Zinc Casting and Recycling (8 pp)

Aim, Scope and Background Metal die casting is a highly energy-intensive industry. In addition to that, the production of primary zinc by smelting consumes huge amounts of energy as well as generates many types of pollution. This paper uses LCA to investigate the environmental performance of a zinc cast product. The areas of environmental concern are focused on the direct and indirect air emissions that arise from the Zinc Smelting, Casting and Recycling, as well as transportation. Main Features The LCA case study employs a cradle-to-gate approach, which starts with the purchasing of primary zinc from abroad, casting, inspection, and ends when the scrap metal is sent back for recycling by truck. Based on a “generic” zinc casting product, the objective of the LCA was to compare the air emissions from the material cycle due to: i) the increased content of recycled metal in the final cast product; and ii) the choice of selecting between two Remelters (A and B), the first located near the company and the other in a neighbouring country, to send zinc scrap for recycling. The LCA SimaPro software (version 5.0) Eco-indicator “99 method is used to perform an impact assessment for Climate Change, Acidification, Ecotoxicity, Respiratory Inorganics, and Respiratory Organics was performed. Results The results from direct (process) and indirect (power plants) air emissions confirmed that the major air pollution occurs during Zinc Smelting, that is up to approximately 65–70%. Although an increase in recycling rates resulted in higher levels of air pollution from transportation as well as heavy metals from dross, these two issues were insignificant compared to the huge amount of energy consumed for primary metal production. Based on air pollution from transportation alone, a significant reduction of greenhouse gases and VOCs of 90% each was appreciated when Remelter A was selected. Conclusion The results verified that efforts to recycle zinc and consume the material in a more sustainable manner have become highly important. Also, a second LCA investigation that was made to compare zinc cast products that consists of: 100% primary zinc, mixtures of 50–50% and 40–60% primary-to-recycled zinc, and finally 100% recycled zinc; further emphasized the need for using recycled metal, as opposed to using primary metal.     

锌污染对植物的毒害及植物的忍耐性

锌在土壤中的总含量一般为10—300ppm,个别土壤可达500—1000ppm;在一些铅、锌矿区土壤的含锌量可高达2800ppm,甚至更高。锌是植物生长发育的必需元素,但环境中过量的锌会造成环境污染,使一些植物受害不能生存,一些植物可     

Zinc homeostasis in the secretory pathway in yeast

It is estimated that up to 10% of proteins in eukaryotes require zinc for their function. Although the majority of these proteins are located in the nucleus and cytosol, a small subset is secreted from cells or is located within an intracellular compartment. As many of these compartmentalized metalloproteins fold to their native state and bind their zinc cofactor inside an organelle, cells require mechanisms to maintain supply of zinc to these compartments even under conditions of zinc deficiency. At the same time, intracellular compartments can also be the site for storing zinc ions, which then can be mobilized when needed. In this review, we highlight insight that has been obtained from yeast models about how zinc homeostasis is maintained in the secretory pathway and vacuole.     

Zinc homeostasis and functions of zinc in the brain

The brain barrier system, i.e., the blood-brain and blood-cerebrospinal fluid barriers, is important for zinc homeostasis in the brain. Zinc is supplied to the brain via both barriers. A large portion of zinc serves as zinc metalloproteins in neurons and glial cells. Approximately 10% of the total zinc in the brain, probably ionic zinc, exists in the synaptic vesicles, and may serve as an endogenous neuromodulator in synaptic neurotransmission. The turnover of zinc in the brain is much slower than in peripheral tissues such as the liver. However, dietary zinc deprivation affects zinc homeostasis in the brain. Vesicular zinc-enriched regions, e.g., the hippocampus, are responsive to dietary zinc deprivation, which causes brain dysfunctions such as learning impairment and olfactory dysfunction. Olfactory recognition is reversibly disturbed by the chelation of zinc released from amygdalar neuron terminals. On the other hand, the susceptibility to epileptic seizures, which may decrease vesicular zinc, is also enhanced by zinc deficiency. Therefore, zinc homeostasis in the brain is closely related to neuronal activity. Even in adult animals and probably adult humans, adequate zinc supply is important for brain functions and prevention of neurological diseases.     

