Your search keyword '"Bozzini C."' showing total 20 results

1. Periodontal status and mandibular biomechanics in rats subjected to hyposalivation and periodontitis.

Author

Balcarcel NB, Ossola CA, Troncoso GR, Rodas JA, Astrauskas JI, Bozzini C, Elverdin JC, and Fernández Solari J

Subjects

Animals, Rats, Male, Biomechanical Phenomena, Alveolar Bone Loss diagnostic imaging, Alveolar Bone Loss etiology, Periodontitis physiopathology, Mandible diagnostic imaging, Rats, Wistar, Xerostomia etiology, Xerostomia physiopathology

Abstract

Xerostomia emerges as a consequence of salivary gland hypofunction, and seriously compromises the integrity of hard and soft oral tissues, whileperiodontitis is an infectious disease characterized by biofilm accumulation, inflammation and alveolar bone resorption., Aim: The aim this study was to compare the deleterious effects caused by experimental hyposalivation, periodontitis, and the combination of both on periodontal tissues and mandibular biomechanics in rats., Materials and Method: Hyposalivation (group H) was induced through bilateral submandibulectomy. Periodontitis (group EP) was induced by injecting LPS (1 mg/ml) into the gingiva of the first lower molars. A third group was subjected to both conditions (group H+EP). Alveolar bone loss was evaluated by micro-computed tomography and histomorphometric analysis, and gingival inflammatory mediators were assessed by specific techniques. Biomechanical properties were evaluated in mandible., Results: Alveolar bone loss increased similarly in groups H, EP and H+EP compared to control. Metalloproteinase (MMP2 and MMP9) activity was similar in H and control, but higher in groups EP and H+EP (MMP2: C 9644+2214, EP 34441+3336, H 5818+1532, H+EP 42673+3184; MMP9: C 5792+961, EP 14807+861, H 9295+520, H+EP 4838+1531). The rest of the inflammatory mediators evaluated increased in groups H, EP and H+EP to a greater or lesser extent with respect to the control, although in most cases, they were higher in groups EP and H+EP than in group H. The biomechanical properties of the mandible increased in group H compared to the other three groups., Conclusions: Both hyposalivation and periodontitis cause periodontal damage, but hyposalivation also produces biomechanical alterations, causing more extensive deleterious effects than periodontitis., Competing Interests: The authors declare no potential conflicts of interest regarding the research, authorship, and/or publication of this article., (Copyright© 2024 Sociedad Argentina de Investigación Odontológica.)

Published

2024

2. Effect of fried sunflower oil intake on mandibular biomechanical competence of growing rats.

Author

Macri EV, Bozzini C, Ferreira-Monteiro AG, Rodriguez PN, Lifshitz F, Miksztowicz VJ, and Friedman SM

Subjects

Rats, Animals, Male, Sunflower Oil, Rats, Wistar, Diet, Mandible

Abstract

Previous studies by us demonstrated that the consumption of thermally oxidized oil diet adversely affects body growth, lipid metabolism, bone mass and femur biomechanical competence., Aim: The aim of this study was to evaluate the effects of a diet containing fried sunflower oil on the mandible of growing rats., Materials and Method: Male Wistar rats (21±1 day old) (n=21) were assigned at weaning to one of three diets for 8 weeks: a control diet (C), a diet containing sunflower oil (SFO) or a diet containing sunflower oil that had been repeatedly heated (SFOx); both SFO and SFOx were mixed with commercial rat chow at 13% (w/w). The consistency and viscosity of the 3 diets were similar. Zoometrics and food intake were recorded weekly. At wk=8, mandibular growth was assessed by measurements of anatomical points of cleaned bones, and mandible biomechanical competence was assessed to estimate the structural properties of the bone. Statistical analysis was performed by SPSS v. 20.0., Results: Rats fed SFOx diet attained the lowest final body weight (P=0.0074), mandibular weight (P=0.0001) and mandibular \length (P=0.0002). Load bearing capacity (Wf;N), load of yielding (Wy;N) and stiffness (Wy/dy;N/mm) of the mandible were negatively affected by both sunflower oil diets (fresh and fried) (P=0.001; P=0.002; P=0.003, respectively) though SFOx induced the most significant reduction in Wy/dy (C:44.4(5.4) > SFO:36.1(2.1) > SFOx: 26.3(3.7) N/ mm; P=0.003). The deleterious effect of SFOx on mandibular growth was more accentuated on the posterior part of the bone (C:11.4(0.3)=SFO:11.2(0.2)>SFOx: 10.7(0.2) mm; p=0.0005); the anterior/ posterior ratio (C:1.25(0.02)=SFO:1.27(0.02)

