Analyse et modélisation statistique linéaire de la structure osseuse crânienne à partir de données morphométriques et anthropométriques pour la prédiction de paramètres mécaniques

The aim of this study is to establish and quantify the relationship between quasi-static stiffness and anthropometric and morphometric parameters of cranial osseous bones. The purpose is to predict the fracture parameters of cranial bone in crashworthiness situation. Within an experimental protocol, 289 specimens are taken from 17 unembalmed human skulls; the subjects are aged between 53 and 82. The specimen are tested under quasi-static three-points bending tests, at 10 mm/min. Morphometric data are got by analysing specimens’ photography. Values are studied by statistical analysis based on linear methods. Data are resumed by Component Principal Analysis. Groups of specimen, in function of the area of extraction of the specimen, are detected. The relationship between the stiffness and the morphometric parameters of the specimen is studied by using multiple linear regression; the input data are the weight, the density and the curvature indices of each specimen. The regression equation for the frontal and parietal areas is confirmed by residuals study; the relative error between predicted values and observed values is 3 ± 25%. There is no linear regression for the specimen taken from the temporal area of the skull.     

Distal skeletal tibia assessed by HR-pQCT is highly correlated with femoral and lumbar vertebra failure loads

Dual energy X-ray absorptiometry (DXA) is the standard for assessing fragility fracture risk using areal bone mineral density (aBMD), but only explains 60–70% of the variation in bone strength. High-resolution peripheral quantitative computed tomography (HR-pQCT) provides 3D-measures of bone microarchitecture and volumetric bone mineral density (vBMD), but only at the wrist and ankle. Finite element (FE) models can estimate bone strength with 86–95% precision. The purpose of this study is to determine how well vBMD and FE bone strength at the wrist and ankle relate to fracture strength at the hip and spine, and to compare these relationships with DXA measured directly at those axial sites. Cadaveric samples (radius, tibia, femur and L4 vertebra) were compared within the same body. The radius and tibia specimens were assessed using HR-pQCT to determine vBMD and FE failure load. aBMD from DXA was measured at the femur and L4 vertebra. The femur and L4 vertebra specimens were biomechanically tested to determine failure load. aBMD measures of the axial skeletal sites strongly correlated with the biomechanical strength for the L4 vertebra (r = 0.77) and proximal femur (r = 0.89). The radius correlated significantly with biomechanical strength of the L4 vertebra for vBMD (r = 0.85) and FE-derived strength (r = 0.72), but not with femur strength. vBMD at the tibia correlated significantly with femoral biomechanical strength (r = 0.74) and FE-estimated strength (r = 0.83), and vertebral biomechanical strength for vBMD (r = 0.97) and FE-estimated strength (r = 0.91). The higher correlations at the tibia compared to radius are likely due to the tibia’s weight-bearing function.     

Epipaleolithic human appendicular remains from Ein Gev I,Israel

The Upper Paleolithic (Early Epipaleolithic/Kebaran; ∼ 19,000 cal BP) human skeleton, from Layer 3 of Ein Gev I on the western flanks of the Golan Heights adjacent to the Sea of Galilee, retains sufficient limb remains to permit assessment of its body size and proportions, as well as diaphyseal reflections of skeletal hypertrophy. The individual was of modest stature but average mass for a later Upper Paleolithic individual, providing it with the body mass-to-stature body proportions characteristic of later Upper Paleolithic and more recent circum-Mediterranean humans. The humeri exhibit unexceptional diaphyseal asymmetry and robustness for an Upper Paleolithic human, and the femur exhibits similar relative diaphyseal hypertrophy. The humeral midshafts are relatively round, but the femoral and tibial midshafts are pronounced anteroposteriorly. As such, Ein Gev 1 provides additional paleobiological data on the appendicular remains of these Southwest Asian humans prior to the increasing sedentism of the terminal Pleistocene.     