锌的生物学功能

人体所必需的微量元素锌,是生物体内约160多种酶的辅基,与生物的生长发育、各种抗性及免疫都有重要关系。本文综述了微量元素锌在生物体内对生物膜的稳定性和抗氧化作用、基因表达调控、细胞免疫、细胞凋亡及其对生物的毒性等生理生化功能。     

锌的生物学功能

人体所必需的微量元素锌,是生物体内约160多种酶的辅基,与生物的生长发育、各种抗性及免疫都有重要关系.本文综述了微量元素锌在生物体内对生物膜的稳定性和抗氧化作用、基因表达调控、细胞免疫、细胞凋亡及其对生物的毒性等生理生化功能.     

Zinc kinetics in insulin-dependent diabetes mellitus patients

Zinc has an important role in the control of carbohydrate metabolism, and diabetic patients are at risk for zinc deficiency. However, there are conflicting data concerning nutritional zinc status. In order to investigate this topic, 10 normal and 10 insulin-dependent diabetic patients were studied following venous zinc tolerance test. Our results found no evidence of zinc deficiency or of changes on the kinetic parameters of zinc in patients with insulin-dependent diabetes mellitus following a venous zinc tolerance test.     

Zinc availability from zinc lipoate and zinc sulfate in growing rats

The purpose of this study was to investigate the effect of zinc lipoate and zinc sulfate on zinc availability in growing rats. 6 . 6 male albino rats were fed purified diets based on corn starch, egg albumen, sucrose, soy bean oil and cellulose over a 4-week period (diet Ia: 10 mg Zn/kg as zinc sulfate, diet Ib: 10 mg Zn/kg as zinc lipoate, diet IIa: 10 mg Zn/kg as zinc sulfate +0.4% phytic acid, diet IIb: 10 mg Zn/kg as zinc lipoate +0.4% phytic acid, diet IIIa: 20 mg Zn/kg as zinc sulfate + 0.4% phytic acid, diet IIIb: 20 mg Zn/kg as zinc lipoate + 0.4% phytic acid). Zinc lipoate and zinc sulfate both proved to be highly available zinc sources. When 0.4% phytic acid were present in the diets, apparent zinc absorption was generally depressed but was higher from zinc lipoate in tendency than from zinc sulfate. Comparable results were evident for femur zinc, plasma zinc and metallothionein concentrations in liver tissues. This indicates that zinc lipoate could be a valuable zinc source under conditions of low zinc availability. Nevertheless the absence or presence of phytic acid was a more important factor influencing zinc availability than the type of zinc source investigated.     

滇苦菜（Picris divaricata Vant.）对锌的吸收和富集特性

通过野外调查和营养液培养,研究Zn对滇苦菜(Picris divaricata Vant.)生长的影响及其吸收富集Zn的特性.野外调查发现,铅锌矿区土壤Zn全量范围为1724～134973 mg·kg-1,平均为61495 mg·kg-1.滇苦菜地上部Zn含量范围为1214～18339 mg·kg-1,平均为5911 mg·kg-1,且转运系数(S/R)的平均值为2.21,大于1.在营养液培养条件下,当Zn浓度达到80 mg·L-1时,滇苦菜生长开始出现明显的中毒症状,随着Zn处理的增加,植物地上部与根部的生物量呈下降趋势,Zn含量呈上升趋势,且地上部与根部在160 mg·L-1时Zn含量达最高值,分别为12472 mg·kg-1和14026 mg·kg-1,体内Zn富集量也达最高值1518 μg ·株-1,并且整个植株富集的Zn有75%～91%分布在地上部.结果表明滇苦菜具有很强的忍耐、吸收和富集Zn的能力,是我国境内发现的又一种Zn超富集植物.     

