Your search keyword '"Guy, Pierre"' showing total 21 results

1. Effect of humeral rotation on the reliability of radiographic measurements for proximal humerus fractures

Author

Sepehri, Aresh, Stockton, David J., Roffey, Darren M., Lefaivre, Kelly A., Potter, Jeffrey M., and Guy, Pierre

Published

2024

2. Relationships between individual behavioural traits and post-weaning growth in segregated early-weaned piglets

Author

Giroux, Sylvie, Martineau, Guy-Pierre, and Robert, Suzanne

Published

2000

3. Guide wire insertion for percutaneous LC2 screws in acetabular and pelvic ring fixation using a transpedicular working cannula.

Author

Scherer, Julian, Guy, Pierre, Lefaivre, Kelly A., Pape, Hans-Christoph, Werner, Clément M.L., and Osterhoff, Georg

Subjects

*ACETABULUM (Anatomy), *FLUOROSCOPY, *FRACTURE fixation, *BONE injuries, *ILIUM fractures, *WOUNDS & injuries, *THERAPEUTICS

Abstract

Closed reduction and percutaneous screw fixation (CRIF) of iliac crescent fractures and fractures of the anterior column of the acetabulum has become an established method in the treatment of these injuries. After reduction, safe insertion of a guide wire is a key step during this procedure. We present a technique that can facilitate introducing the guide wire under fluoroscopic guidance and allow for decreased radiation exposure. [ABSTRACT FROM AUTHOR]

Published

2017

4. Sub-lamellar microcracking and roles of canaliculi in human cortical bone.

Author

Ebacher, Vincent, Guy, Pierre, Oxland, Thomas R., and Wang, Rizhi

Subjects

COMPACT bone, BIOMATERIALS, BONE fractures, CONFOCAL microscopy, POROSITY, DEFORMATIONS (Mechanics)

Abstract

Abstract: Bone is a tough biological material. It is generally accepted that bone’s toughness arises from its unique hierarchical structure, which in turn facilitates distributed microcracking prior to fracture. Yet, there has been limited progress on the detailed roles of the structural elements in the microcracking process. The present study examines the structure–microcracking relations at the lamellar and sub-lamellar levels of human cortical bone subjected to compressive loading. Laser scanning confocal microscopy revealed a clear influence of the local structure and porosity of the Haversian systems’ lamellae on microcrack development. In particular, crack initiation and growth under transverse compression were associated with stress concentration at canaliculi. Later stages of microcracking showed extensive sub-lamellar cracks forming cross-hatched patterns and regularly spaced 0.5–1.7μm apart. The density, size and regularity of the crack patterns suggest enhanced inelastic deformation capacity through cracking control at the level of mineralized collagen fibril bundles. The present study thus improves the current understanding of the nature of inelastic deformation and microcracking in bone and further suggests that bone’s resistance to fracture is achieved through microcrack control at multiple length scales. [Copyright &y& Elsevier]

Published

2012

5. A multicenter, prospective, randomized, controlled trial of open reduction—internal fixation versus total elbow arthroplasty for displaced intra-articular distal humeral fractures in elderly patients.

Author

McKee, Michael D., Veillette, Christian J.H., Hall, Jeremy A., Schemitsch, Emil H., Wild, Lisa M., McCormack, Robert, Perey, Bertrand, Goetz, Thomas, Zomar, Mauri, Moon, Karyn, Mandel, Scott, Petit, Shirlet, Guy, Pierre, and Leung, Irene

