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BioMed Research International 2022A morphological analysis of ancient human bones is essential for understanding life history, medical history, and genetic characteristics. In addition to external...
Application of Methods for a Morphological Analysis of the Femoral Diaphysis Based on Clinical CT Images to Prehistoric Human Bone: Comparison of Modern Japanese and Jomon Populations from Hegi Cave, Oita, Japan.
A morphological analysis of ancient human bones is essential for understanding life history, medical history, and genetic characteristics. In addition to external measurements, a three-dimensional structural analysis using CT will provide more detailed information. The present study examined adult male human skeletons excavated from Hegi cave, Nakatsu city, Oita Prefecture. CT images were taken from the femurs of adult males (Initial/Early Jomon Period ( = 10) and Late Jomon Period ( = 5)). Cross-sectional images of the diaphysis from below the lesser trochanter to above the adductor tubercle were obtained using the method established by Imamura et al. (2019) and Imamura et al. (2021). Using Excel formulas and macros, the area of cortical bone, thickness, and degree of curvature were quantitatively analyzed. The results were compared with data on modern Japanese. The maximum thickness of cortical bone in the diaphysis and the degree of the anterior curvature were significantly greater in Late Jomon humans than in the other groups. In contrast to modern humans, the majority of Jomon femurs showed the S-shaped curvature with the medial side at the top position and the lateral side at the lower position. The present results demonstrate that Late Jomon humans had a wider range of activity than the other groups and also provide insights into diseases in the hip and knee joints of Jomon humans.
Topics: Adult; Bone and Bones; Diaphyses; Femur; Humans; Japan; Male; Tomography, X-Ray Computed
PubMed: 35711519
DOI: 10.1155/2022/2069063 -
Journal of Applied Physiology... May 2006
Topics: Adaptation, Physiological; Animals; Biomechanical Phenomena; Diaphyses; Epiphyses; Mice; Osteogenesis; Tibia
PubMed: 16614362
DOI: 10.1152/japplphysiol.00038.2006 -
Orthopaedic Surgery Feb 2018To study the biomechanical properties of a novel modular intercalary prosthesis for humeral diaphyseal segmental defect reconstruction, to establish valid finite element...
OBJECTIVE
To study the biomechanical properties of a novel modular intercalary prosthesis for humeral diaphyseal segmental defect reconstruction, to establish valid finite element humerus and prosthesis models, and to analyze the biomechanical differences in modular intercalary prostheses with or without plate fixation.
METHODS
Three groups were set up to compare the performance of the prosthesis: intact humerus, humerus-prosthesis and humerus-prosthesis-plate. The models of the three groups were transferred to finite element software. Boundary conditions, material properties, and mesh generation were set up for both the prosthesis and the humerus. In addition, 100 N or 2 N.m torsion was loaded to the elbow joint surface with the glenohumeral joint surface fixed. Humeral finite element models were established according to CT scans of the cadaveric bone; reverse engineering software Geomagic was used in this procedure. Components of prosthetic models were established using 3-D modeling software Solidworks. To verify the finite element models, the in vitro tests were simulated using a mechanical testing machine (Bionix; MTS Systems Corporation, USA). Starting with a 50 N preload, the specimen was subjected to 5 times tensile (300 N) and torsional (5 N.m) strength; interval time was 30 min to allow full recovery for the next specimen load. Axial tensile and torsional loads were applied to the elbow joint surface to simulate lifting heavy objects or twisting something, with the glenohumeral joint surface fixed.
RESULTS
Stress distribution on the humerus did not change its tendency notably after reconstruction by intercalary prosthesis whether with or without a plate. The special design which included a plate and prosthesis effectively diminished stress on the stem where aseptic loosening often takes place. Stress distribution major concentrate upon two stems without plate addition, maximum stress on proximal and distal stem respectively diminish 27.37% and 13.23% under tension, 10.66% and 11.16% under torsion after plate allied.
CONCLUSION
The novel intercalary prosthesis has excellent ability to reconstruct humeral diaphyseal defects. The accessory fixation system, which included a plate and prosthesis, improved the rigidity of anti-tension and anti-torsion, and diminished the risk of prosthetic loosening and dislocation. A finite element analysis is a kind of convenient and practicable method to be used as the confirmation of experimental biomechanics study.