Zinc and immunity

Nutritional deficiency of zinc is widespread throughout the developing countries and a conditioned deficiency of zinc is known to occur in many diseased states. Zinc is known to play an important role in the immune system and zinc deficient subjects may experience increased susceptibility to a variety of pathogens. We have studied the effects of a mild deficiency of zinc on T cells in an experimental model of human zinc deficiency. We showed that T cell functions were affected adversely even when the deficiency of zinc was mild in humans. Characteristically during zinc deficiency, the serum thymulin activity (a thymic hormone) was decreased which was restored following zinc supplementation. Our studies also showed that zinc deficiency caused an imbalance between TH1 and TH2 functions. The production of IFN-g, IL-2, TNF-a (products of TH1 cells) were decreased, whereas the production of IL-4, IL-6 and IL-10 (products of TH2) were not affected during zinc deficiency. T cell subpopulation studies revealed that the CD4+ CD45RA+ to CD4+ CD45RO+ ratio was decreased as a result of zinc deficiency, suggesting that zinc may be required for the regeneration of new CD4+ T cells. We further documented that zinc deficiency decreased NK cell lytic activity and caused a decrease in the percentage of CD8+ CD73+ T cells which are known to be predominantly precursors of cytotoxic T cells. In a suitable cell culture model our studies revealed that the gene expression of a DNA synthesizing enzyme TK was affected adversely which resulted in delayed cell cycle and decreased cell growth. The above immunological consequences of zinc deficiency may be responsible for decreased cell mediated immune functions in zinc deficient subjects.     

细菌锌离子调控体系与感染北大核心CSCD

锌(Zn)是生命体不可或缺的微量元素,对细菌和宿主同等重要。细菌体内锌离子稳态的维持依赖锌离子转运和调控体系。宿主通过限制锌离子或高锌离子中毒来控制细菌感染。为了在宿主体内生存,细菌必须表达高亲和力的锌离子转运系统,如ZnuABC,以获取足够的锌离子。由于锌与细菌大量的代谢和毒性通路密切相关,在细菌建立感染的过程中尤为重要,因此通过抑制锌离子转运系统来影响锌离子的稳态,将成为一个非常有发展前途的新型抗菌策略。     

Zinc depletion suppresses tumor growth in mice

The hypothesis that in tumor-bearing animals an increase of host hepatic zinc metallothionein (Zn-MT) causes a restriction of zinc in the tumor tissue was studied. Three types of tumors were induced in laboratory mice by cell transplant. Tumor growth appears to be inhibited under zinc-deficient conditions, even in cases where zinc deficiency was started after tumor cell transplant. The survival times of tumor-bearing mice were prolonged by administration of cadmium chloride, which induces the synthesis of a combined zinc-cadmium metallothionein derivative in the host liver, but not in the tumor tissue, leading to an increase of hepatic zinc in the treated animals. The uptake of⁶⁵Zn by the liver of Cd-treated, tumor bearing mice was significantly higher than that of controls whereas uptake of⁶⁵Zn by tumor cells was significantly higher in controls than in the treated animals. These results suggest that restriction of zinc intake suppresses tumor growth.     

Zinc efficiency of oilseed rape (t Brassica napus and t B. juncea) genotypes

Twenty five genotypes of oilseed rape (canola and mustard) were tested under varied supply of Zn (+Zn: 2 mg kg^–1 soil, -Zn: no Zn added) in two pot experiments in soil culture to determine the genotypic variation in tolerance to the Zn-deficient conditions, that is, to identify the Zn-efficient genotypes. On the basis of performance of genotypes in pot experiments, ten genotypes were tested in 1995 for their performance under varied supply of Zn (+Zn: 3.5 kg ha^–1, -Zn: no Zn added) on a Zn-deficient field in South Australia.Zn efficiency (ratio of shoot dry matter in -Zn to shoot dry matter in +Zn treatment and expressed in percentage) in pot Experiment 1 varied from 35% for 92-13 to 74% for Siren. Narendra, Dunkeld, Barossa, Oscar and Xinza 2 performed well under -Zn treatment. Zn efficiency in Experiment 2 varied from 32% for Wuyou 1 to 62% for Pusa Bold. Pusa Bold and CSIRO-1(mustard genotypes) were the most efficient in terms of dry matter production among all the oilseed rape genotypes tested. Root dry matter accumulation was significantly higher in Zn-efficient genotypes. Zn efficiency (ratio of seed yield in -Zn to seed yield in +Zn and expressed in percentage) in field experiment varied from 62% for Huashang 2 to 76% for Dunkeld. With few exceptions, the ranking of genotypes in pot and field experiments indicates similarity in their response to Zn deficiency. There looks to be genetic control over Zn concentration in tissues. Zn-efficient genotypes had lower Zn concentration in roots and higher Zn concentration in youngest fully opened leaf blades, indicating a better transport of Zn. This, together with a higher Zn uptake, appears to be the basis of expression of Zn efficiency.     