Subjects

BONE surgery, INTERNAL fixation in fractures, TOTAL elbow replacement, HUMERUS

Abstract

Summary: We conducted a prospective, randomized, controlled trial to compare functional outcomes, complications, and reoperation rates in elderly patients with displaced intra-articular, distal humeral fractures treated with open reduction–internal fixation (ORIF) or primary semiconstrained total elbow arthroplasty (TEA). Forty-two patients were randomized by sealed envelope. Inclusion criteria were age greater than 65 years; displaced, comminuted, intra-articular fractures of the distal humerus (Orthopaedic Trauma Association type 13C); and closed or Gustilo grade I open fractures treated within 12 hours of injury. Both ORIF and TEA were performed following a standardized protocol. The Mayo Elbow Performance Score (MEPS) and Disabilities of the Arm, Shoulder and Hand (DASH) score were determined at 6 weeks, 3 months, 6 months, 12 months, and 2 years. Complication type, duration, management, and treatment requiring reoperation were recorded. An intention-to-treat analysis and an on-treatment analysis were conducted to address patients randomized to ORIF but converted to TEA intraoperatively. Twenty-one patients were randomized to each treatment group. Two died before follow-up and were excluded from the study. Five patients randomized to ORIF were converted to TEA intraoperatively because of extensive comminution and inability to obtain fixation stable enough to allow early range of motion. This resulted in 15 patients (3 men and 12 women) with a mean age of 77 years in the ORIF group and 25 patients (2 men and 23 women) with a mean age of 78 years in the TEA group. Baseline demographics for mechanism, classification, comorbidities, fracture type, activity level, and ipsilateral injuries were similar between the 2 groups. Operative time averaged 32 minutes less in the TEA group (P = .001). Patients who underwent TEA had significantly better MEPSs at 3 months (83 vs 65, P = .01), 6 months (86 vs 68, P = .003), 12 months (88 vs 72, P = .007), and 2 years (86 vs 73, P = .015) compared with the ORIF group. Patients who underwent TEA had significantly better DASH scores at 6 weeks (43 vs 77, P = .02) and 6 months (31 vs 50, P = .01) but not at 12 months (32 vs 47, P = .1) or 2 years (34 vs 38, P = .6). The mean flexion-extension arc was 107° (range, 42°-145°) in the TEA group and 95° (range, 30°-140°) in the ORIF group (P = .19). Reoperation rates for TEA (3/25 [12%]) and ORIF (4/15 [27%]) were not statistically different (P = .2). TEA for the treatment of comminuted intra-articular distal humeral fractures resulted in more predictable and improved 2-year functional outcomes compared with ORIF, based on the MEPS. DASH scores were better in the TEA group in the short term but were not statistically different at 2 years'' follow-up. TEA may result in decreased reoperation rates, considering that 25% of fractures randomized to ORIF were not amenable to internal fixation. TEA is a preferred alternative for ORIF in elderly patients with complex distal humeral fractures that are not amenable to stable fixation. Elderly patients have an increased baseline DASH score and appear to accommodate to objective limitations in function with time. [Copyright &y& Elsevier]

Published

2009

6. Prophylactic augmentation implants in the proximal femur for hip fracture prevention: An in silico investigation of simulated sideways fall impacts.

Author

Fung, Anita, Fleps, Ingmar, Cripton, Peter A., Guy, Pierre, Ferguson, Stephen J., and Helgason, Benedikt

Subjects

HIP fractures, FEMUR neck

Published

2022

7. Ultrasound Bone Segmentation: A Scoping Review of Techniques and Validation Practices.

Author

Pandey, Prashant U., Quader, Niamul, Guy, Pierre, Garbi, Rafeef, and Hodgson, Antony J.

Subjects

*IMAGE analysis, *COMPUTER-assisted surgery

Abstract

Ultrasound bone segmentation is an important yet challenging task for many clinical applications. Several works have emerged attempting to improve and automate bone segmentation, which has led to a variety of computational techniques, validation practices and applied clinical scenarios. We characterize this exciting and growing body of research by reviewing published ultrasound bone segmentation techniques. We review 56 articles in detail and categorize and discuss the image analysis techniques that have been used for bone segmentation. We highlight the general trends of this field in terms of clinical motivation, image analysis techniques, ultrasound modalities and the types of validation practices used to quantify segmentation performance. Finally, we present an outlook on promising areas of research based on the unaddressed needs for solving ultrasound bone segmentation. [ABSTRACT FROM AUTHOR]

Published

2020

8. Subject-specific ex vivo simulations for hip fracture risk assessment in sideways falls.

Author

Fleps, Ingmar, Fung, Anita, Guy, Pierre, Ferguson, Stephen J., Helgason, Benedikt, and Cripton, Peter A.