Published

2023

3. Mandibular biomechanical behavior of rats submitted to chronic intermittent or continuous hypoxia and periodontitis.

Author

Terrizzi AR, Rugolo G, Bozzini C, Conti MI, Fernández-Solari J, and Martínez MP

Subjects

Alveolar Bone Loss etiology, Animals, Biomechanical Phenomena, Dinoprostone analysis, Female, Gingiva chemistry, Hypoxia physiopathology, Nitric Oxide Synthase Type II metabolism, Periodontitis physiopathology, Periodontium physiopathology, Rats, Rats, Wistar, Weight-Bearing, Hypoxia complications, Mandible physiopathology, Periodontitis complications

Abstract

Background: The aim of this study was to investigate the effects of exposure to continuous (CH) and intermittent (IH) hypoxia on biomechanical properties of the mandible and periodontal tissue of animals submitted to experimental periodontitis (EP) when applying loads in a hypoxic environment., Methods: Adult female Wistar rats were exposed during 90 days to IH or CH (simulated high altitude of 4200 m above sea level). Fourteen days prior to the euthanasia, EP was induced to half of the animals of each group., Results: Only in the rats with EP, IH decreased the maximum capacity of the mandible to withstand load and the limit of elastic load. Indicators of intrinsic properties of the bone material were significantly reduced by both types of hypoxia in rats with EP. Hypoxia enhanced the alveolar bone loss induced by EP in the buccal side of the mandible, without showing additional effects in lingual or interradicular bone. Hypoxia increased prostaglandin E 2 content in gingival tissue of healthy animals and further elevated the E 2 levels increased by EP., Conclusions: When periodontitis is present, hypoxic stress induces a decrease in mineral properties that ultimately affects the ability of the mandible to resist load, mainly during intermittent exposure to hypoxia. These effects on bone may be related to the higher levels of prostaglandin E 2 reached in the surrounding gingival tissue. The findings of this study may stimulate strategies to prevent unwanted effects of hypoxia on periodontal tissues.

Published

2021

4. Mechanical mandible competence in rats with nutritional growth retardation.

Author

Lezón CE, Pintos PM, Bozzini C, Romero AA, Casavalle P, Friedman SM, and Boyer PM

Subjects

Animals, Biomarkers, Biomechanical Phenomena, Body Weight, Disease Models, Animal, Dose-Response Relationship, Drug, Elasticity, Male, Mandible physiopathology, Organ Size drug effects, Random Allocation, Rats, Rats, Wistar, Adrenergic beta-Antagonists pharmacology, Bone Diseases, Developmental physiopathology, Food Deprivation physiology, Mandible drug effects, Mandible growth & development, Propranolol pharmacology, Sympathetic Nervous System physiopathology

Abstract

Objective: In order to provide a better understanding of the sympathetic nervous system as a negative regulator of bone status, the aim of the study was to establish the biomechanical mandible response to different doses of a β-adrenergic antagonist such as propranolol (P) in a stress-induced food restriction model of growth retardation., Methods: Rats were assigned to eight groups: Control (C), C+P3.5 (CP3.5), C+P7 (CP7), C+P14 (CP14), NGR, NGR+P3.5 (NGRP3.5), NGR+P7 (NGRP7) and NGR+P14 (NGRP14). C, CP3.5, CP7 and CP14 rats were freely fed with the standard diet. NGR, NGRP3.5, NGRP7 and NGRP14 rats received, for 4 weeks (W4), 80% of the amount of controls food consumed. Propranolol 3.5, 7 and 14mg/kg/day was injected ip 5days per week in CP3.5 and NGRP3.5, CP7 and NGRP7, CP14 and NGRP14, respectively. At W4, zoometry, mandible morphometry, static histomorphometric and biomechanical competence were performed., Results: A dose of Propranolol 7mg/kg/day induced interradicular bone volume accretion reaching a mandible stiffness according to chronological age., Conclusion: These findings evidenced that sympathetic nervous system activity is a negative regulator of mandible mechanical competence in the nutritional growth retardation model. Propranolol 7mg/kg/day, under the regimen usage, seems to be appropriate to blockade SNS activity on mandible mechanical performance in NGR rats, probably associated to an effect on bone mechanostat system ability to detect disuse mode as an error., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

5. Effect of dexamethasone on mandibular bone biomechanics in rats during the growth phase as assessed by bending test and peripheral quantitative computerized tomography.

