Integration of heterologous bone matrix associated with polymethylmethacrylate in induced tibial bone defects. An experimental study in rabbits

ABSTRACT Purpose To analyze and compare the reactions at the interface between the composite, composed of fragmented heterologous mineralized bone matrix (MOMHF) and polymethylmethacrylate (PMMA), and the rabbit's tibias, through macroscopic evaluation and scanning electron microscopy (SEM) in different periods. Methods In this study, 12 New Zealand adult rabbits were used (E1: n = 3, E2: n = 3, E3: n = 3 and E4: n = 3). They had the right tibial defects filled with composite and were evaluated immediately after surgery and at 30, 60, 90, and 120 days. Results The composites were incorporated and integrated into the recipient beds in 100% of the cases, defined by the MOMHF osseointegration and the PMMA fibrointegration, with no sign of infection, migration, or rejection. Conclusions The behavior of the composites in the recipient beds demonstrates that these biomaterials have the potential to be used in bone defect repairs, offering, thus, better quality of life to the orthopedic patient.

Characterization and Biological Performance of Marine Sponge Collagen

Abstract This study characterized the morphological aspects of marine collagen - spongin (SPG) extract from marine sponges, as well as, evaluating its in vitro and in vivo biological performance. Aplysina fulva marine sponge was used for the SPG extraction. It was investigated the physicochemical and morphological properties of SPG by using scanning electron microscopy, Fourier transform infrared spectroscopy, X-ray diffraction and compared to PMMA and bovine collagen. Additionally, the SPG cytotoxicity and its influence on cell proliferation, through in vitro tests. Moreover, the in vivo biological response was investigated using an experimental model of tibial bone defect. The results demonstrated that SPG presented an irregular granular aspect, with a composition of OH, C=O, NH, CN and an amorphous profile. Also, in vitro viability results for the L929 and MC3T3 cell lines cultured with SPG extracts demonstrated normal growth in comparison to controls, except for MC3T3 viability at day 3. For in vivo analysis, using tibial bone defects in rats, SPG treated animals presented an increased rate of material resorption and higher granulation and bone formation deposition in the region of the defect, mainly after 45 days. As a conclusion, SPG was successfully extracted. The in vitro and in vivo studies pointed out that SPG samples produced an increase in L929 and MC3T3 viability and improved the performance in tibial bone defects. It can be concluded that SPG can be used as a bone graft for bone regeneration.

Órtese com impressão 3D para ombro: relato de caso / 3D print orthesis for shoulder: case report

Subluxação do ombro é a complicação musculoesquelética mais comum das afecções do Sistema Nervoso Central e Periférico, que leva a diminuição do movimento, da função e aumento de dor. Órtese é um dos recursos auxiliares utilizados no tratamento desta patologia e visa corrigir deformidade, diminuir dor e proporcionar função ao membro acometido. Objetivo: Este trabalho propõe uma nova metodologia para projetar e fabricar órteses customizadas estabilizadoras de ombro utilizando as tecnologias de aquisição 3D por escaneamento e de fabricação por Impressão 3D, e assegurar melhor adaptabilidade e maior conforto para o usuário. Método: A metodologia utilizada neste estudo foi dividida em cinco fases: estudo de caso, escaneamento, modelagem e impressão em 3D; e acabamento. O estudo de caso do usuário com lesão de plexo braquial motivou o projeto de desenho original de órtese híbrida, personalizada e manufaturada em 3D, usando estrutura rígida e faixas de tração, com objetivo de estabilizar o ombro, diminuir a dor e permitir função. Resultados: Após escaneamento em 3D utilizou-se softwares especializados para processar a imagem tridimensional STL. Realizaram-se otimizações do projeto com geração de modelos e peças prototipadas em FDM; avaliada pelo usuário. O conceito desenvolvido foi: órtese personalizada, fácil de higienizar e vestir, resistente, articulada, veste nos dois braços com faixas de tração em tecido rígido acoplado à cintura. Conclusão: O teste com usuário corroborou com o conceito projetado e mostrou um protótipo preliminar com bom acoplamento ao tronco, tração satisfatória e possibilidade de realizar um maior número de AVD´s com menos dor e/ou sensação de cansaço

