UMLS:C0004153 - FACTA Search

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Query: UMLS:C0004153 (atherosclerosis)
77,401 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Although a superficial similarity exists between the musculoskeletal disorders associated with natural aging and those of progeria, an in-depth analysis reveals profound differences in the pathophysiology between the two processes. The protean manifestations of progeria can best be explained on the basis of the vascular changes found at autopsy. A disorder of the vascular endothelium may predispose progeric vessels to atherosclerotic changes. The unique musculoskeletal manifestations of progeria arise from the effects of premature atherosclerosis on the vascularized connective tissues.
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PMID:The musculoskeletal manifestations of progeria. A literature review. 304 91

The cardiovascular findings in cases of progeria are similar in many respects to the changes associated with aging. These changes include prominent atherosclerosis and calcification of the aortic and mitral valves, coronary arteries, and aorta. The coronary artery disease leads to ischemic changes in the myocardium, including well-defined infarcts. In addition, the present case demonstrates narrowing of the small intramural arteries, which may have contributed to myocardial fibrosis.
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PMID:Cardiovascular abnormalities in progeria. Case report and review of the literature. 689 91

Report of necropsy findings of a 17 years old girl with a progeria syndrome. There was a high degree of generalized atherosclerosis, involving the visceral arteries, chiefly those to the kidneys. The patient died of nephrosclerosis with uraemia. The aetiology of progeria syndrome remains obscure, single findings (lipoprotein- and amino-acid metabolism) may be understood as an inborn error of metabolism.
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PMID:[Morphologic contribution to a progeria syndrome (Hutchinson-Gilford) (author's transl)]. 744 1

Hutchinson-Gilford progeria syndrome (HGPS) is a rare condition with an unknown molecular defect. Patients with HGP progressively develop failure to thrive (FTT), alopecia, loss of subcutaneous fat, scleroderma, stiffening of various joints, and severe atherosclerosis. The median life span is 13 years, and the main cause of death is cardiovascular complications. There are few reports of endocrine and metabolic studies because of the rarity of this condition, and the response to long-term growth hormone (GH) treatment has not been described. We report the results of endocrine and metabolic studies performed to investigate the etiology of growth failure in five patients with HGP. Additionally, the response to nutritional therapy (NT) and GH treatment in three of these patients is presented. Our results suggest that elevated GH levels are characteristic of this disease and that an elevated basal metabolic rate (BMR) could be the cause of the FTT seen in HGP. Nonaggressive NT slightly improved weight gain and growth velocity (GV). Combined NT and GH treatment in three patients improved the GV, increased the levels of growth factors, and paradoxically resulted in decreased BMRs. However, the response to these therapies decreased over time and did not seem to prevent the progression of atherosclerotic disease.
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PMID:Response to nutritional and growth hormone treatment in progeria. 925 64

Although philosophers and scientists have long been interested in the aging process, general interest in this fascinating and highly important topic was minimal before the 1960s. In recent decades, however, interest in aging has greatly accelerated, not only since the elderly form an ever-increasing percentage of the population, but because they utilize a significant proportion of the national expenditures. In addition, many people have come to the realization that one can now lead a very happy, active, and productive life well beyond the usual retirement age. Scientifically, aging is an extremely complex, multifactorial process, and numerous aging theories have been proposed; the most important of these are probably the genomic and free radical theories. Although it is abundantly clear that our genes influence aging and longevity, exactly how this takes place on a chemical level is only partially understood. For example, what kinds of genes are these, and what proteins do they control? Certainly they include, among others, those that regulate the processes of somatic maintenance and repair, such as the stress-response systems. The accelerated aging syndromes (i.e., Hutchinson-Gilford, Werner's, and Down's syndromes) are genetically controlled, and studies of them have decidedly increased our understanding of aging. In addition, C. elegans and D. melanogaster are important systems for studying aging. This is especially true for the former, in which the age-1 mutant has been shown to greatly increase the life span over the wild-type strain. This genetic mutation results in increased activities of the antioxidative enzymes, Cu-Zn superoxide dismutase and catalase. Thus, the genomic and free radical theories are closely linked. In addition, trisomy 21 (Down's syndrome) is characterized by a significantly shortened life span; it is also plagued by increased oxidative stress which results in various free radical-related disturbances. Exactly how this extra chromosome results in an increased production of reactive oxygen species is, however, only partially understood. There is considerable additional indirect evidence supporting the free radical theory of aging. Not only are several major age-associated diseases clearly affected by increased oxidative stress (atherosclerosis, cancer, etc.), but the fact that there are numerous natural protective mechanisms to prevent oxyradical-induced cellular damage speaks loudly that this theory has a key role in aging [the presence of superoxide dismutase, catalase, glutathione peroxidase, and glutathione reductase, among others; various important intrinsic (uric acid, bilirubin, -SH proteins, glutathione, etc.) and extrinsic (vitamins C, E, carotenoids, flavonoids, etc.) antioxidants; and metal chelating proteins to prevent Fenton and Haber-Weiss chemistry]. In addition, a major part of the free radical theory involves the damaging role of reactive oxygen species and various toxins on mitochondria. These lead to numerous mitochondrial DNA mutations which result in a progressive reduction in energy output, significantly below that needed in body tissues. This can result in various signs of aging, such as loss of memory, hearing, vision, and stamina. Oxidative stress also inactivates critical enzymes and other proteins. In addition to these factors, caloric restriction is the only known method that increases the life span of rodents; studies currently underway suggest that this also applies to primates, and presumably to humans. Certainly, oxidative stress plays an important role here, although other, as yet unknown, factors are also presumably involved. Exactly how the other major theories (i.e., immune, neuroendocrine, somatic mutation, error catastrophe) control aging is more difficult to define. The immune and neuroendocrine systems clearly deteriorate with age. (ABSTRACT TRUNCATED)
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PMID:The biochemistry of aging. 1104 Sep 57