Subjects

*PERSPECTIVE (Art), *PELVIC fractures, *PELVIS, *RISK assessment, *DEGREES of freedom

Abstract

The risk of hip fracture of a patient due to a fall can be described from a mechanical perspective as the capacity of the femur to withstand the force that it experiences in the event of a fall. So far, impact forces acting on the lateral aspect of the pelvic region and femur strength have been investigated separately. This study used inertia-driven cadaveric impact experiments that mimic falls to the side from standing in order to evaluate the subject-specific force applied to the hip during impact and the fracture outcome in the same experimental model. Eleven fresh-frozen pelvis-femur constructs (6 female, 5 male, age = 77 years (SD = 13 years), BMI = 22.8 kg/m2 (SD = 7.8 kg/m2), total hip aBMD = 0.734 g/cm2 (SD = 0.149 g/cm2)), were embedded into soft tissue surrogate material that matched subject-specific mass and body shape. The specimens were attached to metallic lower-limb constructions with subject-specific masses and subjected to an inverted pendulum motion. Impact forces were recorded with a 6-axis force plate at 10,000 Hz and three dimensional deflections in the pelvic region were tracked with two high-speed cameras at 5000 Hz. Of the 11 specimens, 5 femur fractures and 3 pelvis fractures were observed. Three specimens did not fracture. aBMD alone did not reliably separate femur fractures from non-fractures. However, a mechanical risk ratio, which was calculated as the impact force divided by aBMD, classified specimens reliably into femur fractures and non-fractures. Single degree of freedom models, based on specimen kinetics, were able to predict subject-specific peak impact forces (RMSE = 2.55% for non-fractures). This study provides direct evidence relating subject-specific impact forces and subject-specific strength estimates and improves the assessment of the mechanical risk of hip fracture for a specific femur/pelvis combination in a sideways fall. • Eleven subject-specific post mortem human sideways fall simulations using full femur-pelvis constructs embedded in surrogate soft tissue. • Impact conditions representative of a fall from standing with a greater trochanter impact velocity of 3.1 m/s. • Clinical relevant impact outcomes: five femur fractures, three pelvis fractures, and three non-injurious impacts. • Femoral aBMD alone was not able to discriminate between falls leading to femoral fractures and non-injurious falls. • The Mechanical Risk Ratio (MRR) allowed for discrimination between falls leading to femoral fractures and non-injurious falls. [ABSTRACT FROM AUTHOR]

Published

2019

9. Body condition evaluation in sows

Author

Charette, Robert, Bigras-Poulin, Michel, and Martineau, Guy-Pierre

Published

1996

10. Serological follow-up in breeding herds infected with Actinobacillus pleuropneumoniae Serotype 1 using the tube agglutination test with 2-mercaptoethanol

Author

Vaillancourt, Jean-Pierre, Martineau, Guy-Pierre, Lariviere, Serge, Higgins, Robert, and Mittal, Khyali R.

Published

1988

11. Two-dimensional model for thermal and solutal convection in multizone physical vapor transport

Author

Extrémet, Guy Pierre, Roux, Bernard, Bontoux, Patrick, and Elie, Frédéric

Published

1987

12. Fast and Accurate Data Extraction for Near Real-Time Registration of 3-D Ultrasound and Computed Tomography in Orthopedic Surgery.

Author

Brounstein, Anna, Hacihaliloglu, Ilker, Guy, Pierre, Hodgson, Antony, and Abugharbieh, Rafeef

Subjects

*ORTHOPEDIC surgery, *ULTRASONIC imaging, *COMPUTED tomography, *IMAGE registration, *DATA extraction

Abstract

Automatic, accurate and real-time registration is an important step in providing effective guidance and successful anatomic restoration in ultrasound (US)-based computer assisted orthopedic surgery. We propose a method in which local phase-based bone surfaces, extracted from intra-operative US data, are registered to pre-operatively segmented computed tomography data. Extracted bone surfaces are downsampled and reinforced with high curvature features. A novel hierarchical simplification algorithm is used to further optimize the point clouds. The final point clouds are represented as Gaussian mixture models and iteratively matched by minimizing the dissimilarity between them using an L2 metric. For 44 clinical data sets from 25 pelvic fracture patients and 49 phantom data sets, we report mean surface registration accuracies of 0.31 and 0.77 mm, respectively, with an average registration time of 1.41 s. Our results suggest the viability and potential of the chosen method for real-time intra-operative registration in orthopedic surgery. [ABSTRACT FROM AUTHOR]

Published

2015

13. Responsiveness of the PROMIS physical function measure in orthopaedic trauma patients.

Author

Sepehri, Aresh, Sleat, Graham K.J., Roffey, Darren M., Broekhuyse, Henry M., O'Brien, Peter J., Guy, Pierre, and Lefaivre, Kelly A.