Subluxation of the shoulder is the most common musculoskeletal complication of Central and Peripheral Nervous System disorders, which leads to decreased movement, function, and increased pain. Objective: Orthosis is one of the assistive devices used in the treatment of this pathology and it focuses in correcting deformity, decreasing pain and providing function to the affected member. This study proposes a new methodology for designing and manufacturing customized shoulder stabilization orthoses with 3D scan image acquisition and 3D printing technologies, for ensuring better adaptability and comfort for the user. Method: The methodology used in this study was divided into five phases: case study, scanning, modeling and 3D printing; and finishing. The case study included a user with brachial plexus injury that motivated the original design of hybrid orthosis, personalized and manufactured in 3D, with rigid structure and traction straps, for stabilizing the shoulder, reduce pain and allowing function. Results: After 3D scanning, we used specialized software to process the three-dimensional STL image. Optimization of the project with generation of models and prototyped parts in FDM based on the user evaluations was performed. The developed concept was: personalized orthosis, easy to clean and wear, resistant, articulated, for wearing in both arms with traction straps in rigid fabric coupled to the waist. Conclusion: The user test corroborated with the designed concept and showed a preliminary prototype with good trunk coupling, satisfactory traction and possibility of performing a greater number of ADLs with less pain and/or tiredness

Axial compressive strength of human vertebrae trabecular bones classified as normal, osteopenic and osteoporotic by quantitative ultrasonometry of calcaneus

Abstract Introduction Biomechanical assessment of trabecular bone microarchitecture contributes to the evaluation of fractures risk associated with osteoporosis and plays a crucial role in planning preventive strategies. One of the most widely clinical technics used for osteoporosis diagnosis by health professionals is bone dual-energy X-ray absorptiometry (DEXA). However, doubts about its accuracy motivate the introduction of congruent technical analysis such as calcaneal ultrasonometry (Quantitative Ultrasonometry - QUS). Methods Correlations between Bone Quality Index (BQI), determined by calcaneal ultrasonometry of thirty (30) individuals classified as normal, osteopenic and osteoporotic, and elastic modulus (E) and ultimate compressive strength (UCS) from axial compression tests of ninety (90) proof bodies from human vertebrae trabecular bone, which were extracted from cadavers in the twelfth thoracic region (T12), first and fourth lumbar (L1 and L4). Results Analysis of variance (ANOVA) showed significant differences for E (p = 0.001), for UCS (p = 0.0001) and BQI. Spearman's rank correlation coefficient (rho) between BQI and E (r = 0.499) and BQI and UCS (r = 0.508) were moderate. Discussion Calcaneal ultrasonometry technique allowed a moderate estimate of bone mechanical strength and fracture risk associated with osteoporosis in human vertebrae.

A new concept of orthosis for correcting fingers ulnar deviation

Abstract Introduction Rheumatoid arthritis (RA) is a chronic, multisystem disease that involves synovial inflammation, leading to deformities, like finger ulnar deviation, pain and functional difficulties. The conservative treatment comprises orthoses, features added to the body that aims to correct deformity, reduce pain and improve functionality. In the market there are few kinetic/mobile orthosis models for correction of ulnar deviation in the fingers. However, users usually complain about increased palmar volume, presence of pressure points and functional loss, demonstrating the necessity to develop more effective orthoses. In this paper we introduce an innovative concept, of an original and articulate dynamic/kinetics orthosis, which aims to correct this finger deformity and encourage functionality. Methods Methodological procedures were divided into: Need Recognition; Specification Concept; Prototype and Validation. This paper deals with the last two stages of this research. Results A virtual orthosis prototype using CAD Solid Edge Insight™ was proposed. The orthosis developed consisted of 10 pieces, made of metal and resin with carbon fiber. Conclusion After virtual movement simulation, it was verified that the prototype allows for wrist and finger flexion/extension, the possibility of bilateral use, and provids ulnar deviation correction for the fingers. The final product is innovative and is easy to put on/off; volunteers claimed that the new prototype was satisfactory in terms of deformity correction.