镶嵌式外固定架治疗长骨骨不连17例体会

目的:探讨长骨骨不连的一种治疗方法。方法:2007年1月至2009年8月,采用镶嵌式外固定架治疗17例长骨骨不连。本组17例,男11例,女6例,年龄16-64岁,平均31岁。2例为血源性骨髓炎病理性骨折后,股骨、胫骨各1例;6例为创伤性骨髓炎后骨折不愈,肱骨1例,股骨1例,胫骨4例;9例为手术后无感染性骨不连,肱骨2例,股骨2例,胫骨5例;7例有不同程度畸形,6例有1.5-8cm骨短缩,其中2例同时行骨痂延长术。结果:全部病人均获随访,随访时间9-20个月,以1975年天津全国骨科会议制定的骨折愈合标准为依据,本组17例病人均获得临床愈合,骨不连处平均愈合时间为4～9月(平均6.2月),1例延长8cm,另1例延长6cm。结论:利用镶嵌式外固定架治疗长骨骨不连一种简单有效的方法。     

镶嵌式外固定架治疗长骨骨不连17例体会

目的：探讨长骨骨不连的一种治疗方法。方法：2007年1月至2009年8月,采用镶嵌式外固定架治疗17例长骨骨不连。本组17例,男11例,女6例,年龄16-64岁,平均31岁。2例为血源性骨髓炎病理性骨折后,股骨、胫骨各1例;6例为创伤性骨髓炎后骨折不愈,肱骨1例,股骨1例,胫骨4例;9例为手术后无感染性骨不连,肱骨2例,股骨2例,胫骨5例;7例有不同程度畸形,6例有1.5-8cm骨短缩,其中2例同时行骨痂延长术。结果：全部病人均获随访,随访时间9-20个月,以1975年天津全国骨科会议制定的骨折愈合标准为依据,本组17例病人均获得临床愈合,骨不连处平均愈合时间为4～9月（平均6.2月）,1例延长8cm,另1例延长6cm。结论：利用镶嵌式外固定架治疗长骨骨不连一种简单有效的方法。     

Kinematic simulation of fracture reduction and bone deformity correction under unilateral external fixation

Combined kinematic analysis and graphic models of two unilateral external fixators are presented to simulate and visualize the correction of bone fracture deformities through systematic adjustments of the fixator joints. The models were developed as rigid linkage systems, and the analysis utilized the 4x4 transformation matrices and the kinematic chain theory to obtain the necessary rotations and translations at each joint of the fixator to correct bone deformities at the fracture site. Three-dimensional malalignments with fracture gaps were simulated to correct the deformities. Due to the redundant pair variables in the fixator joints and other problems in obtaining unique solutions, an optimization technique was used to solve the governing linkage loop equations. For each adjustment solution, the bone correction paths were infinite but a unique and optimal reduction path was obtained by applying corrections to all joints simultaneously and in small increments. When the deformity exceeded a certain range, no admissible solution could be obtained, partially due to the limitation of the unilateral fixator configuration and partially due to the restricted joint rotation and translation in the fixator design. The present models and analysis technique can be used to investigate a fixator's adjustability to correct a 3-D bone deformity at a fracture or lengthening site facilitating patient care planning and medical personnel training.     

Kinematic adjustability of unilateral external fixators for fracture reduction and alignment of axial dynamization

Bone fracture reduction and bone axial dynamization are important operations which effectiveness can be further enhanced by the use of a unilateral external fixator. By design, axial dynamization can be performed through reciprocating one of its translational joints. However, non-axial dynamization may occur after correcting residual fracture deformity. To explore and to maximize its full potential, the joint adjustment constraint equations for fracture reduction and alignment of axial dynamization under unilateral external fixation are derived. Their physical implications and criteria on the kinematic structure of a fixator are then established. In order to correctly make the alignment of axial dynamization with the proper fracture reduction, this study shows that the linkage of a bone–fixator system should have a minimum of eight degrees-of-freedom (DOFs) with at least two nonparallel rotational DOFs adjacent to both ends of the designated single translational DOF for axial dynamization. Thus, the adjustment of the connection between bone pin/pin clamp of Othofix^® fixator is required, while the alignment of one of the translational joints of Dynafix^® fixator with its bone segment axis during fracture stabilization procedure is a crucial step. A conceptual fixator that requires neither an adjustment of the pin/pin clamp connection nor special pre-alignment is demonstrated. Based on the constraint equations and criteria developed throughout this study, the creation of an effective frame design of external fixation device becomes feasible.     

