Carlos E. Bozzini

Dexamethasone effects on mechanical, geometric and densitometric properties of rat femur diaphyses as described by peripheral quantitative computerized tomography and bending tests

In previous studies with cortisol, betamethasone and oxazacort we attributed glucocorticoid effects on bone biomechanics to changes in bone mass and geometry rather than to an action on bone material properties. In this experiment, groups of 7 rats each received subcutaneous doses of 15.6, 31.2, 62.5, 125, 250, 500 or 1000 micrograms/kg per day of dexamethasone (DMS) and an additional 14 animals were controlled untreated for 4 weeks. Their fresh femurs were then scanned by peripheral quantitative computerized tomography (pQCT; XCT-960, Stratec, Germany) at the midshaft and submitted to three-point bending tests. In consonance with our earlier investigations, a significant, log-dose-related reduction in bone load-bearing capacity was observed, associated with an impairment in bone geometric properties (cross-sectional area and moment of inertia) and in body weight gain. However, the pQCT-assessed volumetric mineral density of cortical bone (vCtBMD; regarded as a material quality indicator in terms of mineralization) was significantly reduced by DMS following a dose-response relationship. Furthermore, a direct association was detected between vCtBMD and diaphyseal load-bearing capacity and stiffness. In contrast with our previous approach, data suggests that, apart from changes in bone geometric properties, glucocorticoid effects on bone material quality--as assessed by vCtBMD changes in this study--seem also to play a significant role in the determination of their biomechanical consequences.

Effect of protein-energy malnutrition in early life on the dimensions and bone quality of the adult rat mandible

Morphological and biomechanical features of the mandible are negatively affected by protein-energy malnutrition, whose effects are apparently dependent on the time of life of application. The aim here was to investigate, in neonatal rats nursed by dams put on a protein-free diet to depress milk production and thus create a state of protein-energy malnutrition in the offspring, subsequent growth and long-term effects by analyzing mandibular dimensions and bone quality in adulthood. Pregnant Wistar rats were fed a 20% protein diet (control) or a protein-free diet (malnourished) to obtain normal or subnormal milk production, respectively. After weaning, the offspring (males) were fed a 20% protein diet for 70 days. The dimensions of their excised mandibles were measured directly between anatomical points; the geometry and material quality of mandibular bone were assessed by peripheral quantitative computed tomography. Pups suckling from malnourished dams weighed 49.4% of those suckling from control dams at weaning; the actual difference between control and malnourished pups was 25.1g, which persisted until day 91 of age, indicating the absence of catch-up growth. As with body size, the mandibular base length, height and area (an index of mandibular size) were significantly smaller in malnourished than control rats at the end of the study. The mandibular cortical area, volumetric cortical bone mineral content and volumetric cortical bone mineral density assessed by peripheral quantitative computed tomography were similar in both groups of rats at the end of the observation period, but there was a significant reduction in the cortical axial moment of inertia in malnourished rats at this time of postnatal life. These findings suggest that catch-up growth was incomplete in rats malnourished during the suckling period and that the adaptation of mandibular bone architecture to body growth was apparently insufficient to attain normal values, thus not allowing complete compensation in mechanical competence at the end of the study because of an inadequate spatial distribution of resistive material through its cross-section rather than qualitative or quantitative impairment of cortical bone.

Failure of Polycythemia-Induced Increase in Arterial Oxygen Content to Suppress the Anorexic Effect of Simulated High Altitude in the Adult Rat

The anorexic effect of exposure to high altitude may be related to the reduction in the arterial oxygen content (Ca(O2)) induced by hypoxemia and possibly the associated decreased convective oxygen transport (COT). This study was then performed to evaluate the effects of either transfusion-induced polycythemia or previous acclimation to hypobaria with endogenously induced polycythemia on the anorexic effect of simulated high altitude (SHA) in adult female rats. Food consumption, expressed in g/d/100 g body weight, was reduced by 40% in rats exposed to 506 mbar for 4 d, as compared to control rats maintained in room air. Transfusion polycythemia, which significantly increased hematocrit, hemoglobin concentration, Ca(O2), and COT, did not change the anorexic response to the exposure to hypobaric air. Depression of food intake during exposure to SHA also occurred in rats fasted during 31 h before exposure and allowed to eat ad libitum for 2 h during exposure. Body mass loss was similar in 48-h fasted rats that were either hypoxic or normoxic. Body mass loss was similar in normoxic and hypoxic rats, the former eating the amount of food freely eaten by the latter. Hypoxia-acclimated rats with endogenously induced polycythemia taken to SHA again had diminished food intake and lost body mass at rates that were very close to those found in nonacclimated ones. Exposure to SHA also led to a decrease in food consumption, body weight, and plasma leptin in adult female mice. Analysis of data suggest that body mass loss that accompanies SHA-induced hypoxia is due to hypophagia and that experimental manipulation of the blood oxygen transport capacity cannot ameliorate it. Leptin does not appear to be an inducer of the anorexic response to hypoxia, at least in mice and rats.