Over-Expression of an Arabidopsis Zinc Transporter in Hordeum Vulgare Increases Short-Term Zinc Uptake after Zinc Deprivation and Seed Zinc Content

Increasing the zinc content of cereal grains will be important for improving human nutrition. Improved plant zinc efficiency will lead to increased yields when available zinc is limiting plant growth. The aim of our work was to test how the over-expression of zinc transporters in cereals affects plant growth, seed mineral content, and zinc transport rates. Known zinc transporters from Arabidopsis were over-expressed in Hordeum vulgare cv. Golden Promise by means of a ubiquitin promoter. Multiple transgenic lines were obtained, and the locus number and expression levels were verified. Transgenic lines were tested in long-term growth and short-term uptake experiments. Seeds from transgenic lines grown in soil had higher zinc and iron contents than controls. Short-term uptake rates were higher in the transgenic lines after zinc deprivation. Resupply of zinc after a period of deprivation resulted in the rapid decrease in zinc uptake even in transgenic lines in which a zinc transporter gene was constitutively expressed. Similar to processes in yeast and Arabidopsis, we hypothesize that this rapid decrease in zinc transport activity may be caused by the degradation of transporters in response to zinc-sufficient conditions. In the long-term growth experiments, there were no significant differences between transgenic and control lines in leaf zinc content or shoot biomass under zinc-sufficient or -deficient conditions. However, root-to-shoot ratios were higher in the transgenic plants grown under low-zinc conditions; this could impact zinc acquisition under field conditions. Increased seed zinc and iron content by over-expression of a zinc transporter provides a new strategy for increasing the micronutrient content of cereals.     

ZnT-8, A Pancreatic Beta-Cell-Specific Zinc Transporter

The zinc content in the pancreatic beta cell is among the highest of the body. Zinc appears to be an important metal for insulin-secreting cells as insulin is stored inside secretory vesicles as a solid hexamer bound with two Zn²⁺ ions per hexamer. Zinc is also an important component of insulin secretion mechanisms and is likely to modulate the function of neighbouring cells via paracrine/autocrine interactions. Therefore beta cells undoubtedly need very efficient and specialized transporters to accumulate sufficient amounts of zinc in secretion vesicles. We report here the discovery and the characteristics of a new zinc transporter, ZnT-8, belonging to the CDF (Cation Diffusion Facilitator) family and expressed only in pancreatic beta cells. This transporter, localized in secretion vesicles membrane, facilitates the accumulation of zinc from the cytoplasm into intracellular insulin-containing vesicles and is a major component for providing zinc to insulin maturation and/or storage processes in insulin-secreting pancreatic beta cells. We discovered mammalian orthologs (rat, mouse, chimpanzee, and dog) and found these ZnT-8 proteins very similar (98% conserved amino acids) to human ZnT-8, indicating a high conservation during evolution.     

锌指蛋白与心脏发育

锌指是最大的DNA结合蛋白家族,是最普遍的核酸识别元件.近年来发现锌指参与生物体的基因转录,复制及蛋白质的合成等各种基因调节和控制过程,心脏发育过程中涉及大量锌指基因.综述了心脏发育过程中起重要调控作用的锌指蛋白以及它们的作用机制.     

锌指类基因调控蛋白──生物无机化学和分子生物学发展的新领域

生命必需元素锌,除了以锌酶的形式,参与生物体的各类代谢过程外,近年来发现,锌还以各种锌蛋白的结构方式,包括锌指、锌纽、锌带和锌簇等,参与生物体的基因转录、复制及蛋白质的合成等各种基因调节和控制过程．联想到金属硫蛋白在锌的体内平衡中所扮演的角色,很有可能锌是通过金属硫蛋白和锌指类蛋白的逐级调控,成为生物体生长发育的调控中心．癌基因和人免疫缺陷病毒（HIV）的许多调节蛋白也具有锌指类结构,这给癌症和爱滋病的治疗提供了新思路．     