Topics: Biomechanical Phenomena; Bone Plates; Bone-Implant Interface; Cadaver; Diaphyses; Finite Element Analysis; Humans; Humerus; Materials Testing; Prostheses and Implants; Prosthesis Design; Prosthesis Implantation; Stress, Mechanical
PubMed: 29484857
DOI: 10.1111/os.12368 -
Orthopaedics & Traumatology, Surgery &... Apr 2012Traumatic bone defects (BD) are rare in children. There are no pediatric series in the literature on this topic. The aim of this first pediatric series was to determine... (Comparative Study)
Comparative Study
UNLABELLED
Traumatic bone defects (BD) are rare in children. There are no pediatric series in the literature on this topic. The aim of this first pediatric series was to determine the epidemiological characteristics and evaluate the results of different treatments in this entity.
MATERIAL AND METHODS
This retrospective multicenter study evaluated diaphyseal bone defects in cases in which bone reconstruction was performed. BD was either initial and associated with trauma or secondary, resulting from infected non-union.
RESULTS
The series included 27 patients (17 boys and 10 girls), mean age 11.4 years old (3-16) (20 traffic accidents). At the outset of all patients' history was an open fracture (one stage 1, seven stage 2, 11 stage 3A and seven stage 3B, 1 NR). BD involved 13 tibias, 9 femurs, three humerus, one radius and one ulna. Bone defects were initial in 20 cases and secondary in seven cases. They were less than 2 cm in two cases, between 2 and 5 cm in 9 cases, between 5 and 10 cm in 10 cases and more than 10 cm in six cases. Treatment of BD was immediate in one case and delayed in 26 cases. Techniques used included: induced membrane in 10 cases, bone transport in seven cases, bone autograft in eight cases, vascularized fibular transfer in one case, no bone reconstruction in one case. Union was obtained in 27 patients. Union was obtained within a mean 12.3 months BD (3-62). Fifteen patients presented with sequellae.
DISCUSSION
Traumatic bone defects have a better prognosis in children than in adults. The thicker, more active and richly vascularized periosteum in children is an important prognostic factor. Treatment of BD requires good initial bone stabilization. Reconstruction depends on the integrity of the periosteum. In case of an intact periosteum, bone reconstruction does not seem necessary in young children. If one part of the periosteum is intact, a simple autograft seems sufficient even with extensive bone defects. In the absence of the periosteum or especially in case of infection, the induced membrane technique seems preferable, with bone transport or a vascularized bone transfer.
LEVEL OF EVIDENCE
IV: retrospective study.
Topics: Adolescent; Bone Transplantation; Child; Child, Preschool; Diaphyses; Female; Femoral Fractures; Fracture Fixation, Internal; Fracture Healing; Fractures, Bone; Fractures, Open; Humans; Humeral Fractures; Male; Radiography; Plastic Surgery Procedures; Tibial Fractures; Treatment Outcome; Ulna Fractures
PubMed: 22349205
DOI: 10.1016/j.otsr.2012.01.001 -
Journal of Orthopaedic Surgery and... Jul 2020External fixation improves open fracture management in emerging countries. However, sophisticated models are often expensive and unavailable. We assessed the...
BACKGROUND
External fixation improves open fracture management in emerging countries. However, sophisticated models are often expensive and unavailable. We assessed the biomechanical properties of a low-cost external fixation system in comparison with the Hoffmann® 3 system, as a reference.
METHODS
Transversal, oblique, and comminuted fractures were created in the diaphysis of tibia sawbones. Six external fixators were tested in three modes of loading-axial compression, medio-lateral (ML) bending, and torsion-in order to determine construction stiffness. The fixator construct implies two uniplanar (UUEF1, UUEF2) depending the pin-rods fixation system and two biplanar (UBEF1, UBEF2) designs based on different bar to bar connections. The designed low-cost fixators were compared to a Hoffmann® 3 fixator single rod (H3-SR) and double rod (H3-DR). Twenty-seven constructs were stabilized with UUEF1, UUEF2, and H3-SR (nine constructs each). Nine constructs were stabilized with UBEF1, UBEF2, and H3-DR (three constructs each).