Atomistic simulation of nanomechanical properties of Alzheimer’s Aβ(1–40) amyloid fibrils under compressive and tensile loading

In addition to being associated with severe degenerative diseases, amyloids show exceptional mechanical properties including great strength, sturdiness and elasticity. However, thus far physical models that explain these properties remain elusive, and our understanding of molecular deformation and failure mechanisms of individual amyloid fibrils is limited. Here we report a series of molecular dynamics simulations, carried out to analyze the mechanical response of two-fold symmetric Aβ(1–40) amyloid fibrils, twisted protein nanofilaments consisting of a H-bonded layered structure. We find a correlation of the mechanical behavior with chemical and nanostructural rearrangements of the fibril during compressive and tensile deformation, showing that the density of H-bonds varies linearly with the measured strain. Further, we find that both compressive and tensile deformation is coupled with torsional deformation, which is manifested in a strong variation of the interlayer twist angle that is found to be proportional to both the applied stress and measured strain. In both compression and tension we observe an increase of the Young's modulus from 2.34 GPa (for less than 0.1% strain in compression and 0.2% strain in tension), to 12.43 GPa for compression and 18.05 GPa for tension. The moduli at larger deformation are in good agreement with experimental data, where values in the range of 10–20 GPa have been reported. Our studies confirm that amyloids feature a very high stiffness, and elucidate the importance of the chemical and structural rearrangements of the fibrils during deformation.     

Candida utilis metabolism and morphology under increased air pressure up to 12 bar

Batch cultures of Candida utilis CBS 621 were carried out in a pressurized reactor under increased air pressure up to 6 bar. The effect of total air pressure was also investigated in a high cell density fed-batch culture, raising the total air pressure from 1 bar to 12 bar. The results showed that the rise of air pressure, for both operation modes, led to a substantial enhancement of biomass production. Moreover, ethanol formation was significantly reduced at 6 bar and 12 bar air pressure, respectively for batch and fed-batch processes.A method using automatic image analysis for classification of C. utilis cells based on their morphology was developed and applied to experimental data. Morphological parameters such as single and budding cells, cell size and elongation factor, were analyzed to assess the pressure effect on yeast culture. No significant differences were observed in cell size distribution and yeast cells retained the typical oval form, even at 12 bar air pressure.In what biological aspects are concerned, it is possible to state that C. utilis CBS 621 can cope with hyperbaric stress, meaning that the use of increased air pressure is a suitable method for oxygenation enhancement of high-density cultures of this strain.     

Tibio-femoral joint contact in healthy and osteoarthritic knees during quasi-static squat: A bi-planar X-ray analysis

The aim of this study was to quantify the tibio-femoral contact point (CP) locations in healthy and osteoarthritic (OA) subjects during a weight-bearing squat using stand-alone biplanar X-ray images.Ten healthy and 9 severe OA subjects performed quasi-static squats. Bi-planar X-ray images were recorded at 0°, 15°, 30°, 45°, and 70° of knee flexion. A reconstruction/registration process was used to create 3D models of tibia, fibula, and femur from bi-planar X-rays and to measure their positions at each posture. A weighted centroid of proximity algorithm was used to calculate the tibio-femoral CP locations. The accuracy of the reconstruction/registration process in measuring the quasi-static kinematics and the contact parameters was evaluated in a validation study.The quasi-static kinematics data revealed that in OA knees, adduction angles were greater (p<0.01), and the femur was located more medially relative to the tibia (p<0.01). Similarly, the average CP locations on the medial and lateral tibial plateaus of the OA patients were shifted (6.5±0.7 mm; p<0.01) and (9.6±3.1 mm; p<0.01) medially compared to the healthy group. From 0° to 70° flexion, CPs moved 8.1±5.3 mm and 8.9±5.3 mm posteriorly on the medial and lateral plateaus of healthy knees; while in OA joints CPs moved 10.1±8.4 mm and 3.6±2.8 mm posteriorly. The average minimum tibio-femoral bone-to-bone distances of the OA joints were lower in both compartments (p<0.01).The CPs in the OA joints were located more medially and displayed a higher ratio of medial to lateral posterior translations compared to healthy joints.     

