镉毒性:深入了解来源、毒性动力学和对重要器官和胚胎的影响

Sara Bashir Ali EL-Hengary
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It has been postulated that metallothionein passes through the red cell membrane and is transformed to the kidney. Cadmium being a divalent cation is accumulated by transfers mechanisms developed for necessary metals. Cadmium may interact with zinc, iron, magnesium, manganese, calcium and selenium and cause their secondary disability and so break down metabolism, resulting in the final morphological and functional changes in many organs. Toxicity could result from cadmium (Cd2+) interacting with cellular ingredients until without get into the cell, but by interaction with receptors on their surface. Cadmium forms covalent and ionic bonds with atoms of sulfur, oxygen, and hydrogen present in the sulfhydryl groups, disulfide, carboxyl, imidazole or severally amino compounds present in the cells, causing significant disruption of their homeostasis. The principle target organelle of cadmium is the mitochondria. Symptoms of acute cadmium intoxicating usually appear after 24 hours are shortness of breath, general weakness, fever. It can also cause pulmonary edema, pneumonia and in acute cases, respiratory failure and death. Cadmium accumulates in the renal cortex and induces tubular damage. It may cause nephrotoxicity by procreating free radicals and/or by inducing necrosis, apoptosis and creatinine increase in plasma and urea increase in the serum. Exposure to cadmium can cause skeletal damage. Cadmium is attached to low bone mineralization, a high rate of fractures, increased osteoporosis and intense bone pain. It accumulates in the proximal tubular cells, it compresses cellular functions, which may result in reduced transformation among two forms of vitamin D3. This is probably to causes a decrease in calcium absorption and bone mineralization, which in turn may produce osteomalacia. The skeletal effects observed in young rats exposed to cadmium during the period of rapid skeletal growth and teratogenesis or skeletal effects recorded include sirenomelia (fused lower limbs), Amelia (absence of one or more limbs) and retard ossification of the sternum and ribs, dysplasia of facial bones and rear limbs and edema. Cadmium has been shown to be both embryotoxic and teratogenic in a different of animal species. It accumulates in human placenta and its concentration in cord blood increase with maternal exposure. Cadmium may be responsible for decreasing the volume of fetal capillaries in the terminal villi of the placenta. Furthermore, increasing the connective tissue about the fetal vessels changed synthesis of serum and amniotic fluid proteins and decreased expression of growth factors also may key a role in cadmium teratogenicity. Cadmium induces oxidative stress in many organisms at the cellular level, which may outcomes in physiological damage to various organs such as kidneys, liver, lung, pancreas, testes, placenta and bones Cadmium induces oxidative stress in many organisms at the cellular level, which may outcomes in physiological damage to various organs such as kidneys, liver, lung, pancreas, testes, placenta and bones. Reactive oxygen species reacting with polyunsaturated fatty acids of cell membranes initiate lipid peroxidation process that results in modulation of proteins, alteration in membrane components and this reason the loss of their impartiality and irrevocable damage. Conclusion: It can be concluded that symptoms of acute cadmium intoxicating are shortness of breath, general weakness, fever. pulmonary edema, and pneumonia. Cadmium accumulates with age in the different organs in the body and induces oxidative stress at the cellular level, which may outcomes in physiological damage to various organs such as kidneys, liver, lung, pancreas, testes, placenta and bones. Reactive oxygen species reacting with polyunsaturated fatty acids of cell membranes initiate lipid peroxidation process that results in modulation of proteins, alteration in membrane components and this reason the loss of their impartiality and irrevocable damage. 