RESULTS
UUEF2 was significantly stiffer than H3-SR (p < 0.001) in axial compression for oblique fractures and UUEF1 was significantly stiffer than H3-SR (p = 0.009) in ML bending for transversal fractures. Both UUEFs were significantly stiffer than H3-SR in axial compression and torsion (p < 0.05), and inferior to H3-SR in ML bending, for comminuted fractures. In the same fracture pattern, UBEFs were significantly stiffer than H3-DR (p = 0.001) in axial compression and torsion, while only UBEF1 was significantly stiffer than H3-DR in ML bending (p = 0.013).
CONCLUSIONS
The results demonstrated that the stiffness of the UUEF and UBEF device compares to the reference fixator and may be helpful in maintaining fracture reduction. Fatigue testing and clinical assessment must be conducted to ensure that the objective of bone healing is achievable with such low-cost devices.
Topics: Biomechanical Phenomena; Cost Savings; Diaphyses; Equipment Design; External Fixators; Fracture Fixation; Fracture Healing; Fractures, Comminuted; Humans; Materials Testing; Models, Anatomic; Tibia; Tibial Fractures
PubMed: 32631381
DOI: 10.1186/s13018-020-01777-5 -
Acta Orthopaedica Et Traumatologica... 2012The aim of this study was to evaluate the time to union and complications in cases of tibial diaphysis and distal tibial fractures fixed with a minimally invasive...
OBJECTIVE
The aim of this study was to evaluate the time to union and complications in cases of tibial diaphysis and distal tibial fractures fixed with a minimally invasive percutaneous plate.
METHODS
Thirty-five patients (23 males, 12 females) were operated on using minimally invasive percutaneous plate osteosynthesis (MIPPO) principles for tibial diaphysis and distal tibial fractures. Twenty-eight were closed and seven were open fractures. After direct or indirect fracture reduction, the plate was advanced through a submuscular extraperiosteal tunnel through the distal incision without opening the fracture line. The plate was fixed with screws through the proximal and distal incisions. Clinical and radiological evaluations were made at four to six week intervals after surgery. Full weight-bearing was allowed after an average of 14.43 (range: 12 to 20) weeks and 15.39 (range: 8 to 32) weeks in open and closed fractures, respectively. Duration of the union and complications were analyzed.
RESULTS
The mean duration of the union was 20.7 (range: 16 to 28) weeks and 17.96 (range: 10 to 36) weeks in open and closed fractures, respectively. All cases showed union except one who had an implant failure. Necrosis at the wound developed in one case and infection in another.
CONCLUSION
MIPPO is an effective alternative treatment for tibial diaphysis and distal tibia fractures with low complication and high union rates.
Topics: Adult; Aged; Aged, 80 and over; Bone Plates; Diaphyses; Female; Fracture Fixation, Internal; Fracture Healing; Fractures, Closed; Fractures, Open; Humans; Male; Middle Aged; Minimally Invasive Surgical Procedures; Radiography; Tibial Fractures; Young Adult
PubMed: 22659631
DOI: 10.3944/aott.2012.2597 -
PloS One 2023Previous studies have demonstrated the ability of osseointegration of porous titanium implants in cancellous bone. Our study was designed to (i) investigate the ability...