Subjects

*ARM injuries, *HEALTH surveys, *ORTHOPEDICS, *LONGITUDINAL method

Abstract

Objectives: To compare the responsiveness of the Patient-Reported Outcomes Measurement Information System Physical Function (PROMIS-PF) to the 36-Item Short Form Survey Physical Component Score (SF36-PCS) in orthopaedic trauma patients from pre-injury to one year recovery.Design and Setting: Prospective cohort study at a Level 1 trauma centre.Participants: Patients over the age of 18 with orthopaedic trauma injuries to the pelvis, lower extremity or upper extremity between 2017 and 2018.Main Outcomes Measurements: The PROMIS-PF and SF36-PCS assessments were conducted at baseline, 3 months, 6 months and 12 months. Responsiveness of each measure was assessed between time points by calculating the standardized response mean (SRM), the proportions of patients exceeding minimal clinically important difference (MCID), and the floor and ceiling effects.Results: Sixty-eight patients with completed assessments at every timepoint were included: mean age 44.7 years, 39 were male and mean Injury Severity Score (ISS) was 7.4 (range: 4-16). Mean time of completion for the SF-36 at all the time points was 5.6 min vs 1.7 min for the PROMIS-PF (p<0.01). The SRM was comparable between measures at all the time points. Although a greater proportion of patients achieved MCID for SF36-PCS between all the time points, this only approached statistical significance between the 6- and 12-month assessments (47.1% vs 33.8%; p = 0.15). There was a significant ceiling effect demonstrated with the PROMIS-PF at baseline and 12-month assessments, with 34 (50.0%) patients and 7 (10.3%) patients achieving the maximum scores at each time point, respectively.Discussion and Conclusions: PROMIS-PF has a more favourable responder burden based on lower time to completion and comparable responsiveness to the SF-36 PCS. However, there are limitations in responsiveness with the PROMIS-PF in patients who are higher functioning as demonstrated by the ceiling effects in patients at baseline pre-injury and at 12 months post-injury timepoints. [ABSTRACT FROM AUTHOR]

Published

2022

14. Proximal femur bone strength estimated by a computationally fast finite element analysis in a sideways fall configuration.

Author

Nishiyama, Kyle K., Gilchrist, Seth, Guy, Pierre, Cripton, Peter, and Boyd, Steven K.

Subjects

*BONE mechanics, *MECHANICAL loads, *STIFFNESS (Mechanics), *SENSITIVITY analysis, *BOUNDARY value problems, *FEMUR, *SIMULATION methods & models, *FINITE element method

Abstract

Finite element (FE) analysis based on quantitative computed tomography (QCT) images is an emerging tool to estimate bone strength in a specific patient or specimen; however, it is limited by the computational power required and the associated time required to generate and solve the models. Thus, our objective was to develop a fast, validated method to estimate whole bone structural stiffness and failure load in addition to a sensitivity analysis of varying boundary conditions. We performed QCT scans on twenty fresh-frozen proximal femurs (age: 77±13 years) and mechanically tested the femurs in a configuration that simulated a sideways fall on the hip. We used custom software to generate the FE models with boundary conditions corresponding to the mechanical tests and solved the linear models to estimate bone structural stiffness and estimated failure load. For the sensitivity analysis, we varied the internal rotation angle of the femoral neck from -30° to 45° at 15° intervals and estimated structural stiffness at each angle. We found both the FE estimates of structural stiffness (R²=0.89, p<0.01) and failure load (R²=0.81, p<0.01) to be in high agreement with the values found by mechanical testing. An important advantage of these methods was that the models of approximately 500,000 elements took less than 11 min to solve using a standard desktop workstation. In this study we developed and validated a method to quickly and accurately estimate proximal femur structural stiffness and failure load using QCT-driven FE methods. [ABSTRACT FROM AUTHOR]

Published

2013

15. Clinical hip fracture is accompanied by compression induced failure in the superior cortex of the femoral neck.

Author

Tang, Tengteng, Wang, Rizhi, Cripton, Peter A., Guy, Pierre, and McKay, Heather A.