Design and testing of external fixator bone screws

In external fixation, bone screw loosening still presents a major clinical problem. For this study, the design factors influencing the mechanics of the bone-screw interface were analysed and various experimental screws designed with the intention of maximizing the strength and stiffness of the inserted screw. Push-in, pull-out and bending tests were then carried out on the three experimental screws, and on two commercially available screws in both a synthetic material and in cadaveric bone; photoelastic tests on different screw threadforms were also performed. The results of the push-in and pull-out tests indicate that both the screw threadform and cutting head have a significant effect on the holding strength of the screw. The photoelastic tests show that most of the applied load is distributed over the first few threads closest to the load, and that the area between the thread crests is subjected to high shear stresses.     

Predicting the external formation of a bone fracture callus: an optimisation approach

The formation of a fracture callus in vivo tends to form in a structurally efficient manner distributing tissues where mechanical stimulus persists. Therefore, it is proposed that the formation of a fracture callus can be modelled in silico by way of an optimisation algorithm. This was tested by generating a finite element model of a transversal bone fracture embedded in a large tissue domain which was subjected to axial, bending and torsional loads. It was found that the relative fragment motion induced a compressive strain field in the early callus tissue which could be utilised to simulate the formation of external callus structures through an iterative optimisation process of tissue maintenance and removal. The phenomenological results showed a high level of congruence with in vivo healing patterns found in the literature. Consequently, the proposed strategy shows potential as a means of predicting spatial bone healing phenomena for pre-clinical testing.     

Predicting the external formation of a bone fracture callus: an optimisation approach

The formation of a fracture callus in vivo tends to form in a structurally efficient manner distributing tissues where mechanical stimulus persists. Therefore, it is proposed that the formation of a fracture callus can be modelled in silico by way of an optimisation algorithm. This was tested by generating a finite element model of a transversal bone fracture embedded in a large tissue domain which was subjected to axial, bending and torsional loads. It was found that the relative fragment motion induced a compressive strain field in the early callus tissue which could be utilised to simulate the formation of external callus structures through an iterative optimisation process of tissue maintenance and removal. The phenomenological results showed a high level of congruence with in vivo healing patterns found in the literature. Consequently, the proposed strategy shows potential as a means of predicting spatial bone healing phenomena for pre-clinical testing.     

Independent external validation of nomograms for predicting risk of low-trauma fracture and hip fracture

Background

A set of nomograms based on the Dubbo Osteoporosis Epidemiology Study predicts the five- and ten-year absolute risk of fracture using age, bone mineral density and history of falls and low-trauma fracture. We assessed the discrimination and calibration of these nomograms among participants in the Canadian Multicentre Osteoporosis Study.

Methods

We included participants aged 55–95 years for whom bone mineral density measurement data and at least one year of follow-up data were available. Self-reported incident fractures were identified by yearly postal questionnaire or interview (years 3, 5 and 10). We included low-trauma fractures before year 10, except those of the skull, face, hands, ankles and feet. We used a Cox proportional hazards model.

Results

Among 4152 women, there were 583 fractures, with a mean follow-up time of 8.6 years. Among 1606 men, there were 116 fractures, with a mean follow-up time of 8.3 years. Increasing age, lower bone mineral density, prior fracture and prior falls were associated with increased risk of fracture. For low-trauma fractures, the concordance between predicted risk and fracture events (Harrell C) was 0.69 among women and 0.70 among men. For hip fractures, the concordance was 0.80 among women and 0.85 among men. The observed fracture risk was similar to the predicted risk in all quintiles of risk except the highest quintile of women, where it was lower. The net reclassification index (19.2%, 95% confidence interval [CI] 6.3% to 32.2%), favours the Dubbo nomogram over the current Canadian guidelines for men.

