bone healing progression.

The experimental model was adapted from Tufekci et al. 2018 and required creation of a critical size defect and an osteotomy in a sheep tibia. They were separated by a mobile bone fragment. The distal and proximal parts of the tibia were fixed with an external fixator, whereas the mobile fragment was connected to the proximal part with an active fixator equipped with a linear actuator to move it axially for mechanical stimulation of the tissue in the fracture gap. This configuration installed well-controlled mechanical conditions in the osteotomy, dependent only on the motion of the active fixator and shielded from the influence of the sheep's functional weightbearing. A load sensor was integrated to measure the force acting in the fracture gap during mechanical stimulation. The motion of the bone fragment was controlled by means of a custom-made controller allowing to program stimulation protocols of various profiles, amplitudes and frequencies of loading events. Following in vitro testing, the system was tested in two Swiss White Alpine Sheep. It was configured to simulate immediate weightbearing for one of the animals and delayed weightbearing for the other. The applied loading protocol consisted of 1000 loading events evenly distributed over 12 hours resulting in in a single loading event every 44 seconds.

Bench testing confirmed the ability of the system to operate effectively with frequencies up to 1Hz over a range of stimulation amplitudes from 0.1 to 1.5 mm. Continuous measurements of in vivo callus stiffness revealed progressive fracture consolidation in the course of each experiment. A delayed onset of fracture healing was observed in the sheep with simulated delayed weightbearing.

The conducted preclinical experiments demonstrated its robustness and reliability. The system can be applied for further preclinical research and comprehensive in-depth investigation of fracture healing.


Orthopaedic Proceedings
Vol. 98-B, Issue SUPP_23 | Pages 31 - 31
1 Dec 2016
Metsemakers W Schmid T Zeiter S Ernst M Keller I Cosmelli N Arens D Moriarty F Richards G
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Aim

The aim of this study was to define the role of implant material and surface topography on infection susceptibility in a preclinical in vivo model incorporating appropriate fracture biomechanics and bone healing.

Method

The implants included in this experimental study were composed of: standard Electro polished Stainless Steel (EPSS), standard titanium (Ti-S), roughened stainless steel (RSS) and surface polished titanium (Ti-P). In an in vivo study, a rabbit humeral fracture model was used. Each rabbit received one of three Staphylococcus aureus inocula, aimed at determining the infection rate at a low, medium and high dose of bacteria. Outcome measures were quantification of bacteria on the implant and in the surrounding tissues, and determination of the infectious dose 50 (ID50).


Orthopaedic Proceedings
Vol. 92-B, Issue SUPP_I | Pages 35 - 35
1 Mar 2010
Anderson SL Taillon MR Ernst M
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Purpose: 2 orthopaedic surgeons identified 18 patients who developed glenohumeral chondrolysis following arthroscopic shoulder surgery. The index surgery for all 18 patients occurred over an 18 month period. We sought to find any common factors among the 18 cases.

Method: A retrospective chart review of all 18 patients was performed. We gathered information on patient demographics, type of surgical procedure, nature of shoulder instability, post-operative complications such as infection, the use of radiofrequency energy, the type/number of suture anchors, the use of an IAPPC and the type of local anaesthetic used. We compared pre-operative radiographs and MRI scans to the intra-operative findings from the operative report to confirm that no chondrolysis was present pre-operatively. We examined post-operative radiographs and MRI scans to document the extent of chondrolysis

Results: Of the 18 patients who developed chondrolysis, we had 15 males and 3 females with an average age of 23 years (range 16–39). 17 patients had shoulder instability due to a definitive traumatic event while 1 patient had an atraumatic etiology. No radiofrequency energy was used in any of the cases. No post-operative infections were diagnosed and many had work-ups for infection which included ESR, CRP, bone & gallium/WBC scans. All patients had labral stabilization procedures, 15 anterior (Bankart), 1 posterior, and 2 combinations. All patients received suture anchors, 13 patients had 2 anchors and 5 had 3 anchors. 2 different manufacturer’s suture anchors were used, 10 patients received Smith & Nephew anchors while 8 patients received Linvatec anchors. 10 patients received bioabsorbable anchors and 8 patients received metal anchors. All patients received an IAPPC loaded with 0.5% bupivacaine with epinephrine for post-operative pain control. 15 of the IAPPC’s were considered large with an infusion rate of 5 mL/hr and a fill volume of 275 mL’s. 3 IAPPC’s were considered small with an infusion rate of 2 mL/hr and a fill volume of 100 mL’s.

Conclusion: We suspect a continuous intra-articular infusion of bupivacaine with epinephrine may have contributed to the development of chondrolysis. We caution against the use of IAPPC’s until their safety has been proven.