Author

Bozzini C, Champin G, Alippi RM, and Bozzini CE

Subjects

Animals, Biomechanical Phenomena, Bone Density, Dexamethasone, Female, Rats, Tomography, Mandible

Abstract

Long-term glucocorticoid administration to growing rats induces osteopenia and alterations in the biomechanical behavior of the bone. This study was performed to estimate the effects of dexamethasone (DTX), a synthetic steroid with predominant glucocorticoid activity, on the biomechanical properties of the mandible of rats during the growth phase, as assessed by bending test and peripheral quantitative computed tomographic (pQCT) analysis. The data obtained by the two methods will provide more precise information when analyzed together than separately. Female rats aged 23 d (n=7) received 500μg.kg-1 per day of DXT for 4 weeks. At the end of the treatment period, their body weight and body length were 51.3% and 20.6% lower, respectively, than controls. Hemimandible weight and area (an index of mandibular size) were 27.3% and 9.7% lower, respectively. The right hemimandible of each animal was subjected to a mechanical 3-point bending test. Significant weakening of the bone, as shown by a correlative impairment of strength and stiffness, was observed in experimental rats. Bone density and cross-sectional area were measured by pQCT. Cross-sectional, cortical and trabecular areas were reduced by 20% to 30% in the DTX group, as were other cortical parameters, including the bone density, mineral content and cross-sectional moment of inertia. The "bone strength index" (BSI, the product of the pQCT-assessed xCSMI and vCtBMD) was 56% lower in treated rats, which compares well with the 54% and 52% reduction observed in mandibular strength and stiffness determined through the bending test. Data suggest that the corticosteroid exerts a combined, negative action on bone geometry (mass and architecture) and volumetric bone mineral density of cortical bone, which would express independent effects on both cellular (material quality) and tissue (cross-sectional design) levels of biological organization of the skeleton in the species.

Published

2015

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

Author

Bozzini CE, Champin GM, Alippi RM, and Bozzini C

Subjects

Analysis of Variance, Animals, Case-Control Studies, Elastic Modulus, Female, Mandible chemistry, Rats, Rats, Sprague-Dawley, Stress, Mechanical, Animal Feed adverse effects, Bone Development physiology, Caseins, Dietary Proteins adverse effects, Glutens adverse effects, Mandible growth & development

Abstract

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 (Young's 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., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2013

7. Growth inhibition in rats fed inadequate and incomplete proteins: repercussion on mandibular biomechanics.

Author

Bozzini C, Champin GM, Bozzini CE, and Alippi RM

Subjects

Animals, Biomechanical Phenomena, Female, Rats, Rats, Sprague-Dawley, Bone Development, Dietary Proteins administration & dosage, Mandible physiopathology, Protein Deficiency physiopathology

Abstract

This study describes the effects of feeding growing rats with a diet containing inadequate and incomplete proteins on both the morphological and the biomechanical properties of the mandible. Female rats aged 30 d were fed freely with one of two diets, control (CD, 301 Cal/100g) and experimental (ED, 359 Cal/100g). CD was a standard laboratory diet, while ED was a synthetic diet containing cornflower supplemented with vitamins and minerals. Both diets had the same physical characteristics. Control (C) and experimental (E) animals were divided into 4 groups of 10 animals each. C40 and E40 rats were fed CD and ED, respectively, for 40 d; C105 were fed the CD for 105 d; and E105 were fed the ED for 40 d and then the CD for the remainder of the experimental period (65 d). Mandibular growth was estimated directly on excised and cleaned bones by taking measurements between anatomical points. Mechanical properties of the right hemimandible were estimated by using a 3-point bending test to estimate the structural properties of the bone. Geometric properties of both the entire bone and the cross-section were determined. Bone material properties were calculated from structural and geometric properties. The left hemimandibles were ashed and the ash weight obtained. Rats fed the ED failed to achieve normal body weight gain. Complete catch-up was observed at the end of nutritional rehabilitation. Mandibular weight and length were negatively affected by the ED, as were the cross-sectional area, the mineralized cortical area, and the cross-sectional moment of inertia. All of these parameters showed incomplete catch-up. The structural bone mechanical properties indicative of strength and stiffness were negatively affected. Intrinsic material properties, as assessed by the modulus of elasticity and maximal elastic stress, were within normal values. In summary, the experimental bone was weaker than the control and structurally incompetent. The bone considered was smaller than the control bone, showing a significant reduction in the cross-sectional area and the moment of inertia. However, material properties as well as the ash fraction and degree of mineralization were similar in E and C bones. Therefore, the E bone was weaker than the C bone because of its smaller bone mass, which appears to have been negatively influenced by the ED in relation to its effects on overall body mass.