The Concentration of Dietary Casein Required for Normal Mandibular Growth in the Rat

To determine a suitable casein concentration for normal, undeformed mandibular growth, we placed weanling male rats on diets containing graded levels of casein between 0% and 30% for 19 days. Some weanlings were killed so that initial values could be established. Ten linear dimensions corresponding to the six skeletal units of the mandible were evaluated so that their growth rates at the end of the experimental period could be established. Other dimensions were also evaluated for study of the growth rate of the bone as a whole. The macroscopic growth of the mandible showed a sigmoidal relationship with dietary casein concentration, most of the measurements reaching a plateau at 20% casein. Within the skeletal units, four dimensions corresponding to the alveolar and symphyseal regions did not change with age and were not affected by the casein content of the diet. The remaining six dimensions-corresponding to condylar, coronoid, angular, and basal regions of the mandible-increased with age and were related positively to dietary casein concentration. Their growth patterns were not uniform, although all of them reached maximal values when the diet contained 20% casein. Therefore, deformation of the mandible appears to occur in rats fed diets with a casein concentration lower than 20%. It appears that a dietary casein concentration of 20% is required for normal, undeformed mandibular growth.

Prolonged exposure to hypobaric hypoxia transiently reduces GABAA receptor number in mice cerebral cortex

The central nervous system is severely affected by hypoxic conditions, which produce alterations in neural cytoarchitecture and neurotransmission, resulting in a variety of neuropathological conditions such as convulsive states, neurobehavioral impairment and motor CNS alterations. Some of the neuropathologies observed in hypobaric hypoxia, corresponding to high altitude conditions, have been correlated with a loss of balance between excitatory and inhibitory neurotransmission, produced by alterations in glutamatergic and GABAergic receptors. In the present work, we have studied the effect of chronic hypobaric hypoxia (506 hPa, 18 h/day x 21 days) applied to adult male mice on GABA(A) receptors from cerebral cortex, to determine whether hypoxic exposure may irreversibly affect central inhibitory neurotransmission. Saturation curves for [3H]GABA specifically bound to GABA(A) receptors in isolated synaptic membranes showed a 30% decrease in maximal binding capacity after hypoxic exposure (Bmax control, 4.70+/-0.19, hypoxic, 3.33+/-0.10 pmol/mg protein), with no effect on GABA binding sites affinity (Kd control: 159.3+/-13.3 nM, hypoxic: 164.2+/-15.1 nM). Decreased B(max) values were observed up to the 10th post-hypoxic day, returning to control values by the 15th post-hypoxic day. Pharmacological properties of GABA(A) receptor were also affected by hypoxic exposure, with a 45 to 51% increase in the maximal effect by positive allosteric modulators (pentobarbital and 5alpha-pregnan-3alpha-ol-20-one). We conclude that long-term hypoxia produces a significant but reversible reduction on GABA binding to GABA(A) receptor sites in cerebral cortex, which may reflect an adaptive response to this sustained pathophysiological state.

Growth-dependent effects of dietary protein concentration and quality on the biomechanical properties of the diaphyseal rat femur☆

