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冲击波聚心的英文The shockwave of a supernova explosion is a magnificent display of cosmic power, radiating outward from the dying star with incredible force and energy. This phenomenon, known as the supernova remnant, is a crucial area of study for astronomers, providing insights into the life cycles of stars and the processes that shape our universe.At the heart of these explosive events lies a complex interplay of physical forces and phenomena. When a massive star reaches the end of its life, it undergoes a cataclysmic collapse, triggering a chain reaction of nuclear fusion and fission within its core. As the star's core becomes increasingly unstable, it eventually reaches a critical point where it can no longer support its own weight, leading to a sudden and violent collapse known as a supernova.The shockwave generated by this explosive event is incredibly powerful, traveling outward at speeds of millions of kilometers per hour. As it expands into the surrounding space, it encounters the interstellar medium, the vast expanse of gas and dust that fills the space between stars. The interaction between the supernova shockwave and the interstellar medium is a dynamic and complex process, giving rise to a wide range of phenomena observed by astronomers.One of the most striking features of supernova remnants is their intricate and beautiful structure. As the shockwave sweeps through the interstellar medium, it compresses and heats the surrounding gas and dust, creating elaborate patterns of filaments, bubbles, and shells. These structures can persist for thousands of years, providing astronomers with a snapshot of the supernova explosion and its aftermath.In addition to their aesthetic appeal, supernova remnants play a crucial role in the evolution of galaxies. The energy and heavy elements synthesized in supernova explosions are injected into the interstellar medium, enriching it with the raw materials needed for the formation of new stars and planetary systems. This process, known as stellar nucleosynthesis, is essential for the continued growth and evolution of galaxies over cosmic time scales.Furthermore, supernova remnants are also sites of intense physical processes, including the acceleration of charged particles to relativistic speeds. These high-energy particles can interact with magnetic fields and emit radiation across the entire electromagnetic spectrum, from radio waves to gamma rays. Studying the emission from supernova remnants allows astronomers to probe the underlying physics of particle acceleration and magnetic field dynamics in extreme environments.In recent years, advances in observational techniques have led to a deeper understanding of supernova remnants and their role in the universe. High-resolution imaging and spectroscopic observations have revealed the intricate details of shockwave dynamics and the distribution of heavy elements within these cosmic relics. Theoretical models and numerical simulations have provided valuable insights into the physical processes driving the evolution of supernova remnants and their impact on galactic ecosystems.Looking ahead, future observations with next-generation telescopes and space-based observatories promise to unveil even more secrets of supernova remnants. By studying these cosmic artifacts in greater detail, astronomers hope to unravel the mysteries of stellar death and the profound influence it has on the evolution of the cosmos. From the heart of a dying star to the farthest reaches of the universe, the shockwaves of supernova explosions continue to captivate our imagination and inspire scientific discovery.。