Published

2013

8. Lead bone toxicity in growing rats exposed to chronic intermittent hypoxia.

Author

Conti MI, Bozzini C, Facorro GB, Lee CM, Mandalunis PM, Piehl LL, Piñeiro AE, Terrizzi AR, and Martínez MP

Subjects

Animals, Bone Density drug effects, Bone and Bones drug effects, Bone and Bones physiology, Femur drug effects, Growth Plate, Hypoxia veterinary, Male, Mandible drug effects, Rats, Tibia, Bone Development drug effects, Environmental Pollutants toxicity, Femur growth & development, Lead toxicity, Mandible growth & development

Abstract

Lead chronic intoxication under hypoxic conditions revealed growth retardation in growing rats and damages on femoral and mandibular bones that predispose to fractures. These findings aimed us to investigate if bone material and geometric properties, bone mass in terms of histomorphometry or antioxidant capacity are also impaired in such experimental model. Combined treatments significantly reduced hemimandible cross sectional geometry and intrinsic stiffness (-16% and -34%); tibia and hemimandible bone volume (-45% and -40%) and growth plate cartilage thickness (-19%). These results show a previously unreported toxic effect of lead on mandible however, longer studies should be necessary to evaluate if an adaptation of bone architecture to maintain structural properties may occur and if the oxidative stress can be identified as the primary contributory agent in the pathogenesis of lead poisoning.

Published

2012

9. Bone mineral density and bone strength from the mandible of chronically protein restricted rats.

Author

Bozzini CE, Champin G, Alippi RM, and Bozzini C

Subjects

Animals, Biomechanical Phenomena, Chronic Disease, Diet, Protein-Restricted, Female, Rats, Rats, Wistar, Bone Density, Mandible physiopathology, Protein Deficiency physiopathology

Abstract

Unlabelled: The present investigation was performed to assess the biomechanical repercussion of protein malnutrition imposed on rats between the 26th and 135th days of postnatal life on the mandible, which is not a weight-bearing bone but supports the loads related to the masticatory activity. Female Wistar rats aged 26 d (n = 14) were placed on either a 4%-protein diet (ICN 960254, P4 group) or a 20%-protein diet (ICN 960260, P20 group) and killed 111 d later. Both body weight and length were recorded regularly. The mandibles were dissected and cleaned of adhering soft tissue. Mandibular growth was estimated directly by taking measurements between anatomical points. Areal Bone Mineral Density (BMD) was estimated using a bone densitometer (LUNAR DPX-L). Mechanical properties of the right hemimandible were determined using a three-point bending mechanical test to obtain the load/deformation curve and estimate the structural properties of the bone. Results were summarized as means +/- SD. Comparisons between parameters were performed by Student's t test. A 75% reduction in body weight and a 32% reduction in body length were observed in P4 rats. Like body size, mandibular weight, length, height and area (index of mandibular size) were negatively affected by P4 diet, as was the posterior part of the bone (posterior to molar III). The anterior part (alveolar and incisor alveolar process) was not affected by age or diet. The "load capacity" extrinsic properties of the mandible (load fracture, stiffness, yielding point) were between 43% and 64% of control value in protein restricted rats. BMD was similar in both groups of animals., Conclusion: 1) Chronic protein malnutrition imposed on rats from infancy to early adulthood reduces the growth of the posterior part of the mandible without inducing changes in the anterior part, which produces some deformation of the bone in relation to age-matched rats; and 2) the significant reduction of strength and stiffness of the mandible seem to be the result of an induced loss of gain in bone structural properties as a consequence of a correlative loss of gain in both growth and mass, yet not in bone material properties.