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Toxicity could result from cadmium (Cd2+) interacting with cellular ingredients until without get into the cell, but by interaction with receptors on their surface. Cadmium forms covalent and ionic bonds with atoms of sulfur, oxygen, and hydrogen present in the sulfhydryl groups, disulfide, carboxyl, imidazole or severally amino compounds present in the cells, causing significant disruption of their homeostasis. The principle target organelle of cadmium is the mitochondria. Symptoms of acute cadmium intoxicating usually appear after 24 hours are shortness of breath, general weakness, fever. It can also cause pulmonary edema, pneumonia and in acute cases, respiratory failure and death. Cadmium accumulates in the renal cortex and induces tubular damage. It may cause nephrotoxicity by procreating free radicals and/or by inducing necrosis, apoptosis and creatinine increase in plasma and urea increase in the serum. Exposure to cadmium can cause skeletal damage. Cadmium is attached to low bone mineralization, a high rate of fractures, increased osteoporosis and intense bone pain. It accumulates in the proximal tubular cells, it compresses cellular functions, which may result in reduced transformation among two forms of vitamin D3. This is probably to causes a decrease in calcium absorption and bone mineralization, which in turn may produce osteomalacia. The skeletal effects observed in young rats exposed to cadmium during the period of rapid skeletal growth and teratogenesis or skeletal effects recorded include sirenomelia (fused lower limbs), Amelia (absence of one or more limbs) and retard ossification of the sternum and ribs, dysplasia of facial bones and rear limbs and edema. Cadmium has been shown to be both embryotoxic and teratogenic in a different of animal species. It accumulates in human placenta and its concentration in cord blood increase with maternal exposure. 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引用次数: 0

摘要

背景:元素镉、氧化镉、硫化镉和氯化物从自然和人为来源重新释放到大气中。吸烟者血液、尿液和肾皮质中的镉浓度明显高于从不吸烟者。被吸收的镉主要在肾皮质和肝脏中积累。胰腺、甲状腺、胆囊和睾丸也可能含有相对较高的浓度。目的:综述氯化镉对重要器官和胚胎的影响。从肺部吸收镉是吸烟者和职业接触者之间的主要接触源。镉随着年龄的增长而积累,甚至在50岁左右达到最大水平。金属硫蛋白已在动物的肝脏、肾脏、十二指肠、尿液和血液中发现。据推测,金属硫蛋白通过红细胞膜并转化到肾脏。镉是一种二价阳离子,通过为必需金属开发的转移机制积累。镉可与锌、铁、镁、锰、钙、硒等发生相互作用,引起它们的继发性残疾,从而破坏代谢,最终导致许多器官形态和功能的改变。毒性可能是由于镉(Cd2+)与细胞成分相互作用直到没有进入细胞,而是通过与细胞表面的受体相互作用而产生的。镉与存在于细胞中的硫、氧、氢、硫、二硫、羧基、咪唑或几种氨基化合物中的原子形成共价键和离子键,导致细胞内稳态的严重破坏。镉的主要靶细胞器是线粒体。急性镉中毒24小时后通常出现呼吸急促、全身乏力、发热等症状。它还可引起肺水肿、肺炎,在急性病例中,可导致呼吸衰竭和死亡。镉在肾皮质积聚,引起肾小管损伤。它可能通过产生自由基和/或诱导坏死、细胞凋亡和血浆肌酐升高和血清尿素升高而引起肾毒性。接触镉会导致骨骼损伤。镉与低骨矿化、高骨折率、骨质疏松症加剧和剧烈骨痛有关。它积聚在近端小管细胞中,它压缩细胞功能,这可能导致两种形式的维生素D3之间的转化减少。这可能会导致钙吸收和骨矿化减少,从而可能产生骨软化症。在骨骼快速生长和致畸期间暴露于镉的幼鼠中观察到的骨骼效应或记录的骨骼效应包括下肢融合(sirenomelia), Amelia(缺少一个或多个肢体)以及胸骨和肋骨的延迟骨化,面部骨骼和后肢发育不良以及水肿。镉已被证明在不同的动物物种中具有胚胎毒性和致畸性。它在人胎盘中积累,在脐带血中的浓度随着母体接触而增加。镉可能是导致胎盘末端绒毛中胎儿毛细血管体积减少的原因。此外,胎儿血管结缔组织的增加改变了血清和羊水蛋白的合成,并降低了生长因子的表达,也可能是镉致畸的关键因素。镉在细胞水平上诱导许多生物体的氧化应激,这可能导致肾、肝、肺、胰腺、睾丸、胎盘和骨骼等多种器官的生理损伤。镉在细胞水平上诱导许多生物体的氧化应激,这可能导致肾、肝、肺、胰腺、睾丸、胎盘和骨骼等多种器官的生理损伤。活性氧与细胞膜上的多不饱和脂肪酸反应,引发脂质过氧化过程,导致蛋白质的调节,膜成分的改变,从而导致其公平性的丧失和不可挽回的损伤。结论:急性镉中毒的主要症状为呼吸急促、全身乏力、发热。肺水肿和肺炎。随着年龄的增长,镉在人体不同器官中积累,并在细胞水平上引起氧化应激,从而可能导致肾、肝、肺、胰腺、睾丸、胎盘和骨骼等多种器官的生理损伤。活性氧与细胞膜上的多不饱和脂肪酸反应,引发脂质过氧化过程,导致蛋白质的调节,膜成分的改变,从而导致其公平性的丧失和不可挽回的损伤。镉已被证明在不同的动物物种中具有胚胎毒性和致畸性。
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Cadmium Toxicity: Insight into Sources, Toxicokinetics, and Effect on Vital Organs and Embryos
Background: Elemental cadmium, cadmium oxide, sulfide, and chloride are resurrected to the atmosphere from both natural and anthropogenic sources. cadmium concentrations in the blood, urine and kidney cortex are substantially higher in smokers compared to never smokers. Absorbed cadmium accumulates primly in the renal cortex and liver. The pancreas, thyroid, gall-bladder and testes can also include comparatively high concentrations. Objectives: The current review aimed to highlight on the effect of cadmium chloride on vital organs and embryos. Absorption of cadmium from the lungs is a major source of exposure between smokers and the occupationally exposed. Cadmium accumulates with age even a maximum level is arrived at about age 50. Metallothionein has been identified in the liver, kidneys, duodenum, urine