Proximal femoral diaphyseal cross-sectional geometry in Orrorin tugenensis

Functional adaptations in femora attributed to Orrorin tugenensis provide a unique opportunity to examine locomotor behavior very early in the hominin lineage. This study examines relative cortical thickness, cortical area (CA) relative to the polar moment of area (J), and J relative to femoral head superoinferior diameter (FHD) in the proximal femur of O. tugenensis (BAR 1002’00 and BAR 1003’00), and compares patterns in this early hominin with those in a sample of modern humans (N = 31), Plio-Pleistocene fossil hominins (N = 8), Pan troglodytes troglodytes (N = 13), and Pan paniscus (N = 3). Relative cortical thickness and CA relative to J in the proximal femur of O. tugenensis are comparable to patterns generally found in other fossil hominins. Proximal femoral diaphyseal J relative to FHD in BAR 1002’00 is similar to patterns found in fossil hominins typically attributed to a non-Homo genus (i.e. SK 82, SK 97, and KNM-ER 738). Cross-sectional geometric patterns in the proximal femur of Orrorin are not unlike those generally found in australopithecines and fossil Homo. While the results of this study cannot confirm unequivocally that Orrorin was an obligate biped, a mode of locomotion comparable to that proposed for australopithecines cannot be ruled out.     

Compressive strain rate sensitivity of ballistic gelatin

Gelatin is a popular tissue simulant used in biomedical applications. The uniaxial compressive stress–strain response of gelatin was determined at a range of strain rates. In the quasistatic regime, gelatin strength remained relatively constant. With increase in loading rate, the compressive strength increased from 3 kPa at a strain rate of around 0.0013/s to 6 MPa at a strain rate of around 3200/s. This dramatic increase in strength of gelatin at high rates is attributed to its shear-thickening behavior and is argued on the basis of hydrocluster formation mechanism and differences in internal energy dissipation mechanism under static and dynamic loading.     

Transplantation of human neonatal foreskin stromal cells in ex vivo organotypic cultures of embryonic chick femurs

We have previously reported that human neonatal foreskin stromal cells (hNSSCs) promote angiogenesis in vitro and in chick embryo chorioallantoic membrane (CAM) assay in vivo. To examine the in vivo relevance of this observation, we examined in the present study the differentiation potential of hNSSCs in ex vivo organotypic cultures of embryonic chick femurs. Isolated embryonic chick femurs (E10 and E11) were cultured for 10 days together with micro-mass cell pellets of hNSSCs, human umbilical vein endothelial cells (HUVEC) or a combination of the two cell types. Changes in femurs gross morphology and integration of the cells within the femurs were investigated using standard histology and immunohistochemistry. After 10 days, the femurs that were cultured in the presence of hNSSCs alone or hNSSC + HUVEC cells grew longer, exhibited thicker diaphysis and an enlarged epiphyseal region compared to control femurs cultured in the absence of cells. Analysis of cell–femur interactions, revealed intense staining for CD31 and enhanced deposition of collagen rich matrix along the periosteum in femurs cultured with hNSSCs alone or hNSSCs + HUVEC and the most pronounced effects were observed in hNSSC + HUVEC cultures. Our data suggest that organotypic cultures can be employed to test the differentiation potential of stem cells and demonstrate the importance of stem cell interaction with 3D-intact tissue microenvironment for their differentiation.     

Deformation and recovery of cartilage in the intact hip under physiological loads using 7 T MRI

Accurate measurement of cartilage deformation in loaded cadaver hip joints could be a valuable tool to answer clinically relevant research questions. MRI is a promising tool, but its use requires an understanding of cartilage deformation and recovery properties in the intact hip. Our objective was to answer the following questions: (1) How long does it take for hip cartilage to reach a deformed steady-state thickness distribution under simulated physiological load, and how much does the cartilage deform? (2) How long does it take for hip cartilage to return to the original cartilage thickness distribution once the load is removed?MethodsFive human hip specimens were axially loaded to 1980 N in a 7 T MR scanner and scanned every 15 min throughout loading. One specimen was scanned every hour throughout recovery from load. One repeatability specimen was loaded and scanned every day for 4 days. Hip cartilage was segmented as a single unit and thickness was measured radially.ResultsThe hip cartilage reached a steady-state thickness distribution after 225 min of load, and 16.5 h of recovery. Mean strain after 225 min of load was 30.9%. The repeatability specimen showed an average day-to-day change in mean cartilage thickness of 0.10 mm over 4 days of data collection. The amount of deformation (0.96 mm) was far greater than the image resolution (0.11 mm) and error due to repeatability (0.10 mm).ConclusionUsing an ex vivo model, this method has potential for assessing changes in hip cartilage strain due to injury or surgical intervention.     