Published

2011

10. Permanent reduction of mandibular size and bone stiffness induced in post-weaning rats by cyclophosphamide.

Author

Olivera MI, Martínez MP, Conti MI, Bozzini C, Bozzini CE, and Alippi RM

Subjects

Age Factors, Animals, Animals, Newborn, Elasticity drug effects, Female, Growth Disorders chemically induced, Mandible anatomy & histology, Organ Size drug effects, Rats, Rats, Sprague-Dawley, Antineoplastic Agents, Alkylating adverse effects, Bone Density drug effects, Cyclophosphamide adverse effects, Mandible drug effects

Abstract

It has been previously reported that several doses of cyclophosphamide (CPA) reduce body weight gain, diaphyseal torsional strength and longitudinal femoral growth in the growing rat. The present study was thus designed to estimate both the initial and the possible long-term effects of CPA treatment, by analyzing mandibular dimensions and biomechanical performance of the bone in adulthood in rats treated with the drug around weaning. Female Sprague-Dawley rats (N=20), 26 d of age, received 100mg/kg of CPA by the intraperitoneal route during days 0, 7 and 21 of the experimental period. Controls (C) received saline. Groups of rats were sacrificed at day 28 to estimate initial changes induced by the drug and on day 126 in order to determine long-term effects. The dimensions of the excised mandibles were measured directly between anatomical points; the geometry and material biomechanical quality of mandibular bone were assessed using a three-point bending mechanical test in an Instron Universal Testing Machine model 4442. CPA reduced body weight, body length and mandibular size (posterior part of the bone) significantly, when the parameters were measured at day 28. They did not recover with time, which means that catch-up growth did not occur and that the overall growth of the body was permanently affected by the drug. CPA treatment was also associated with a marked depression of the natural increase in the mandibular bone mass (cross-sectional area). The bending cross-sectional moment of inertia of the fracture sections (xCSMI) was also negatively affected by treatment. Significant decreases of both ultimate load and stiffness were also observed. The above structural parameters did not recover enough with time to attain control values at the end of the study. The intrinsic stiffness (E) of the mandibular bone was not affected by treatment. These findings suggest that CPA treatment during early postnatal life causes permanent changes in mandibular morphology and affects the adaptation of mandibular bone architecture to body growth, thus not allowing complete compensation at the end of the study because of an inadequate distribution of the resistive material through its cross-section rather than a qualitative impairment of cortical bone.

Published

2009

11. Mandibular bone stiffening and increased bone calcium mass in rats permanently stunted by hypophysectomy.

Author

Alippi RM, Olivera MI, Bozzini C, Mandalunis P, and Bozzini CE

Subjects

Animals, Biomechanical Phenomena, Biometry methods, Bone Density physiology, Elasticity, Female, Hypophysectomy, Mandible metabolism, Mandible physiology, Rats, Rats, Sprague-Dawley, Calcium metabolism, Mandible growth & development, Pituitary Gland physiology

Abstract

Objective: This investigation was designed to obtain information on the changes induced by hypophysectomy on biometric parameters, bone calcium mass, and material and architectural properties during ontogenesis of the rat mandible., Design: Female Sprague-Dawley rats were hypophysectomised (HX) at 30 days of age. A "basal control group" (BC) was sacrificed on the same day surgery was performed. An "age-matched intact control group" (CON) was also included. HX and CON rats were sacrificed when aged 6 months. Body weight was monitored weekly. Mandibular growth was estimated directly on the right hemimandible by taking measurements between stable anatomical points. Its mechanical properties were determined using a three-point bending mechanical test. Load was applied transversely to the bone axis at a point immediately posterior to the posterior surface of the third molar. The left hemimandibles were ashed in a muffle furnace at 600 degrees C for 18h and the ash weight obtained. Calcium content in the ashes was determined by atomic absorption spectrophotometry. It was taken as the mandibular calcium mass. Histomorphometric studies were performed on decalcified hemimandibles: total interradicular bone, bone volume, and height of the periodontal ligament were measured., Conclusions: Morphometric studies indicated that hypophysectomy in juvenile rats induced mandibular growth cessation, which was limited to the posterior part of the bone. Thus, the mandible maintained its juvenile proportions and showed an important deformation relative to age. In spite of the reduced bone size, both the mandibular weight and the calcium bone mass increased more than two times in ontogenia. Histomorphometric studies revealed that the interradicular bone volume was markedly increased. These findings strongly suggest that the bone that forms the mandible of the hypophysectomised rat under the conditions of the present study showed a higher than normal density. As evidenced from biomechanical studies, these bone properties, plus the significant stiffening of bone material tissue, were presumably responsible for the unnecessary and marked increment in the "load capacity" suffered by the mandible of the hypophysectomised rat during ontogenesis.