Previous studies have demonstrated the ability of osseointegration of porous titanium implants in cancellous bone. Our study was designed to (i) investigate the ability of bone ingrowth into 3D-printed porous titanium alloy implant on the cortical bone of rabbits using CT-scan and histology, and (ii) to identify the consistency of the radiology information between clinical Cone Beam Computed Tomography (CBCT) and Micro Computed Tomography (μCT) in the evaluation of bone ingrowth. The porous titanium alloy implants were 3D-printed employing the Electron Beam Melting (EBM) technology with an intended pore size of 600 μm and porosity of approximately 50 percent. Each implant was inserted into tibial diaphysis in one rabbit and its pores were classified as contacting bone or non-contacting bone. Depending on the time of explantation, the rabbits were divided into two groups: group 1 consisting of 6 rabbits between 13 and 20 weeks and group 2 consisting of 6 rabbits between 26 and 32 weeks. Tissue ingrowth into the non-bone contacting pores were evaluated by CBCT and histology. μCT was used to further investigate the bone ingrowth into four implants (two from each group were randomly chosen). The CBCT detected the present of tissue with bone-like density in both bone-contacting pores and non-bone-contacting pores of all implants. The μCT analysis also supported this result. All the bone-like tissues were then histologically confirmed to be mature bone. The analysis of CBCT data to assess bone ingrowth in porous implants had the sensitivity, specificity, positive and negative predictive values of 85, 84, 93 and 70 percent, respectively, when considering μCT assessment as the gold standard. Fully porous titanium alloy implant has great potential to reconstruct diaphyseal bone defect due to its good ability of osseointegration. CBCT is a promising method for evaluation of bone ingrowth into porous implants.
Topics: Animals; Rabbits; Diaphyses; Porosity; Titanium; X-Ray Microtomography; Lagomorpha; Alloys; Printing, Three-Dimensional
PubMed: 37682822
DOI: 10.1371/journal.pone.0282457 -
BMC Musculoskeletal Disorders Sep 2021The implantation of screws is a standard procedure in musculoskeletal surgery. Heat can induce thermal osteonecrosis, damage the bone and lead to secondary problems like...
BACKGROUND
The implantation of screws is a standard procedure in musculoskeletal surgery. Heat can induce thermal osteonecrosis, damage the bone and lead to secondary problems like implant loosening and secondary fractures. The aim of this study was to investigate whether screw insertion generates temperatures that can cause osteonecrosis.
METHODS
We measured the temperature of twenty human femur diaphysis in a total of 120 measurements, while screws of different material (stainless steel and titanium alloy) and different design (locking and cortex screw) were inserted in three different screwing modes (manual vs. machine screwing at full and reduced rotational speed) with 6 thermocouples (3 cis and 3 trans cortex). Each was placed at a depth of 2 mm with a distance of 1.5 mm from the outer surface of the screw.
RESULTS
The screw design (cortical > locking), the site of measurement (trans-cortex > cis-cortex) and the type of screw insertion (hand insertion > machine insertion) have an influence on the increase in bone temperature. The screw material (steel > titanium), the site of measurement (trans-cortex > cis-cortex) and the type of screw insertion (machine insertion > hand insertion) have an influence on the time needed to cool below critical temperature values. The combination of the two parameters (maximum temperature and cooling time), which is particularly critical for osteonecrosis, is found only at the trans-cortex.
CONCLUSION
Inserting a screw hast the potential to increase the temperature of the surrounding bone tissue above critical values and therefore can induce osteonecrosis. The trans-cortex is the critical area for the development of temperatures above the osteonecrosis threshold, making effective cooling by irrigation difficult. It would be conceivable to cool the borehole with cold saline solution before inserting the screw or to cool the screw in cold saline solution. If possible, insertion by hand should be considered.
Topics: Biomechanical Phenomena; Bone Screws; Bone and Bones; Diaphyses; Hot Temperature; Humans; Stainless Steel
PubMed: 34592967
DOI: 10.1186/s12891-021-04723-6 -
Journal of Shoulder and Elbow Surgery Jul 2022Closed reduction and percutaneous pinning is still a preference for the treatment of supracondylar humerus fractures in children. However, no reports have shown the pin...
BACKGROUND
Closed reduction and percutaneous pinning is still a preference for the treatment of supracondylar humerus fractures in children. However, no reports have shown the pin trajectory and the characteristics of the entry point so far. So we established a computational simulation model of the elbow to observe the trajectory of pinning for supracondylar humerus fractures.
METHODS
We reconstructed an adult elbow computationally and simulated pin placement through lateral and medial pinning. Pin trajectories were traced after placement and after the addition of the skin profile; the relative entry points of the pins were determined. We used the center of the dorsal olecranon inflection as an anatomic reference for the entry points of lateral pinning. Four quadrants were established based on the center of the dorsal olecranon inflection: upper medial quadrant, upper lateral quadrant, lower medial quadrant, and lower lateral quadrant (LLQ).