OBJECTIVES This study compares the effects of feeding growing rats with increasing concentrations of casein (C) and wheat gluten (G), proteins that show different biological qualities, on the morphometrical and biomechanical properties of the femoral diaphysis. MATERIALS AND METHODS Female rats were fed with one of ten diets containing different concentrations (5-30%) of C and G between the 30th and 90th days of life (Control=C-20%). Biomechanical structural properties of the right femur middiaphysis were estimated using a 3-point bending mechanical test with calculation of some indicators of bone material properties. RESULTS Body weight and length were affected by treatments, values being highest in rats fed the C-20% diet. G diets affected negatively both parameters. Changes in cross-sectional geometry (mid-diaphyseal cross-sectional and cortical areas, femoral volume, and rectangular moment of inertia) were positively related to the C content of the diet, while they were severely and negatively affected by G diets. Similar behaviors were observed in the bone structural properties (fracture load, yielding load, diaphyseal stiffness and elastic energy absorption). When values of strength and stiffness were normalized for body weight, the differences disappeared. The bone material quality indicators (elastic modulus, yielding stress, elastic energy absorption/volume) did not differ significantly among all studied groups. Femoral calcium concentration in ashes was not significantly different among groups. CONCLUSION The clear differences in strength and stiffness of bone beams induced by dietary protein concentration and quality seemed to be the result of an induced subnormal gain in bone structural properties as a consequence of a correlative subnormal gain in bone growth and mass, yet not in bone material properties.

Biomechanical properties of the mandible, as assessed by bending test, in rats fed a low-quality protein

OBJECTIVE The present study describes the effects of feeding growing rats with diets containing increasing concentrations of wheat gluten (a low quality protein, G) on both the morphometrical and the biomechanical properties of the mandible. DESIGN Female rats were fed one of six diets containing different concentrations (5-30%) of G between the 30th and 90th days of life. Control rats were fed a diet containing 20% casein (C), which allows a normal growth and development of the bone. Mandibular growth was estimated directly on excised and cleaned bones by taking measurements between anatomical points. Mechanical properties of the right hemimandibles were determined by using a three-point bending mechanical test to obtain a load/deformation curve and estimate the structural properties of the bone. Bone material properties were calculated from structural and geometric properties. The left hemimandibles were ashed and the ash weight obtained. Calcium content was determined by atomic energy absorption. Results were summarised as means±SEM. Comparisons between parameters were performed by ANOVA and post-test. RESULTS None of the G-fed groups could achieve a normal growth performance as compared to the C-fed control group. Like body size, age-related increments in mandibular weight, length, height and area (index of mandibular size) were negatively affected by the G diets, as was the posterior part of the bone (posterior to molar III). The cross-sectional geometry of the mandible (cross-sectional area and rectangular moment of inertia) as well as its structural properties (yielding load, fracture load, and stiffness) were also severely affected by the G diets. However, material properties (Youngs modulus and maximum elastic stress) and calcium concentration in ashes and the degree of mineralisation were unaffected. CONCLUSIONS The differences in strength and stiffness between treated and control rats seemed to be the result of an induced loss of gain in bone growth and mass, in the absence of changes in the quality of the bone mineralised material.

Androgens and Erythropoiesis. Induction of Erythropoietin- Hypersecretory State and Effect of Finasteride on Erythropoietin Secretion

The major activity of androgens in promoting erythropoiesis is mediated by the ability of these steroids to increase erythropoietin (EPO) production. Testosterone exerts a nephrotrophic action which is evidenced by an increased renal mass following chronic administration of this steroid. The increased renal mass, in turn, may be associated with an increased capacity for production of EPO by the organ. The present study was thus designed to test the hypothesis that chronic administration of testosterone induces an EPO-hypersecretory state (EPO-HS) defined as a condition of higher than normal EPO synthesis and secretion in response to well-known erythropoietic stimuli, such as hypoxia, anaemia or cobalt. In addition, since 5α-dehydrotestosterone (5α-DHT) was found to be more active than testosterone in stimulating EPO production, the effect of inhibition of the 5α-reductase by finasteride on both constitutive and stimulated EPO secretion was also estimated. Female adult mice receiving 2 mg testosterone propionate three times a week for 3.5 weeks increased their erythrocyte production rates at day 4 and at the time of each sampling points thereafter during the injection period. Average renal weight was about 1.8 times higher in testosterone-treated than in vehicle-treated mice. When mice were hypertransfused at the end of the injection period and exposed to hypobaric air, both RBC-59Fe uptake and plasma EPO concentration (pEPO) were several times greater in androgen-treated than in vehicle-injected mice. No changes were observed in both parameters under normobaric conditions Testosterone treatment altered neither the plasma disappearance (t1/2) of radiolabelled rh-EPO nor the erythropoietic response to exogenously administered rh-EPO. pEPO was similar into normoxic male and female mice and neither orchidectomy nor finasteride (10 mg/kg/day for 12 days) modified these levels. Significant differences were seen in pEPO levels between male and female mice under hypoxic conditions. Orchidectomy and finasteride both lowered the hypoxia-dependent increment in pEPO in male mice to levels that were not significantly different from those of hypoxic female mice. In summary, an EPO-HS followed chronic administration of testosterone in mice, which may or may not be related to the nephrotrophic effect of this androgen. Since finasteride adversely affected stimulated-EPO production in mice, it is suggested that the testosterone effect on stimulated-EPO secretion is mediated by DHT. In contrast, the findings of unchanged baseline pEPO in either orchidectomised or finasteride-treated mice suggest that constitutional EPO production is not influenced by testosterone.