Published

2006

12. The development of bone mass and bone strength in the mandible of the female rat.

Author

Olivera MI, Bozzini C, Meta IF, Bozzini CE, and Alippi RM

Subjects

Aging physiology, Animals, Animals, Newborn growth & development, Elasticity, Female, Mandible anatomy & histology, Mandible growth & development, Rats, Rats, Wistar, Tensile Strength, Bone Development, Mandible physiology

Abstract

The present study provides baseline data for a number of mandibular growth dimensions, specially on bone mass and bone strength, that were collected between the 21st and the 180th days of postnatal life, which are intended as a reference for researchers designing experimental studies, specially on mandibular catch-up growth, and as an aid for clinicians who must evaluate results from published animal studies for validity and potential extrapolation to the human clinical situation. Fifty weanling female Wistar (Hsd:Wi) rats were fed ad libitum a diet previously shown to allow normal, undeformed mandibular growth. Five of them were randomly selected at different times between 21 and 180 d of life. Mandibular growth was estimated directly on the right hemimandible by taking measurements between anatomical points; mandibular bone mass (calcium mass) was estimated from the mg of calcium, determined by atomic absorption spectrophotometry, present in the ashes of the left hemimandible; and mechanical properties of the right hemimandible were determined using three-point bending mechanical test. Dimensions, bone calcium mass and bone strength of the female rat mandible increased linearly from day 21 to approximately day 90. Bone growth, as expected, was more than twice when assessed from bone weight than when derived from mandibular area, length or height when the parameters were expressed as the relative increase from the mean infant condition. The growth rate of the posterior part of the mandible (behind the third molar) was almost five times greater than that of the anterior part. The rates of growth of the studied parameters showed a marked decline after day 90. ANOVA indicated that no statistical differences were found between day 90 and day 120 values. It could be concluded that the female rat mandible attains its adult size, peak bone calcium mass and bone structural mechanical properties at some point between 90 and 120 d of postnatal life. Because of the extremely high positive correlation between mandibular bone calcium mass and both mandibular area and mandibular weight, it was possible to calculate the mandibular peak bone mass from the relations 7.69 mgCa/cm2 and 0.19 mgCa/mg bone.

Published

2003

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

Author

Alippi RM, Meta MD, Olivera MI, Bozzini C, Schneider P, Meta IF, and Bozzini CE

Subjects

Analysis of Variance, Animals, Animals, Newborn, Biomechanical Phenomena, Body Constitution, Body Weight, Bone Density physiology, Diet, Protein-Restricted adverse effects, Dietary Proteins administration & dosage, Female, Lactation physiology, Male, Mandible pathology, Mandible physiopathology, Pregnancy, Protein-Energy Malnutrition pathology, Rats, Rats, Wistar, Statistics as Topic, Stress, Mechanical, Tomography, X-Ray Computed, Weaning, Mandible growth & development, Protein-Energy Malnutrition physiopathology

Abstract

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.

Published

2002

14. Bone growth in nonorganic nutritional dwarfing rats.

Author

Boyer PM, Friedman SM, Olivera MI, Bozzini C, Norese MF, and Rodríguez PN

Subjects

Animals, Dwarfism physiopathology, Energy Intake, Femur growth & development, Male, Rats, Rats, Wistar, Weaning, Bone Development, Mandible growth & development, Protein-Energy Malnutrition physiopathology