Subjects

*HIP fractures, *CONFOCAL microscopy, *FEMUR neck, *MICROCRACKS, *STRAINS & stresses (Mechanics)

Abstract

Hip fractures pose a major health problem throughout the world due to their devastating impact. Current theories for why these injuries are so prevalent in the elderly point to an increased propensity to fall and decreases in bone mass with ageing. However, the fracture mechanisms, particularly the stress and strain conditions leading to bone failure at the hip remain unclear. Here, we directly examined the cortical bone from clinical intra-capsular hip fractures at a microscopic level, and found strong evidence of compression induced failure in the superior cortex. A total of 143 sections obtained from 24 femoral neck samples that were retrieved from 24 fracturing patients at surgery were examined using laser scanning confocal microscopy (LSCM) after fluorescein staining. The stained microcracks showed significantly higher density in the superior cortex than in the inferior cortex, indicating a greater magnitude of strain in the superior femoral neck during the failure-associated deformation and fracture process. The predominant stress state for each section was reconstructed based on the unique correlation between the microcrack pattern and the stress state. Specifically, we found clear evidence of longitudinal compression and buckling as the primary failure mechanisms in the superior cortex. These findings demonstrate the importance of microcrack analysis in studying clinical hip fractures, and point to the central role of the superior cortex failure as an important aspect of the failure initiation in clinical intra-capsular hip fractures. [ABSTRACT FROM AUTHOR]

Published

2018

16. Risk of second hip fracture persists for years after initial trauma.

Author

Sobolev, Boris, Sheehan, Katie Jane, Kuramoto, Lisa, and Guy, Pierre

Subjects

*BONE fractures, *FRACTURE mechanics, *PELVIC bones, *THERAPEUTICS, *DEATH rate

Abstract

Background Secondary prevention often targets women who suffer from higher rates of second hip fracture than men, especially in the early years after first fracture. Yet, the occurrence of second hip fracture by certain times also depends on the death rate, which is higher in men than women. We compared the risk of sustaining second hip fracture by a certain time between women and men remaining alive at that time. Methods We retrieved 38,383 hospitalization records of patients aged 60 years or older, who were discharged alive after admission for hip fracture surgery between 1990 and 2005 in British Columbia, Canada. The outcome variable was the time to a subsequent hip fracture. Results During ten years of follow-up, 2,902 (8%) patients sustained a second hip fracture, and 21,428 (56%) died before sustaining a second hip fracture. The risk of second hip fracture in the surviving post-fracture patients was higher in women than in men: 2% vs 2%, 5% vs 4%, 9% vs 7%, 15% vs 13%, and 35% vs 30% at 1, 2, 3, 5, and 10 years after initial trauma, respectively, crude OR = 1.25 (95% CI: 1.13–1.39). However, the risk did not differ between women and men after adjustment, OR = 1.09 (95% CI: 0.98–1.21). Conclusions The risk of second hip fracture persists for at least ten years among hip fracture survivors, and therefore secondary prevention should continue beyond an early post-fracture period. Women and men have similar risks of second hip fracture and both should be considered for secondary prevention. [ABSTRACT FROM AUTHOR]

Published

2015

17. Shear deformation and fracture of human cortical bone.

Author

Tang, Tengteng, Ebacher, Vincent, Cripton, Peter, Guy, Pierre, McKay, Heather, and Wang, Rizhi

Subjects

*BONE fractures, *COMPACT bone, *BIOMECHANICS, *DEFORMATIONS (Mechanics), *SHEAR (Mechanics), *HUMAN behavior, *COMPRESSION fractures, *DIGITAL image correlation