Biomechanical properties of the mid-shaft femur in middle-aged hypophysectomized rats as assessed by bending test

Both stiffness and strength of bones are thought to be controlled by the “bone mechanostat”. Its natural stimuli would be the strains of bone tissue (sensed by osteocytes) that are induced by both gravitational forces (body weight) and contraction of regional muscles. Body weight and muscle mass increase with age. Biomechanical performance of load-bearing bones must adapt to these growth-induced changes. Hypophysectomy in the rat slows the rate of body growth. With time, a great difference in body size is established between a hypophysectomized rat and its age-matched control, which makes it difficult to establish the real effect of pituitary ablation on bone biomechanics. The purpose of the present investigation was to compare mid-shaft femoral mechanical properties between hypophysectomized and weight-matched normal rats, which will show similar sizes and thus will be exposed to similar habitual loads. Two groups of 10 female rats each (H and C) were established. H rats were 12-month-old that had been hypophysectomized 11 months before. C rats were 2.5-month-old normals. Right femur mechanical properties were tested in 3-point bending. Structural (load-bearing capacity and stiffness), geometric (cross-sectional area, cortical sectional area, and moment of inertia), and material (modulus of elasticity and maximum elastic stress) properties were evaluated. The left femur was ashed for calcium content. Comparisons between parameters were performed by the Student’s t test. Average body weight, body length, femur weight, femur length, and gastrocnemius weight were not significantly different between H and C rats. Calcium content in ashes was significantly higher in H than in C rats. Cross-sectional area, medullary area, and cross-sectional moment of inertia were higher in C rats, whereas cortical area did not differ between groups. Structural properties (diaphyseal stiffness, elastic limit, and load at fracture) were about four times higher in hypophysectomized rats, as were the bone material stiffness or Young’s modulus and the maximal elastic stress (about 7×). The femur obtained from a middle-aged H rat was stronger and stiffer than the femur obtained from a young-adult C rat, both specimens showing similar size and bone mass and almost equal geometric properties. The higher than normal structural properties shown by the hypophysectomized femur were entirely due to changes in the intrinsic properties of the bone; it was thus stronger at the tissue level. The change of the femoral bone tissue was associated with a high mineral content and an unusual high modulus of elasticity and was probably due to a diminished bone and collagen turnover.

Enhanced Erythropoietin Response to Acute Hypoxemia in Mice with Pharmacological Depression of Erythropoiesis

The recent report of a depression of stimulated production of erythropoietin (EPO) in mice with enhanced erythropoiesis suggests that unknown mechanism (s) other than hypoxia may be involved in the regulation of EPO formation. The present study was thus designed to investigate EPO production during acute hypoxemia in a mouse model in which the oxygen-carrying capacity of blood, the plasma EPO level, and the plasma EPO half-life were within normal values in spite of a marked depression of the red cell production rate (RCPR) induced by cyclophosphamide (CP) administration. Injection of 100 mg/Kg of the drug into adult female CF-1 mice that previously received 0.4 ml of packed red cells depressed markedly the 24-hour RBC 59Fe uptake without affecting the plasma immunoreactive EPO level and the plasma disappearance of 1251-labeled recombinant human EPO. The EPO production rate, calculated from the change in plasma EPO levels and the estimated EPO clearance rate, after 4 h of exposure to hypobaric air was about 2.8 times higher in mice with CP-induced inhibition of the RCPR than in mice with normal RCPR. The results support the hypothesis that the EPO production rate in mammals is not only related to the oxygen supply to the tissues relative to their oxygen needs (main stimulus) but also to the erythroid activity of the marrow (modulatory action).