Interpretation

The published nomograms provide good fracture-risk discrimination in a representative sample of the Canadian population.Current recommendations for the treatment of osteoporosis are in transition. The T-score-based definition of osteoporosis and osteopenia by the expert committee of the World Health Organization on bone mineral density has been used in many guidelines to set intervention thresholds for treatment. However, studies have consistently reported that the highest number of fractures in a given population occurs in those with osteopenic or normal bone mineral density.^1,2 In fact, the National Osteoporosis Foundation has singled out people with osteopenic bone mineral density as a population in which assessment for fracture risk is merited.³Nevertheless, appropriate prevention and treatment strategies for such people are uncertain.⁴ Recent developments include the assessment of absolute fracture risk based on bone mineral density and other risk factors. Current Canadian methodology determines categorical risk based on age, sex, T-score, fracture history and glucocorticoid use.⁵ These criteria were derived from Swedish data, but have been assessed and validated in a cohort of Manitoba women.⁶ Newer nomograms based on the Australian cohort of the Dubbo Osteoporosis Epidemiology Study⁷ are now available for the calculation of low-trauma hip fracture⁸ and any fracture.⁹ These nomograms provide continuous estimates for five- and 10-year absolute fracture risk in both men and women (available at http://fractureriskcalculator.com). The use of factors in addition to bone mineral density may provide a better assessment of fracture risk for people who are near the T-score thresholds and facilitate decisions regarding therapeutic intervention.A key step in the development of any prediction model is the assessment of its validity.¹⁰ The aim of our study was to assess the performance of the Australian-derived nomogram among community-dwelling Canadians aged 55–95 years old. The first part of this assessment was a comparison of the nomogram model using the same variables, but using data from a Canadian population — participants in the Canadian Multicentre Osteoporosis Study (www.camos.org). The second part involved computing the calibration and discrimination of the nomogram in a Canadian cohort. The final part was comparison of the new assessments with the existing Canadian risk classification system.     

Development and clinical application of an external fixator monitoring system

A monitoring system for measuring movement occurring in a dynamic external fixator used to treat fractures is described. The system measures shortening during fracture healing, micromovement at the fracture site on weight bearing and detects pin loosening. The method of calibration including cadaver experiments is presented. The clinical application is described and the reasons for measuring movement are discussed.     

Tensioning technique and fixator stability of a circular external fixator with threaded fine wires

Hybrid external fixators have become more popular over recent years, and although biomechanical tests show varying results from paper to paper, a consistent finding is shear motion occurring at the fracture/osteotomy site during loading. This can be reduced to some extent by frame configuration, and with the use of olive stop wires, but both of these have limitations. We have investigated the use of threaded fine wires in a circular hybrid fixator. A reliable tensioning method is described which minimises movement at the wire-bone interface during tensioning, and threaded wires are seen to offer a significant improvement in fracture site shear stiffness when compared to smooth fine wires.     

Failure modelling of trabecular bone using a non-linear combined damage and fracture voxel finite element approach

Trabecular bone tissue failure can be considered as consisting of two stages: damage and fracture; however, most failure analyses of 3D high-resolution trabecular bone samples are confined to damage mechanisms only, that is, without fracture. This study aims to develop a computational model of trabecular bone consisting of an explicit representation of complete failure, incorporating damage criteria, fracture criteria, cohesive forces, asymmetry and large deformation capabilities. Following parameter studies on a test specimen, and experimental testing of bone sample to complete failure, the asymmetric critical tissue damage and fracture strains of ovine vertebral trabecular bone were calibrated and validated to be compression damage ?1.16 %, tension damage 0.69 %, compression fracture ?2.91 % and tension fracture 1.98 %. Ultimate strength and post–ultimate strength softening were captured by the computational model, and the failure of individual struts in bending and shear was also predicted. This modelling approach incorporated a cohesive parameter that provided a facility to calibrate ductile–brittle behaviour of bone tissue in this non-linear geometric and non-linear constitutive property analyses tool. Finally, the full accumulation of tissue damage and tissue fracture has been monitored from range of small magnitude (normal daily loading) through to specimen yielding, ultimate strength and post–ultimate strength softening.     

Development of a new approach for screening combinatorial libraries using MALDI-TOF-MS and HPLC-ESI-MS/MS

Mass spectrometric techniques play a prominent role in the rapidly expanding field of high-throughput screening (HTS). In this paper, the authors present a novel qualitative approach for the screening of a small library of compounds using MALDI-TOF-MS and HPLC-ESI-MS/MS. Chymotrypsin (CT), a serine protease, was selected as the target protein. A well-known inhibitor of CT is chymostatin (CS), a naturally occurring peptide aldehyde, which is reported to be a mixture of 3 components-A, B, and C-differing only in one of the amino acids. The authors report that native CS mixture consists of 3 additional ring hydroxylated components and that each compound exists in 2 epimeric forms. In case of protein-binding compounds, only 1 of the epimers was found to be active. A unique feature of this study is the generation of a combinatorial library of CS derivatives applying a one-pot strategy followed by identification and structural elucidation of the library components. Analytical investigation of the library resulted in the identification of 22 compounds. After incubation with CT and centrifugal ultrafiltration, 10 compounds were detected as protein-binding ligands. Finally, the complementary potentials of MALDI-TOF-MS and HPLC-MS/MS in the screening of complex ligand mixtures have been discussed.     