Achieving high strength vinegar fermentation via regulating cellular growth status and aeration strategy

Implementing of high strength vinegar fermentation is still the mission of vinegar producers. The aim of this study was to carry out high acidity vinegar fermentation efficiently based on comprehensive analysis on bacterial fermentation kinetics characteristics of Acetobacter pasteurianus CICIM B7003-02. In practice, semi-continuous vinegar fermentation was optimized with an optimal discharge/charge ratio of 34% of working volume (v/v), which resulted in a proper growth status of Acetobacter and beneficial to acetification. Then, a two-stage aeration protocol was adopted in the vinegar fermentation in line with the Acetobacter theoretical oxygen demand, by which both vinegar stoichiometric yield and acetification rate were improved effectively. As the final result, a titer of 93.09 ± 0.24 g/L acetic acid was achieved, the average acetification rate was enhanced to a level of 1.83 ± 0.01 g/L/h, and the vinegar stoichiometric yield was promoted to 93.97 ± 0.16%. The strategy and practice worked out from this study provided a valuable reference for performing large scale vinegar fermentation with higher strength.     

High-pressure CO2 inactivation and induced damage on Saccharomyces cerevisiae evaluated by flow cytometry

The cultivability, integrity and permeabilisation of Saccharomyces cerevisiae in saline solution after high-pressure CO₂ treatment at 36 °C was assessed by using both conventional cultivation-based technique and flow cytometry. Conventional cultivation-based techniques do not allow the exact quantification of integer cells, which can be determined coupling the staining with propidium iodide and SYBR-Green I and the cell quantification by flow cytometry. A significant portion of cells injured by CO₂ treatment is incapable of forming colonies but is still integer and potentially metabolically active. The yeast cell damage was demonstrated to be dependent on the conditions applied. In particular the influence of different operative parameters on integrity and permeabilisation of yeast cells was evaluated: pressure (50–100 bar), treating time (10–20 min) and stirring rate (500–10,000 rpm). After a 20 min treatment at 100 bar, 36 °C and 10,000 rpm more than 95% of cells result with completely permeabilised membrane.     

Macroscopic anisotropic bone material properties in children with severe osteogenesis imperfecta

Children with severe osteogenesis imperfecta (OI) typically experience numerous fractures and progressive skeletal deformities over their lifetime. Recent studies proposed finite element models to assess fracture risk and guide clinicians in determining appropriate intervention in children with OI, but lack of appropriate material property inputs remains a challenge. This study aimed to characterize macroscopic anisotropic cortical bone material properties and investigate relationships with bone density measures in children with severe OI. Specimens were obtained from tibial or femoral shafts of nine children with severe OI and five controls. The specimens were cut into beams, characterized in bending, and imaged by synchrotron radiation X-ray micro-computed tomography. Longitudinal modulus of elasticity, yield strength, and bending strength were 32–65% lower in the OI group (p < 0.001). Yield strain did not differ between groups (p ≥ 0.197). In both groups, modulus and strength were lower in the transverse direction (p ≤ 0.009), but anisotropy was less pronounced in the OI group. Intracortical vascular porosity was almost six times higher in the OI group (p < 0.001), but no differences were observed in osteocyte lacunar porosity between the groups (p = 0.086). Volumetric bone mineral density was lower in the OI group (p < 0.001), but volumetric tissue mineral density was not (p = 0.770). Longitudinal OI bone modulus and strength were correlated with volumetric bone mineral density (p ≤ 0.024) but not volumetric tissue mineral density (p ≥ 0.099). Results indicate that cortical bone in children with severe OI yields at the same strain as normal bone, and that their decreased bone material strength is associated with reduced volumetric bone mineral density. These results will enable the advancement of fracture risk assessment capability in children with severe OI.     