RESULTS
The maximum angle of pinning through the lateral column was 64° ± 3°. The minimum angles of pinning through the lateral column and middle column were 37° ± 3° and 20° ± 2°, respectively. The range of safe angle pinning through the medial column was between 18° ± 2° and 57° ± 3° to avoid penetration of the olecranon fossa and the cortex of the medial column. The entry points of lateral pinning were within the lateral half of the LLQ, and the lateral one-third of the LLQ contained all entry points of the pins through the lateral column and minor points of the pins through the middle column. The exit points of the medial pinning were within the lateral fringe of the metaphyseal-diaphyseal junction region; entering from the inferior two-thirds of the medial epicondyle could lead to the exit points in the proximal half of the metaphyseal-diaphyseal junction region laterally.
DISCUSSION
For lateral pinning, the entry points would be within the lateral half of the LLQ. For the pins through the lateral column, the entry points should be within the lateral one-third of the LLQ. For medial pinning, entering from the inferior two-thirds of the medial epicondyle would lead to a more proximal exit.
Topics: Bone Nails; Bone Wires; Child; Diaphyses; Fracture Fixation; Humans; Humeral Fractures; Humerus
PubMed: 35151881
DOI: 10.1016/j.jse.2021.12.048 -
Journal of Bone and Mineral Research :... Nov 2005Femoral morphology and composition were determined for three inbred mouse strains between ages E18.5 and 1 year. Genotype-specific variation in postnatal, pubertal, and...
UNLABELLED
Femoral morphology and composition were determined for three inbred mouse strains between ages E18.5 and 1 year. Genotype-specific variation in postnatal, pubertal, and postpubertal growth patterns and mineral accrual explained differences in adult bone trait combinations and thus bone fragility.
INTRODUCTION
Fracture risk is strongly regulated by genetic factors. However, this regulation is generally considered complex and polygenic. Therefore, the development of effective genetic-based diagnostic and treatment tools hinges on understanding how multiple genes and multiple cell types interact to create mechanically functional structures. The goal of this study was to connect variability in whole bone mechanical function, including measures of fragility, to variability in the biological processes underlying skeletal development. We accomplished this by testing for variation in bone morphology and composition among three inbred mouse strains from E18.5 to 1 year of age.
MATERIALS AND METHODS
Mid-diaphyseal cross-sectional areas, diameters, moments of inertia, and ash content were determined for three strains of mice with widely differing adult whole bone femoral mechanical properties (A/J, C57BL/6J, and C3H/HeJ) at E18.5 and postnatal days 1, 7, 14, 28, 56, 112, 182, and 365 (n = 5-15 mice/strain/age).
RESULTS
Significant differences in the magnitude and rate of change in morphological and compositional bone traits were observed among the three strains at each phase of growth, including prenatal, postnatal, pubertal, and adult ages. These genotype-specific variations in growth patterns mathematically determined how variation in adult bone trait combinations and mechanical properties arose. Furthermore, six bone traits were identified that characterize phenotypic variability in femoral growth. These include (1) bone size and shape at postnatal day 1, (2) periosteal and (3) endosteal expansion during early growth, (4) periosteal expansion and (5) endosteal contraction in later growth, and (6) ash content. These results show that genetic variability in adult bone traits arises from variation in biological processes at each phase of growth.
CONCLUSIONS
Inbred mice achieve different combinations of adult bone traits through genotype-specific regulation of bone surface activity, growth patterns, and whole bone mineral accrual throughout femoral development. This study provides a systematic approach, which can be applied to the human skeleton, to uncover genetic control mechanisms influencing bone fragility.
Topics: Age Factors; Animals; Animals, Newborn; Biomechanical Phenomena; Bone Development; Diaphyses; Female; Femur; Fractures, Bone; Genotype; Male; Mice; Mice, Inbred C3H; Mice, Inbred C57BL; Mice, Inbred Strains; Multifactorial Inheritance; Phenotype
PubMed: 16234972
DOI: 10.1359/JBMR.050707