and blood of animals. It has been postulated that metallothionein passes through the red cell membrane and is transformed to the kidney. Cadmium being a divalent cation is accumulated by transfers mechanisms developed for necessary metals. Cadmium may interact with zinc, iron, magnesium, manganese, calcium and selenium and cause their secondary disability and so break down metabolism, resulting in the final morphological and functional changes in many organs. Toxicity could result from cadmium (Cd2+) interacting with cellular ingredients until without get into the cell, but by interaction with receptors on their surface. Cadmium forms covalent and ionic bonds with atoms of sulfur, oxygen, and hydrogen present in the sulfhydryl groups, disulfide, carboxyl, imidazole or severally amino compounds present in the cells, causing significant disruption of their homeostasis. The principle target organelle of cadmium is the mitochondria. Symptoms of acute cadmium intoxicating usually appear after 24 hours are shortness of breath, general weakness, fever. It can also cause pulmonary edema, pneumonia and in acute cases, respiratory failure and death. Cadmium accumulates in the renal cortex and induces tubular damage. It may cause nephrotoxicity by procreating free radicals and/or by inducing necrosis, apoptosis and creatinine increase in plasma and urea increase in the serum. Exposure to cadmium can cause skeletal damage. Cadmium is attached to low bone mineralization, a high rate of fractures, increased osteoporosis and intense bone pain. It accumulates in the proximal tubular cells, it compresses cellular functions, which may result in reduced transformation among two forms of vitamin D3. This is probably to causes a decrease in calcium absorption and bone mineralization, which in turn may produce osteomalacia. The skeletal effects observed in young rats exposed to cadmium during the period of rapid skeletal growth and teratogenesis or skeletal effects recorded include sirenomelia (fused lower limbs), Amelia (absence of one or more limbs) and retard ossification of the sternum and ribs, dysplasia of facial bones and rear limbs and edema. Cadmium has been shown to be both embryotoxic and teratogenic in a different of animal species. It accumulates in human placenta and its concentration in cord blood increase with maternal exposure. Cadmium may be responsible for decreasing the volume of fetal capillaries in the terminal villi of the placenta. Furthermore, increasing the connective tissue about the fetal vessels changed synthesis of serum and amniotic fluid proteins and decreased expression of growth factors also may key a role in cadmium teratogenicity. Cadmium induces oxidative stress in many organisms at the cellular level, which may outcomes in physiological damage to various organs such as kidneys, liver, lung, pancreas, testes, placenta and bones Cadmium induces oxidative stress in many organisms at the cellular level, which may outcomes in physiological damage to various organs such as kidneys, liver, lung, pancreas, testes, placenta and bones. Reactive oxygen species reacting with polyunsaturated fatty acids of cell membranes initiate lipid peroxidation process that results in modulation of proteins, alteration in membrane components and this reason the loss of their impartiality and irrevocable damage. Conclusion: It can be concluded that symptoms of acute cadmium intoxicating are shortness of breath, general weakness, fever. pulmonary edema, and pneumonia. Cadmium accumulates with age in the different organs in the body and induces oxidative stress at the cellular level, which may outcomes in physiological damage to various organs such as kidneys, liver, lung, pancreas, testes, placenta and bones. Reactive oxygen species reacting with polyunsaturated fatty acids of cell membranes initiate lipid peroxidation process that results in modulation of proteins, alteration in membrane components and this reason the loss of their impartiality and irrevocable damage. Cadmium has been shown to be both embryotoxic and teratogenic in a different of animal species.
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