Abstract

Since no data are available to characterize mandibular growth in nonorganic nutritional dwarfing (ND), the purpose of the present study was to describe the effects of a diet on mandible and femur growth in a nutritional dwarfish animal model. Male Wistar rats were divided into two groups of 10 animals each: Control (C) and Experimental (E80: diet-restricted group). C rats were fed a standard diet ad libitum. E80 rats received 80% of the amount of standard diet eaten by group C. Food intake and body weight (Wt) and length (Lt) were recorded periodically. Growth data (Wt and Lt) were expressed as a Z-score of weight-for-length (WLZ) ratio, an index of body size. Five animals of each group were selected at random at 4 and 8 weeks and sacrificed. Additionally at t = 0, 5 animals were sacrificed for baseline measurements. Mandibular growth was estimated directly on the right mandible by measuring ten dimensions. Femur growth was estimated from Wt and Lt measurements of the bone. Mandibular weight, area, length and height were negatively affected by dietary restriction during the first 4 weeks of the experimental period. Mandibular growth ceased after this point. Dimensions corresponding to the alveolar unit did not change with time. However, all other dimensions were negatively influenced but not to the same extent. Femur rather than mandibular weight was severely affected. Therefore, the negative effects of the nutritional stress that occurs after weaning would be stronger for the femur, than for the mandible. Femur length was also negatively affected by suboptimal nutrition. In summary, the results of the present study showed that mandible and femur growth respond differently to mild chronic food restriction. These observations could be explained in terms of the different critical bone growth periods and of the time at which nutritional stress was imposed.

Published

2000

15. Catch-up in mandibular growth after short-term dietary protein restriction in rats during the post-weaning period.

Author

Alippi RM, Meta MD, Boyer PM, and Bozzini CE

Subjects

Age Factors, Alveolar Process anatomy & histology, Alveolar Process growth & development, Analysis of Variance, Animals, Cephalometry, Dietary Proteins therapeutic use, Male, Mandible anatomy & histology, Nutrition Disorders therapy, Random Allocation, Rats, Rats, Wistar, Time Factors, Weaning, Diet, Protein-Restricted, Dietary Proteins administration & dosage, Mandible growth & development, Nutrition Disorders physiopathology

Abstract

Catch-up growth has been defined as growth with a velocity above the statistical limits of normality for age during a defined period of time which follows a period of impaired growth. Since no data are available on catch-up in mandibular growth, the present study was designed to estimate the dynamics of the mandibular size after short-term dietary protein restriction in rats during the post-weaning period. Weanling male rats, 22 d of age, were divided into two groups, control (C) and experimental (E). E rats were fed a protein-free diet during the first 10 d; from this time on, they were placed on a 20% protein diet, as were C rats during the entire experimental period, which lasted 70 d. Five rats from both groups were randomly selected every 10 d and sacrificed. Mandibular growth was estimated directly on the right mandible by measuring several dimensions (mandibular area, base length, mandibular height, mandibular length, alveolar length and incisor alveolar process length). Alveolar and incisor alveolar process lengths did not change with age or dietary protein. All other dimensions increased with age and were thus negatively affected by protein restriction. After growth restriction ceased, the rate of increase of all affected dimensions was above normal values and deficits were swiftly eliminated. Since age-independent dimensions compose roughly the anterior portion of the mandible, this portion of the bone was not affected by protein restriction. It was, thus, the posterior part of the mandible which stopped growth during the nutritional insult and showed catch-up during nutritional rehabilitation. In summary, the rat mandible has a high potential for catch-up during the post-weaning period, showing the ability to achieve complete catch-up in about 30 d.

Published

1999

16. Additive effects of dietary protein and energy deficiencies on mandibular growth in the weanling rat.

Author

Bozzini C, Alippi RM, Leal TL, Olivera MI, and Bozzini CE

Subjects

Analysis of Variance, Animals, Dietary Proteins, Energy Intake, Male, Rats, Rats, Sprague-Dawley, Statistics, Nonparametric, Growth Disorders etiology, Mandible growth & development, Protein-Energy Malnutrition complications

Abstract

Dietary protein restriction adversely affects mandibular growth in the weanling rat. Protein deficiency is usually accompanied by reduced food intake which, in turn, induces energy deficiency. The present study was thus designed to dissociate the effects of dietary protein and energy deficiencies on the growth of the mandible in rapidly growing rats. Four groups of Sprague-Dawley rats aged 30 days were fed a normal diet, a low-energy diet, a low protein diet, and a low-protein and low-energy diet for 20 days. Rats were sacrificed at the end of experimental period and body weight and mandibular dimensions were recorded to evaluate body growth and mandibular growth. The growth of the mandible was affected almost in the same order of magnitude by both protein and energy restrictions. When both were applied together, mandibular growth was even more severely affected. Two way analysis of variance revealed the absence of synergism between variables, indicating that the negative effects of dietary protein and energy restrictions on mandibular growth could be considered to be additive.