Evolutionary adaptation of Kluyveromyces marxianus strain for efficient conversion of whey lactose to bioethanol

The aim of the present work is to develop an osmotolerant yeast strain with high lactose utilization and further use it to ferment lactose rich whey permeate for high ethanol titer and to reduce energy consumption. Ethanol production and growth rate of selected MTCC 1389 strain were quite high in whey containing lactose up to 150 g/L but it remains constant in lactose concentration (200 g/L) as cells encountered osmotic stress. Thus, strain MTCC 1389 was used for an adaptation to lactose concentration 200 g/L for 65 days and used further for fermentation of lactose rich whey. Fermentation with an adapted K. marxianus MTCC 1389 strain in laboratory fermenter resulted in ethanol titer of 79.33 g/L which is nearly 17.5% higher than the parental strain (66.75 g/L). Expression analysis of GPD1, TPS1and TPS2 found upregulated in lactose adapted K. marxianus strain as compared to the parental strain. These results suggest that an adapted K. marxianus strain accumulates glycerol and trehalose in response to lactose stress and improve osmotolerance in K. marxianus cells. Thus, the study illustrates that evolutionary engineering is an efficient strategy to obtain a superior biofuel yeast strain, which efficiently ferments four-fold concentrated cheese whey.     

Postnatal development of morphological and vocal features in Asian particolored bat,Vespertilio sinensis

We studied the postnatal development of morphological and vocal features in a free-ranging population of the Asian particolored bat, Vespertilio sinensis. There were no significant differences in postnatal growth rates between males and females on the basis of morphological changes. Body mass and forearm length followed a linear pattern of growth until 28 days of age at mean growth rates of 0.38 g/day and 1.15 mm/day, respectively and thereafter increased slowly. The length of total epiphyseal gap of the fourth metacarpal–phalangeal joint initially showed a linear increase for up to 16 days, followed by a linear decrease until day 46 at a mean rate of 0.18 mm/day. When forearm length was used in combination with changes in total epiphyseal gap length, we derived reliable age estimation equations for the 1–46 day age range. Of the three nonlinear growth models (logistic, Gompertz, and von Bertalanffy), the von Bertalanffy and logistic equations provided the best fit to the empirical curves for body mass and forearm length, respectively. Studies of vocal development showed that infants could emit short calls as precursors of echolocation calls after birth. Isolation calls and precursors of echolocation calls were both characterized by multiple harmonics. We observed a systematic increase in the value of the starting frequency without a significant change in the terminal frequency over the 3 week period of development. In addition, the duration of isolation calls increased until day 4 and then decreased, whereas, the duration of precursors of echolocation calls decreased continuously to reach a stable level.     

Intramedullary pressure and matrix strain induced by oscillatory skeletal muscle stimulation and its potential in adaptation

Intramedullary pressure (ImP) and low-level bone strain induced by oscillatory muscle stimulation (MS) has the potential to mitigate bone loss induced by disuse osteopenia, i.e., hindlimb suspension (HLS). To test this hypothesis, we evaluated (a) MS-induced ImP and bone strain as function of stimulation frequency and (b) the adaptive responses to functional disuse, and disuse plus 1 and 20 Hz stimulation in vivo. Femoral ImP and bone strain generated by MS were measured in the frequencies of 1–100 Hz in four rats. Forty retired breeder rats were used for the in vivo HLS study. The quadriceps muscle was stimulated at frequencies of 1 and 20 Hz, 10 min/d for four weeks. The metaphyseal trabecular bone quantity and microstructure at the distal femur were evaluated using μCT, while bone formation indices were analyzed using histomorphometric technique. Oscillatory MS generated a maximum ImP of 45±9 mmHg at 20 Hz and produced a maximum matrix strain of 128±19 με at 10 Hz. Our analyses from the in vivo study showed that MS at 20 Hz was able to attenuate trabecular bone loss and partially maintain the microstructure induced by HLS. Conversely, there was no evidence of an adaptive effect of stimulation at 1 Hz on disused skeleton. The results suggested that oscillatory MS regulates fluid dynamics and mechanical strain in bone, which serves as a critical mediator of adaptation. These results clearly demonstrated the ability of MS in attenuating bone loss from the disuse osteopenia, which may hold potential in mitigating skeletal degradation imposed by conditions of disuse, and may serve as a biomechanical intervention in clinic application.     