Abstract

Bone can be viewed as a nano-fibrous composite with complex hierarchical structures. Its deformation and fracture behaviors depend on both the local structure and the type of stress applied. In contrast to the extensive studies on bone fracture under compression and tension, there is a lack of knowledge on the fracture process under shear, a stress state often exists in hip fracture. This study investigated the mechanical behavior of human cortical bone under shear, with the focus on the relation between the fracture pattern and the microstructure. Iosipescu shear tests were performed on notched rectangular bar specimens made from human cortical bone. They were prepared at different angles (i.e. 0°, 30°, 60° and 90°) with respect to the long axis of the femoral shaft. The results showed that human cortical bone behaved as an anisotropic material under shear with the highest shear strength (~ 50 MPa) obtained when shearing perpendicular to the Haversian systems or secondary osteons. Digital image correlation (DIC) analysis found that shear strain concentration bands had a close association with long bone axis with an average deviation of 11.8° to 18.5°. The fracture pattern was also greatly affected by the structure with the crack path generally following the direction of the long axes of osteons. More importantly, we observed unique peripheral arc-shaped microcracks within osteons, using laser scanning confocal microscopy (LSCM). They were generally long cracks that developed within a lamella without crossing the boundaries. This microcracking pattern clearly differed from that created under either compressive or tensile stress: these arc-shaped microcracks tended to be located away from the Haversian canals in early-stage damaged osteons, with ~ 70% developing in the outer third osteonal wall. Further study by second harmonic generation (SHG) and two-photon excitation fluorescence (TPEF) microscopy revealed a strong influence of the organization of collagen fibrils on shear microcracking. This study concluded that shear-induced microcracking of human cortical bone follows a unique pattern that is governed by the lamellar structure of the osteons. [ABSTRACT FROM AUTHOR]

Published

2015

18. Variations in the vulvar temperature of sows during proestrus and estrus as determined by infrared thermography and its relation to ovulation.

Author

Simões, Vasco G., Lyazrhi, Faouzi, Picard-Hagen, Nicole, Gayrard, Véronique, Martineau, Guy-Pierre, and Waret-Szkuta, Agnès

Subjects

*BIOLOGICAL variation, *SOWS, *ESTRUS, *MEDICAL thermography, *OVULATION, *BODY temperature, *REPRODUCTION, *CATTLE

Abstract

The prediction of ovulation time is one of the most important and yet difficult processes in pig production, and it has a considerable impact on the fertility of the herd and litter size. The objective of this study was to assess the vulvar skin temperature of sows during proestrus and estrus using infrared thermography and to establish a possible relationship between the variations in vulvar temperature and ovulation. The experimental group comprised 36 crossbred Large White × Landrace females, of which 6 were gilts and 30 were multiparous sows. Estrus was detected twice daily and the temperature was obtained every 6 hours from the vulvar area and from two control points in the gluteal area (Gluteal skin temperature [GST]). A third variable, vulvar–gluteal temperature (VGT) was obtained from the difference between the vulvar skin temperature and the GST values. The animals were divided into two subgroups: group A consisting of 11 animals with estrus detected at 6:00 AM, Day 4 postweaning, and group B comprising seven animals with estrus detected at 6:00 AM, Day 5 post-weaning. Both groups showed a similar trend in the VGT. The VGT increased during the proestrus, reaching a peak 24 hours before estrus in group A and 48 hours before estrus in group B. The VGT then decreased markedly reaching the lowest value in groups A and B, respectively, 12 and 6 hours after estrus. Although the time of ovulation was only estimated on the basis of a literature review, the matching between the temporal variations of the VGT values and the predicted time of the peak of estradiol secretion that ultimately leads to the ovulation processes suggests that the VGT values represent a potential predictive marker of the ovulatory events. [ABSTRACT FROM AUTHOR]

Published

2014

19. Automatic Bone Localization and Fracture Detection from Volumetric Ultrasound Images Using 3-D Local Phase Features

Author

Hacihaliloglu, Ilker, Abugharbieh, Rafeef, Hodgson, Antony J., Rohling, Robert N., and Guy, Pierre

Subjects

*DIAGNOSIS of bone fractures, *VOLUMETRIC analysis, *ULTRASONIC imaging, *THREE-manifolds (Topology), *BONE physiology, *PELVIC fractures