Accurate,firm stabilization using external pins: a proposal for closed reduction of unfavorable nasal bone fractures and their simple classification

Nasal bone fractures are the most common among facial fractures and are the third most common fractures in the human frame. Although many forms of treatment have been introduced, controversy regarding the optimal treatment still remains. Nasal bone fractures are complex, with significantly varying types that are often undermanaged in closed reduction procedures. The authors' experiences with nasal bone fractures have shown that the baseline for surgical intervention depends on the type of fracture and the method of maintenance after reduction, both of which have considerable impact on the final result. Therefore, it is very important and challenging to determine the proper method of reduction and maintenance. The periosteal covering plays an important role in the splinting action after closed reduction, but sagging, depression, and instability remain major complications in some cases. The authors devised a new method of accurate, firm stabilization of the fractured nasal bone by using external pins in those unfavorable fractures determined radiologically to gain optimal reduction and fixation. In the present study, fractures were grouped into favorable and unfavorable fractures, the latter being those that remained unstable or impacted even after reduction and thus needed open reduction. Unfavorable fractures were divided into four subclasses according to radiologic findings: (1) type I (frontal), including chip or tip fractures, which often depress the upper lateral cartilage and tend to sag after reduction; (2) type II (lateral), or laterally depressed segmental fractures with a lateral shift of the arch in fragments or as a unit; (3) type III (mixed), or type II with septal involvement; and (4) type IV (complex), including open or multiple comminuted fractures. After an initial evaluation to determine the fracture type, closed reduction and external fixation were performed for types I, II, and III fractures and open reduction was performed for type IV fractures 5 to 7 days after the fracture. Closed reduction with the use of external pins was done in eight cases: type I (two), type II (four), and type III (two). The mean age of the patients was 27.8 years, and the average follow-up period was 11.7 months. Functional and aesthetic results were satisfactory. This new method for support and fixation is an alternative to the conventional closed reduction and a promising way to prevent secondary deformity.     

32 species validation of a new Illumina paired-end approach for the development of microsatellites

Development and optimization of novel species-specific microsatellites, or simple sequence repeats (SSRs) remains an important step for studies in ecology, evolution, and behavior. Numerous approaches exist for identifying new SSRs that vary widely in terms of both time and cost investments. A recent approach of using paired-end Illumina sequence data in conjunction with the bioinformatics pipeline, PAL_FINDER, has the potential to substantially reduce the cost and labor investment while also improving efficiency. However, it does not appear that the approach has been widely adopted, perhaps due to concerns over its broad applicability across taxa. Therefore, to validate the utility of the approach we developed SSRs for 32 species representing 30 families, 25 orders, 11 classes, and six phyla and optimized SSRs for 13 of the species. Overall the IPE method worked extremely well and we identified 1000s of SSRs for all species (mean = 128,485), with 17% of loci being potentially amplifiable loci, and 25% of these met our most stringent criteria designed to that avoid SSRs associated with repetitive elements. Approximately 61% of screened primers yielded strong amplification of a single locus.     

Modelling the effects of different fracture geometries and healing stages on ultrasound signal loss across a long bone fracture

The effect on the signal amplitude of ultrasonic waves propagating along cortical bone plates was modelled using a 2D Finite Difference code. Different healing stages, represented by modified fracture geometries were introduced to the plate model. A simple transverse and oblique fracture filled with water was introduced to simulate the inflammatory stage. Subsequently, a symmetric external callus surrounding a transverse fracture was modelled to represent an advanced stage of healing. In comparison to the baseline (intact plate) data, a large net loss in signal amplitude was produced for the simple transverse and oblique cases. Changing the geometry to an external callus with different mechanical properties caused the net loss in signal amplitude to reduce significantly. This relative change in signal amplitude as the geometry and mechanical properties of the fracture site change could potentially be used to monitor the healing process.