Genetic stability of an Escherichia coli strain engineered to produce a novel therapeutic DNA vaccine encoding chicken type II collagen for rheumatoid arthritis

The development of therapeutic DNA vaccines capable of recovering immunological tolerance through the induction of both CD4 + CD25 + FoxP3 + regulatory and CD3 + CD8 + C28-suppressor T cells, and/or inhibition of both autoreactive CD4 + CD28+ type 1 T helper and autoantibody-producing B cells offers a promising new strategy for the treatment of rheumatoid arthritis. Previously, we developed pcDNA-CCOL2A1, a novel therapeutic DNA vaccine, which encodes the full-length chicken type II collagen sequence, and demonstrated that the efficacy of this vaccine for treating rheumatoid arthritis was comparable to that of the current “gold standard” treatment, methotrexate. In this study, we investigated the genetic stability of a strain engineered to produce the vaccine during continuous passage and long-term storage at different temperatures. By screening a panel of 12 strains, we identified a DH5α strain that exhibited high levels (12.30 ± 0.05 mg L⁻¹) of pcDNA-CCOL2A1 production after 15 h cultivation, and subsequently utilized this strain to establish a three-tier cells bank for future studies. Continuous passage of this strain for 100 inoculation times demonstrated that a higher percentage (>95%) of cells maintained the plasmid when cultivated under selective pressure (ampicillin) than under nonselective conditions, suggesting that the presence of antibiotics in the medium prevents the loss of the pcDNA-CCOL2A1 plasmid. Meanwhile, restriction digestion and gene sequencing analyses demonstrated that the pcDNA-CCOL2A1 vector remained stable, and that the plasmid sequence was conserved during this period. Lastly, the DH5α pcDNA-CCOL2A1 strain exhibited a high plasmid preservation (>90%) and high levels of plasmid production (9.05mg L⁻¹) after storage for 60 months at −80 °C. Furthermore the plasmid extracted from the DH5α pcDNA-CCOL2A1 strain after storage for 60 months at −80 °C was transfected to COS-7 cells, it can stably express the target protein chicken type II collagen. Conversely, this strain exhibited a complete loss of capability after 24 and 18 months storage at −20 °C and 4 °C, respectively. These findings will facilitate further pilot-scale testing, and even industrial-scale production, of the novel therapeutic vaccine pcDNA-CCOL2A1.     

Biodegradability and mechanical properties of polycaprolactone composites encapsulating phosphate-solubilizing bacterium Bacillus sp. PG01

This study examined the feasibility of using polycaprolactone (PCL) and its composites (with starch and/or clay) in encapsulating cells of phosphate-solubilizing bacteria (PSB) for the development of biodegradable and “controlled-release” bacterial fertilizer. The PSB used in this work was an indigenous Bacillus sp. PG01 isolate. The results show that the PG01 strain was able to degrade all the cell-loaded capsules made of PCL and PCL composites, resulting in a continual cell release. Morphology observation indicates that severe disruption of the capsule structure occurred after incubation for 15–20 days. The biodegradability of the capsules decreased in the order of PCL/starch (20 wt%) > PCL/starch (20 wt%)/cay (7 wt%) > PCL alone > PCL/clay (7 wt%). Similar trends were also observed for the decrease in tensile strength and elongation at break, suggesting strong connections between biodegradability and the mechanical properties. Addition of starch appeared to enhance the biodegradability of the capsules, whereas the clay-blended composites were less biodegradable. The amount and rate of cell release from cell-encapsulated PCL-based capsules were positively dependent on the biodegradability and on the decrease in the mechanical strength. Nevertheless, the pattern of cell release was quite similar for all types of capsules. The outcome of this work seems to suggest that by proper manipulation of composite compositions, the controlled release of the bacterial fertilizer (i.e., Bacillus sp. PG01 cells) might be achievable.     