Abstract

Abstract: This article presents a novel method for bone segmentation from three-dimensional (3-D) ultrasound images that derives intensity-invariant 3-D local image phase measures that are then employed for extracting ridge-like features similar to those that occur at soft tissue/bone interfaces. The main contributions in this article include: (1) the extension of our previously proposed phase-symmetry-based bone surface extraction from two-dimensional (2-D) to 3-D images using 3-D Log-Gabor filters; (2) the design of a new framework for accuracy evaluation based on using computed tomography as a gold standard that allows the assessment of surface localization accuracy across the entire 3-D surface; (3) the quantitative validation of accuracy of our 3-D phase-processing approach on both intact and fractured bone surfaces using phantoms and ex vivo 3-D ultrasound scans; and (4) the qualitative validation obtained by scanning emergency room patients with distal radius and pelvis fractures. We show a 41% improvement in surface localization error over the previous 2-D phase symmetry method. The results demonstrate clearly visible segmentations of bone surfaces with a localization accuracy of <0.6 mm and mean errors in estimating fracture displacements below 0.6 mm. The results show that the proposed method is successful even for situations when the bone surface response is weak due to shadowing from muscle and fascia interfaces above the bone, which is a situation where the 2-D method fails. [Copyright &y& Elsevier]

Published

2012

20. During sideways falls proximal femur fractures initiate in the superolateral cortex: Evidence from high-speed video of simulated fractures

Author

de Bakker, Peter M., Manske, Sarah L., Ebacher, Vincent, Oxland, Thomas R., Cripton, Peter A., and Guy, Pierre

Subjects

*FEMUR injuries, *BONE fractures, *FEMUR neck, *BIOMECHANICS research, *HIP joint, *BONE mechanics, *SIMULATION methods & models, *BIOLOGICAL mathematical modeling

Abstract

Abstract: Results of recent imaging studies and theoretical models suggest that the superior femoral neck is a location of local weakness due to an age-related thinning of the cortex, and thus the site of hip fracture initiation. The purpose of this study was to experimentally determine the spatial and temporal characteristics of the macroscopic failure process during a simulated hip fracture that would occur as a result of a sideways fall. Twelve fresh frozen human cadaveric femora were used in this study. The femora were fractured in an apparatus designed to simulate a fall on the greater trochanter. Image sequences of the surface events related to the fractures were captured using two high-speed video cameras at 9111Hz. The videos were analyzed with respect to time and load to determine the location and sequence of these events occurring in the proximal femur. The mean failure load was 4032N (SD 370N). The first surface events were identified in the superior femoral neck in eleven of the twelve specimens. Nine of these specimens fractured in a clear two-step process that initiated with a failure in the superior femoral neck, followed by a failure in the inferior femoral neck. This cadaveric model of hip fracture empirically confirms hypotheses that suggested that hip fractures initiate with a failure in the superior femoral neck where stresses are primarily compressive during a sideways fall impact, followed by a failure in the inferior neck where stresses are primarily tensile. Our results confirm the superolateral neck of the femur as an important region of interest for future hip fracture screening, prevention and treatment research. [Copyright &y& Elsevier]

Published

2009

21. Strain redistribution and cracking behavior of human bone during bending

Author

Ebacher, Vincent, Tang, Cecelia, McKay, Heather, Oxland, Thomas R., Guy, Pierre, and Wang, Rizhi

Subjects

*BONE injuries, *BONE fractures, *DEFORMATIONS (Mechanics), *FRACTURE mechanics, *TIBIA

Abstract

Abstract: Long bones often fail due to bending loads. Understanding the fracture process during bending is of great importance to the prevention and treatment of bone fractures. In this study, we investigated the origin of long bone’s bending strength through the study of the dynamic strain redistribution happening during the post-yield stage of deformation and its relation to microdamage at the microstructural level. This was accomplished by comparing the behaviors of human long bones with standard cortical bone specimens in terms of strain redistribution, Poisson’s ratios, microdamage morphologies, and macro-scale fracture patterns. It was found that human tibia failure in bending was very similar to that of standard beam cortical bone specimens with respect to the four previous aspects. Also, the examination of bone’s Poisson’s ratio indicated very different inelastic deformation mechanisms under tension and compression: bone volume expanded in tension but was nearly conserved in compression. Finally, as a result of strain redistribution, bone’s bending strength mainly depended on its compressive strength, which was significantly influenced by the osteonal “porous” microstructure of human bone as compared to its tensile behavior. Thus, we concluded that bone microstructure at the Haversian system level plays an important role in bone deformation and fracture. [Copyright &y& Elsevier]

Published

2007