Published

1994

17. Mandibular growth retardation in growing rats chronically exposed to hypobaria.

Author

Bozzini CE, Alippi RM, and Barcelo AC

Subjects

Animals, Biometry, Body Weight, Eating, Growth Disorders pathology, Male, Mandible pathology, Mandibular Diseases etiology, Mandibular Diseases pathology, Rats, Rats, Inbred Strains anatomy & histology, Altitude, Atmospheric Pressure, Growth Disorders etiology, Mandible growth & development

Abstract

Weanling male Wistar rats aged 21 days were divided into three groups: initial control, normobaric, and hypobaric (C, N, and H, respectively). C rats were killed three days after being weaned. H rats were placed into an altitude chamber and maintained at 456 mb (6100 m) for 14 days. N rats were maintained at sea-level conditions. Body weight, body and tail lengths, and food intake were recorded every day. Animals were killed at the end of the experimental period, and four linear dimensions of the dried mandible were measured. The amount of food eaten by the H rats during the entire exposure period was 54.6% of that consumed by N ones. Body weight gain in H rats was 32.7% of that seen in N rats. Body length was 49.0% and tail length was 56.6% of normal. All mandibular dimensions were significantly reduced in H rats when compared with N rats and were, in general, in close relation with the reduction observed in skeletal growth. Only one dimension was reduced out of proportion, which indicates some deformation of the mandible. The average daily caloric intake related to metabolic body weight (body weight 0.75) of H rats was 60% of the N value. Efficiency of protein utilization for growth was not significantly different between both groups of rats. These results indicate that chronic exposure to hypobaria induces overall skeletal and mandibular growth retardation, which appears to be the result of a diminution in food intake because of decreased appetite.

Published

1987

18. Effect of prenatal ethanol exposure on the growth of rat mandible skeletal units.

Author

Giglio MJ, Vieiro M, Friedman S, and Bozzini CE

Subjects

Animals, Birth Weight drug effects, Body Weight drug effects, Cephalometry, Dietary Carbohydrates administration & dosage, Energy Intake, Female, Mandible anatomy & histology, Mandible drug effects, Pregnancy, Rats, Rats, Inbred Strains, Starch administration & dosage, Ethanol pharmacology, Mandible growth & development, Prenatal Exposure Delayed Effects

Abstract

To study the effect of prenatal ethanol exposure on the growth of the skeletal units of the rat mandible, female Sprague-Dawley rats weighing 220-240 g were assigned to 1 of 3 different groups. One of the groups received ethanol in the drinking water (up to 10% v/v) for at least 15 days prior to mating, then 20% (v/v) throughout gestation. A balanced diet was supplied ad libitum. A second group was pair-fed with the first group. In addition, an amount of corn starch calorically equivalent to the amount of ethanol consumed by that group was offered. The remaining group formed the normal control and received food and water ad libitum. All groups were offered food and water ad libitum after delivery. Total caloric intakes in the first 2 groups. were 67.8% of that of the normal control group. The average off-spring weight at birth for rats given ethanol was 17% lower than that of normal control rats. There was no significant difference between the average weights of the offspring of pair-fed and normal control rats. During the ensuing 3 weeks, the weight of the offspring of alcoholic rats showed no indication of catching-up. All skeletal units of the mandible of the offspring of ethanol-treated females differed significantly from those of the control group. These differences varied between 2% and 16%. The skeletal units of mandibles of the pair-fed group did not differ significantly from ad libitum controls. The mandibular width was similar in all 3 experimental groups.

Published

1987

19. The concentration of dietary casein required for normal mandibular growth in the rat.

Author

Bozzini C, Barcelo AC, Alippi RM, Leal TL, and Bozzini CE

Subjects

Animals, Body Weight, Male, Mandible anatomy & histology, Organ Size, Rats, Rats, Inbred Strains, Caseins administration & dosage, Dietary Proteins administration & dosage, Mandible growth & development

Abstract

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.

Published

1989

20. Effect of protein-free diet on growth of the skeletal units of the rat mandible.

Author

Alippi RM, Barcelo AC, Bardi M, Friedman SM, Rio ME, and Bozzini CE

Subjects

Animals, Caseins administration & dosage, Dietary Proteins administration & dosage, Male, Rats, Rats, Inbred Strains, Mandible growth & development, Protein Deficiency physiopathology, Protein-Energy Malnutrition physiopathology

Published

1984