Dietary boron does not affect tooth strength,micro-hardness,and density,but affects tooth mineral composition and alveolar bone mineral density in rabbits fed a high-energy diet

The objective of this study was to determine whether dietary boron (B) affects the strength, density and mineral composition of teeth and mineral density of alveolar bone in rabbits with apparent obesity induced by a high-energy diet. Sixty female, 8-month-old, New Zealand rabbits were randomly assigned for 7 months into five groups as follows: (1) control 1, fed alfalfa hay only (5.91 MJ/kg and 57.5 mg B/kg); (2) control 2, high energy diet (11.76 MJ and 3.88 mg B/kg); (3) B10, high energy diet + 10 mg B gavage/kg body weight/96 h; (4) B30, high energy diet + 30 mg B gavage/kg body weight/96 h; (5) B50, high energy diet + 50 mg B gavage/kg body weight/96 h. Maxillary incisor teeth of the rabbits were evaluated for compression strength, mineral composition, and micro-hardness. Enamel, dentin, cementum and pulp tissue were examined histologically. Mineral densities of the incisor teeth and surrounding alveolar bone were determined by using micro-CT. When compared to controls, the different boron treatments did not significantly affect compression strength, and micro-hardness of the teeth, although the B content of teeth increased in a dose-dependent manner. Compared to control 1, B50 teeth had decreased phosphorus (P) concentrations. Histological examination revealed that teeth structure (shape and thickness of the enamel, dentin, cementum and pulp) was similar in the B-treated and control rabbits. Micro CT evaluation revealed greater alveolar bone mineral density in B10 and B30 groups than in controls. Alveolar bone density of the B50 group was not different than the controls. Although the B treatments did not affect teeth structure, strength, mineral density and micro-hardness, increasing B intake altered the mineral composition of teeth, and, in moderate amounts, had beneficial effects on surrounding alveolar bone.     

The effect of zinc and phytoestrogen supplementation on the changes in mineral content of the femur of rats with chemically induced mammary carcinogenesis

The aim of this study was to assess skeletal effects of zinc or zinc with phytoestrogen (resveratrol or genistein) supplementation in an animal model of rats with DMBA-induced mammary carcinogenesis. The changes in bone parameters such as the length and mass were examined, as well as the changes in concentrations of selected minerals: calcium, magnesium, zinc, iron and phosphorus. Moreover, the investigations focused on finding the differences between the levels of iron and zinc in other tissues: the liver, spleen and serum of the examined rats.Fifty-six female Sprague–Dawley rats, 40 days old, were divided into four groups, regardless of the diets: standard (77 mg Zn kg/food), zinc (4.6 mg/mL via gavage), zinc (4.6 mg/mL) plus resveratrol (0.2 mg/kg bw), and zinc (4.6 mg/mL) plus genistein (0.2 mg/kg bw) for a period from 40 days until 20 weeks of age. The study rats were also treated with 7,12-dimethyl-1,2-benz[a]anthracene (DMBA) to induce mammary carcinogenesis.The applied diet and the advanced mammary cancer did not affect macrometric parameters of the rats’ bones, but they strongly affected their mineral content. It was found that mammary cancer, irrespectively of the applied diet, significantly modified the iron level in the femur, liver, spleen and serum of the examined rats. In addition, zinc supplementation significantly lowered the levels of calcium, magnesium and phosphorus in the femur of rats with mammary cancer as compared with respective levels in the control group. So, it was found that additional supplementation with zinc, which is generally considered to be an antioxidant, with the co-existing mammary carcinoma, increased the unfavorable changes as concerns the stability of bone tissue. The appropriate combination of zinc and phytoestrogens (resveratrol or genistein) could help prevent or slow bone loss associated with a range of skeletal disorders in breast cancer.