Aging and Dietary Modulation of Rat Skeleton and Parathyroid Hormone*

Kalu, Dike N.; Hardin, Robert H.; Cockerham, Richard; Yu, Byung P.

doi:10.1210/endo-115-4-1239

Cited by 78 publications

(25 citation statements)

References 18 publications

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“…The greater increase in the SSI values of long bones and the change in first lumbar vertebra might be due to these morphological changes. This might be related to almost no change in organic components with increasing age [11,[13][14]. The age when rats show the so-called peak of bone mass in the whole skeleton was not clearly determined from the results obtained in this study.…”

Section: Discussionmentioning

confidence: 77%

“…According to previous studies, the high BMD or calcium content of the first and fourth lumbar vertebrae, femur, and tibia coincided with a high testosterone level at the age of 12 months in male Wistar rats [11,14,17]. On the other hand, no change in the BMD of the femur measured by DEXA in male rats was observed after the rats had reached maturity [19].…”

Section: Discussionmentioning

confidence: 87%

See 1 more Smart Citation

Age-Related Changes in Bone Mineral Density, Cross-Sectional Area and Strength at Different Skeletal Sites in Male Rats.

Iida¹,

Fukuda²

2002

J. Vet. Med. Sci.

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ABSTRACT. Age-related changes in bone mineral density (BMD), cross-sectional area and strength strain index (SSI) of the long bones in the limbs and first lumbar vertebra of male Wistar rats were measured by a peripheral quantitative computed tomography (pQCT) method. One hundred and ten rats aged 2-30 months were used. The results indicate that the total (cortical + trabecular), cortical and trabecular BMD values of the metaphysis and cortical BMD values of the diaphysis in the long bones varied for each bone and differed from those of the first lumbar vertebra. The total BMD of long bones showed high values at 6-21 months and then decreased, but these did not always coincide with cortical and trabecular BMD. The values of SSI in the long bones varied. The values of total and cortical BMD and SSI of lumbar vertebra increased for 6-12 months and then decreased, but the trabecular BMD increased after 12 months. The total area in both the long bones and the first lumbar vertebra increased with the decrease in cortical area and the increase in the trabecular area with increasing age. It was concluded that age-related changes in bones, similar to those observed in humans, could be observed in some bones and parameters, although the age in rats when the so-called peak bone mass appears in the whole skeleton could not be clearly determined. KEY WORDS: age change, bone mineral density, male rat, peak bone mass, peripheral quantitative computed tomography (pQCT) J. Vet. Med. Sci. 64(1): 29-34, 2002 Rats are widely used for studies on bone metabolism and diseases such as osteoporosis, although their worth as an animal model has been contested [6,12,16,21] because their bone morphological patterns differ from those of humans. Rats show a modeling pattern from youth to old age, while humans show a modeling pattern in the growth stage which changes to a remodeling pattern after maturity [7]. The length and weight of long bones in rats continue to increase up to the old age due to the fact that both or either of the epiphysial growth plates do not close for a long time [8]. The cortical and trabecular bone components of the femur neck in rats have been found to be higher and lower, respectively, than those in humans [3].The age of peak bone mass, hereafter referred to as bone mineral density, in a human is considered a significant indicator for knowing the state of activity of bone metabolism and age of onset of osteoporosis, because thereafter the bone mass reduces with increasing age. To clarify whether rats show peak bone mass or not is an important matter for considering their worth as a model animal in bone researches and for determining corresponding ages between rats and humans in experimental procedures and assessing experimental results. That is, we are interested to know if rats have age-related changes in bone metabolism throughout their life similar to those in humans. We demonstrated that high values of mineral and organic contents at various skeletal sites are present in rats [11] and a peak of bone volume i...

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Section: Discussionmentioning

confidence: 77%

Section: Discussionmentioning

confidence: 87%

Age-Related Changes in Bone Mineral Density, Cross-Sectional Area and Strength at Different Skeletal Sites in Male Rats.

Iida¹,

Fukuda²

2002

J. Vet. Med. Sci.

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“…brain maturation could be compared at similar ages in calorically restricted and normal model organisms. In support of this view, the effects of caloric restriction show a decrease in the normal rate of maturation in both rodents (Kalu et al, 1984;Merry & Holehan, 1981) and rhesus monkeys (Mattison et al, 2003). Interestingly, caloric restriction seems to have reduced effects on longevity if applied after middle age, i.e.…”

Section: Caloric Restrictionmentioning

confidence: 85%

Aging mechanism as the “down side” of adaptation: A network approach

Borup¹,

Trusina²,

Andersson³

2008

Journal of Theoretical Biology

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Many diverse hypotheses on aging are in play. All from "aging genes" over decreasing telomere length to increased level of gene mutations has been suggested to determine an organism's lifespan, but no one unifying theory exists. As part of a growing interest towards more integrative approaches in the field we propose a simplistic model based on the "useit-or-lose-it" concept: we hypothesize that biological aging is a systemic property and the down side of adaptation in complex biological networks at various levels of organization: from brain over the immune system to specialized tissues or organs. The simple dynamical model undergoes three phases during its lifetime: 1. General plasticity (childhood), 2. Optimization/adaptation to given conditions (youth and adolescence) and 3. Steady state associated with high rigidity (aging). Furthermore, our model mimics recent data on the dynamics of the immune system during aging and, although simplistic, thus captures some essential characteristics of the aging process. Finally, we discuss the abstract model in relation to current knowledge on aging and propose experimental set-ups for testing some of the theoretical predictions.

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“…The earliest study (McCay et al 1935) found that femurs removed from restricted (R) rats crumbled during dissection; however, the level of CR makes it likely that these animals were suffering from nutritional deficiencies. Later studies by Kalu et al (1984aKalu et al ( , b, 1988 in F344 rats under a less severe restriction found that CR resulted in delayed epiphyseal closure, bones of lower density, and no reduction in femur density in old age. Results from more recent rodent studies have been variable.…”

Section: Introductionmentioning

confidence: 95%

Skeletal effects of long-term caloric restriction in rhesus monkeys

Colman

Beasley

Allison

et al. 2011

AGE

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Age-related bone loss is well established in humans and is known to occur in nonhuman primates. There is little information, however, on the effect of dietary interventions, such as caloric restriction (CR), on age-related bone loss. This study examined the effects of long-term, moderate CR on skeletal parameters in rhesus monkeys. Thirty adult male rhesus monkeys were subjected to either a restricted (R, n0 15) or control (C, n015) diet for 20 years and examined throughout for body composition and biochemical markers of bone turnover. Total body, spine, and radius bone mass and density were assessed by dualenergy X-ray absorptiometry. Assessment of biochemical markers of bone turnover included circulating serum levels of osteocalcin, carboxyterminal telopeptide of type I collagen, cross-linked aminoterminal telopeptide of type I collagen, parathyroid hormone, and 25(OH)vitamin D. Overall, we found that bone mass and density declined over time with generally higher levels in C compared to R animals. Circulating serum markers of bone turnover were not different between C and R with nonsignficant diet-by-time interactions. We believe the lower bone mass in R animals reflects the smaller body size and not pathological osteopenia.

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Aging and Dietary Modulation of Rat Skeleton and Parathyroid Hormone*

Cited by 78 publications

References 18 publications

Age-Related Changes in Bone Mineral Density, Cross-Sectional Area and Strength at Different Skeletal Sites in Male Rats.

Age-Related Changes in Bone Mineral Density, Cross-Sectional Area and Strength at Different Skeletal Sites in Male Rats.

Aging mechanism as the “down side” of adaptation: A network approach

Skeletal effects of long-term caloric restriction in rhesus monkeys

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