Strategies for Dendrite‐Free Anode in Aqueous Rechargeable Zinc Ion Batteries

Ongoing interest is focused on aqueous zinc ion batteries (ZIBs) for mass‐production energy storage systems as a result of their affordability, safety, and high energy density. Ensuring the stability of the electrode/electrolyte interface is of particular importance for prolonging the cycling ability to meet the practical requirements of rechargeable batteries. Zinc anodes exhibit poor cycle life and low coulombic efficiency, stemming from the severe dendrite growth, and irreversible byproducts such as H₂ and inactive ZnO. Great efforts have recently been devoted to zinc anode protection for designing high‐performance ZIBs. However, the intrinsic origins of zinc plating/striping are poorly understood, which greatly delay its potential applications. Rather than focusing on battery metrics, this review delves deeply into the underlying science that triggers the deposition/dissolution of zinc ions. Furthermore, recent advances in modulating the zinc coordination environment, uniforming interfacial electric fields, and inducing zinc deposition are highlighted and summarized. Finally, perspectives and suggestions are provided for designing highly stable zinc anodes for the industrialization of the aqueous rechargeable ZIBs in the near future.     

Zinc and the Diabetic Heart

Zinc (Zn) is an essential mineral that is required for various cellular functions. Its abnormal metabolism is related to certain disorders such as diabetic complications. Oxidative stress has been considered as the major causative factor for diabetic cardiomyopathy. Zn has a critical antioxidant action in protecting the heart from various oxidative stresses. Zn deficiency was found to be a risk factor for cardiac oxidative damage and supplementation with Zn provides a significant prevention of oxidative damage to the heart. Diabetes causes a significant systemic oxidative stress and also often is accompanied by Zn deficiency that increases the susceptibility of the heart to oxidative damage. Therefore, there is a strong rationale to consider the strategy of Zn supplementation to prevent or delay diabetic cardiomyopathy. This short article collects the preliminary evidence, based on our own studies and those by others, for a preventive effect of Zn supplementation on diabetes-induced injury to the heart in animals and under in vitro conditions. Possible mechanisms by which Zn supplementation prevents diabetic heart disease are discussed. They include an antioxidant action of Zn, insulin function and metallothionein induction. In the final section, the future of Zn supplementation for diabetic patients is also briefly discussed. Although Zn supplementation has not been clinically used to prevent diabetic complications, because several issues need to be addressed, the fact that Zn supplementation is being used clinically for other disorders encourages us to explore its direct clinical application for the prevention of diabetic cardiomyopathy.     

Zinc toxicity in ectomycorrhizal Pinus sylvestris

Six strains of ectomycorrhizal fungi were compared for their ability to increase zinc tolerance in Pinus sylvestris L. seedlings. Pioneer and late-stage fungi as well as one strain collected from a Zn-polluted site were included in the study. The accumulation of zinc in the host plants was determined at two different sublethal substrate Zn concentrations. The mycobionts varied considerably in their protection of the autobionts against zinc toxicity. Several fungal species reduced zinc accumulation in the pine seedlings. A Thelephora terrestris (Ehrh.) Fr. Strain, however, increased the Zn concentration in its host plants. Specific zinc-retaining capacity of the mycelium and density of the extramatrical mycelium were important features determining the effectiveness of the zinc retention in the fungal symbiont.The experiments were carried out in a growth chamber where plants were cultivated in root observation chambers. The determination of the extent of substrate colonization showed that an elevated zinc concentration in a substrate might be an important stress factor for the growth of an ectomycorrhizal fungus. The growth of the extramatrical mycelium of some species was inhibited at the highest zinc concentration supplied. A determination of the in vitro zinc tolerance of the fungi could not always predict their tolerance as symbionts, where the latter characteristic did not determine the Zn retention capacity of their mycelium.In this paper we also discuss the possibility that on Zn-polluted soils ectomycorrhizal species and strains are selected that are Zn-tolerant and, in addition, are able to protect their own energy source, the autobiont, from toxicity. These mycorrhizal fungi act as a safety net, that can immobilize large amounts of zinc, thus preventing transport to the host plant.