Atherosclerosis constitutes the most common medical and surgical problem. This can be manifested clinically as stroke, coronary artery disease, or peripheral vascular disease. In the present review the microscopic appearance of the normal arterial wall, the definition of atherosclerosis and the five theories of atherogenesis are described. These are: the lipid theory, the hemodynamic theory, the fibrin incrustation theory, the nonspecific mesenchymal hypothesis and the response to injury hypothesis. Based on the above theories the sequence of events in atherogenesis is analyzed. The classification of the atherosclerotic lesions according to Stary (types I-VI) and their characteristics appear in a table. The epidemiology and the role of the following risk factors are presented in detail: age, sex, lipid abnormalities, cigarette smoking, hypertension, diabetes mellitus, physical inactivity, alcohol consumption, obesity, and hemostatic factors. In addition, less common genetically determined associations like homocystinuria, Tangier disease, Hutchinson-Gilford syndrome (progeria), Werner's syndrome, radiation induced atherosclerosis and the implications of Chlamydia pneumoniae on the arterial wall are discussed.
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PMID:The genesis of atherosclerosis and risk factors: a review. 1122 92

Progeria, a rare genetic disorder, is characterized by severe growth failure, premature aging, and very early atherosclerosis with coronary artery and cerebrovascular disease. There has been no detailed description of progressive cerebrovascular changes in progeria or any attempted neurologic correlation of those changes. A 5-year-old boy developed signs of progeria at 4 months and hypertension at 4 years, treated with atenolol and dipyridamole. Left-sided seizures with a left hemiparesis occurred at 5 years. Magnetic resonance imaging (MRI) showed bilateral acute, subacute, and chronic cerebral infarctions. Magnetic resonance angiography disclosed severe stenosis of the left internal carotid artery. The child was also found to have an aortic valve vegetation and was anticoagulated. He subsequently developed right-sided seizures, and treatment with gabapentin was started. Later, severe stenosis also of the right internal carotid artery was found. MRI showed new left cerebral infarction. The child's neurologic symptoms almost certainly were caused by cerebral infarctions from progressive atherosclerosis of major intracranial vessels, but clinical-neuroradiologic correlations were imprecise. There were multiple cerebral infarctions of different ages, some asymptomatic, others ipsilateral to the child's neurologic findings. No therapy has halted progression of the child's cerebrovascular disease.
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PMID:Progressive intracranial vascular disease with strokes and seizures in a boy with progeria. 1130 89

A number of mouse models have been identified and are being used for aging and age-associated disease research. However, the use of the genetically manipulated mouse model is still a relatively untapped resource for the study of the biology of aging. Genetically altered mice can be powerful tools for biology of aging research because gene expression can be controlled and correlated with established biomarkers. Standard transgene overexpression and gene targeting techniques were modified and used to generate 30 mouse lines during a 4-year period. These lines include models of Werner's syndrome (premature aging or progeria), Alzheimer's disease, other neurodegenerative condition, atherosclerosis, diabetes, immune dysfunction, musculoskeletal disorders, and oxidative stress. These new mouse models are providing additional insights into aging processes and will be useful for developing intervention strategies and collaborative interactions.
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PMID:Generation of genetically altered mouse models for aging studies. 1178 22

Werner's syndrome or progeria, described for the first time in 1886, is a rare disease with autosomal recessive transmission, characterized by premature ageing of connective tissues. About 200 cases have since been reported in the literature. Most patients die young, generally from heart failure due to early coronary atherosclerosis [1]. The authors report the case of a 46-year-old woman presenting with cardiovascular abnormalities, unusual for her age, associated with a particular morphotype belonging to Werner's syndrome.
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PMID:[Werner's disease presenting as ischemic mitral incompetence]. 1255 82

Numerous studies of the underlying causes of ageing have been attempted by examining diseases associated with premature ageing, such as Werner's syndrome and Hutchinson-Gilford progeria syndrome (HGPS). HGPS is a rare genetic disorder resulting in phenotypes suggestive of accelerated ageing, including shortened stature, craniofacial disproportion, very thin skin, alopecia and osteoporosis, with death in the early teens predominantly due to atherosclerosis. However, recent reports suggest that developmental abnormalities may also be important in HGPS. Here we describe the derivation of mice carrying an autosomal recessive mutation in the lamin A gene (Lmna) encoding A-type lamins, major components of the nuclear lamina. Homozygous mice display defects consistent with HGPS, including a marked reduction in growth rate and death by 4 weeks of age. Pathologies in bone, muscle and skin are also consistent with progeria. The Lmna mutation resulted in nuclear morphology defects and decreased lifespan of homozygous fibroblasts, suggesting premature cell death. Here we present a mouse model for progeria that may elucidate mechanisms of ageing and development in certain tissue types, especially those developing from the mesenchymal cell lineage.
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PMID:A progeroid syndrome in mice is caused by defects in A-type lamins. 1274 43

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