长链的非编码RNA生长停滞特异性转录本5在骨关节炎中的研究进展张晓彤;郝婧婧;李芳;纪斌平;张芳芳【期刊名称】《安徽医药》【年(卷),期】2024(28)5【摘要】骨关节炎(OA)是一种以软骨退变、骨重建为主要病理特点的慢性关节疾病。
目前没有可治愈该疾病的药物及手段,治疗策略有限的根本原因是对其潜在发病机制的认识不足。
长链的非编码RNA(LncRNAs)被认为是许多疾病中的一类新的调控因子,是目前研究OA发病机制的一个重要切入点。
LncRNA生长停滞特异性转录本5(Cas5)参与调控细胞的增殖、分化及凋亡,是一种在软骨细胞中特异性高表达的LncRNA。
然而,由于LncRNA Cas5作用机制复杂,其与OA相关具体分子机制目前仍不明确。
该文针对LncRNA Cas5在OA中的软骨细胞凋亡、软骨基质代谢成骨分化及治疗方面的作用进行综述。
【总页数】4页(P870-873)【作者】张晓彤;郝婧婧;李芳;纪斌平;张芳芳【作者单位】山西医科大学第二临床医学院;山西医科大学第二医院风湿免疫科;山西华晋骨科医院骨科【正文语种】中文【中图分类】R73【相关文献】1.子痫前期患者胎盘组织中长链非编码RNA生长停滞特异性转录本5表达水平及临床意义2.长链非编码RNA生长停滞特异性转录本5在糖尿病肾病进展中作用机制研究3.长链非编码RNA生长停滞特异性转录本5在妇科恶性肿瘤中的研究进展4.长链非编码RNA生长停滞特异性转录本5(lncGAS5)促进同型半胱氨酸致肝细胞自噬作用5.长链非编码生长停滞特异性蛋白6反义RNA1靶向miRNA-374a-3p 调控高糖诱导的人肾小管上皮细胞损伤及纤维化分子机制的研究因版权原因,仅展示原文概要,查看原文内容请购买。
附件6作者姓名:卢滇楠论文题目:温敏型高分子辅助蛋白质体外折叠的实验和分子模拟研究作者简介:卢滇楠,男,1978年4月出生, 2000年9月师从清华大学化工系生物化工研究所刘铮教授,从事蛋白质体外折叠的分子模拟和实验研究,于2006年1月获博士学位。
博士论文成果以系列论文形式集中发表在相关研究领域的权威刊物上。
截至2007年发表与博士论文相关学术论文21篇,其中第一作者SCI论文9篇(有4篇IF>3),累计他引20次(SCI检索),EI收录论文14篇(含双收),国内专利1项。
中文摘要引言蛋白质体外折叠是重组蛋白质药物生产的关键技术,也是现代生物化工学科的前沿领域之一,大肠杆菌是重要的重组蛋白质宿主体系,截止2005年FDA批准的64种重组蛋白药物中有26种采用大肠杆菌作为宿主体系,目前正在研发中的4000多种蛋白质药物中有90%采用大肠杆菌为宿主表达体系。
但由于大肠杆菌表达系统缺乏后修饰体系使得其生产的目标蛋白质多以无生物学活性的聚集体——包涵体的形式存在,在后续生产过程中需要对其进行溶解,此时蛋白质呈无规伸展链状结构,然后通过调整溶液组成诱导蛋白质发生折叠形成具有预期生物学活性的高级结构,这个过程就称之为蛋白质折叠或者复性,由于该过程是在细胞外进行的,又称之为蛋白质体外折叠技术。
蛋白质体外折叠技术要解决的关键问题是避免蛋白质的错误折叠以及形成蛋白质聚集体。
目前本领域的研究以具体技术和产品折叠工艺居多,折叠过程研究方面则多依赖宏观的结构和性质分析如各类光谱学和生物活性测定等,在研究方法上存在折叠理论、分子模拟与实验研究结合不够的问题,这些都不利于折叠技术的发展和应用。
本研究以发展蛋白质新型体外折叠技术为目标,借鉴蛋白质体内折叠的分子伴侣机制,提出以智能高分子作为人工分子伴侣促进蛋白质折叠的新思路,即通过调控高分子与蛋白质分子的相互作用,1)诱导伸展态的变性蛋白质塌缩形成疏水核心以抑制蛋白质分子间疏水作用所导致的聚集,2)与折叠中间态形成多种可逆解离复合物,丰富蛋白质折叠的途径以提高折叠收率。
circRNA_09505介导M2型巨噬细胞极化失衡在强直性脊柱炎模型中的作用*李玄1, 张洁2△, 向伟能1, 蒋林1, 王惟达1, 周乾1, 唐烨1(1长沙市第一医院脊柱外科,湖南 长沙 410005;2南华大学附属第二医院脊柱外科,湖南 衡阳 421001)[摘要] 目的:探讨circRNA_09505(circ09505)是否通过介导M2型巨噬细胞极化失衡参与强直性脊柱炎(AS )的发病机制。
方法:采用高通量circRNA 测序分析确定AS 患者和健康对照者外周血单个核细胞(PBMC )中差异表达的circRNA 。
将SKG 小鼠随机分为对照组、sh -NC 组和sh -circ09505组,每组10只。
各组小鼠通过腹腔注射3 mg 可德胶以建立AS 模型。
对sh -circ09505组小鼠尾静脉注射circ09505敲减慢病毒,以检查circ09505敲减对AS 进展的影响。
体外考察circ09505过表达或敲减对巨噬细胞极化影响,并通过流式细胞术分析M1和M2型巨噬细胞比例。
结果:circ09505是AS 患者PBMC 中上调最显著的circRNA 。
sh -circ09505组小鼠脊柱免疫细胞浸润和软骨破坏较sh -NC 组减轻,脊柱炎评分显著降低(P <0.01)。
与sh -NC 组相比,sh -circ09505组中炎性细胞因子IL -1β、IL -6和TNF -α的表达显著降低(P <0.01),并且脊柱组织中CD11b + CD40+细胞数目显著降低(P <0.01),CD11b + CD206+细胞数目显著增加(P <0.01)。
流式细胞术分析表明,circ09505过表达降低了M2巨噬细胞比例(P <0.01),而circ09505敲减则增加了M2巨噬细胞比例(P <0.01)。
circ09505过表达增加了LPS+IFN -γ处理组的M1巨噬细胞比例(P <0.01),而circ09505敲减则降低了M1巨噬细胞比例(P <0.01)。
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除了抗体和自发荧光的交叉反应,成年猴大脑皮质中是否有内源性神经发生?成年灵长类动物的大脑皮质中是否存在内源性神经发生是一个有争议的问题。
近期许多报道显示,新生神经元标记物DCX阳性神经发生在成年灵长类动物皮质中持续存在,这再次引起了全世界的极大关注。
中国河南理工大学刘若虚等的一项最新研究在免疫组织化学染色和蛋白质印迹实验中,使用不同的不同的DCX及成熟神经元标记物NeuN抗体对成年猕猴大脑皮质的相邻切片进行了标记,并通过应用组织吸收,抗原中和,一抗省略和无抗体实验进一步研究其染色结果差异。
结果发现,(1)应用不同DCX抗体在大脑皮质相邻组织切片中可分别发现DCX强荧光标记的细胞,这些大脑皮质DCX 阳性细胞与成熟神经元的特异性标志物NeuN均有共定位关系;(2)进一步的免疫组织化学染色结果证明,这些共标记结果是由部分DCX抗体的交叉反应,部分二抗的非特异性或组织的自发荧光引起的,但不同于以往部分文献的报道,我们也未通过免疫荧光的方法在成年猕猴大脑皮质中发现任何DCX阳性细胞;(3)上述数据证实,除了抗体和自发荧光的交叉反应之外,成年灵长类动物的大脑皮质中没有DCX阳性神经发生。
研究结果对于理解成人神经发生有重要贡献。
文章研究成果发表在《中国神经再生研究(英文版)》杂志2020年7月第7期。
文章摘要:成年灵长类动物的大脑皮质中是否存在内源性神经发生是一个有争议的问题。
近期许多报道显示,新生神经元标记物DCX阳性神经发生在成年灵长类动物皮质中持续存在,这再次引起了全世界的极大关注。
实验在免疫组织化学染色和蛋白质印迹实验中,使用不同的DCX及成熟神经元标记物NeuN抗体对成年猕猴大脑皮质的相邻切片进行了标记,并通过应用组织吸收,抗原中和,一抗省略和无抗体实验进一步研究其染色结果差异。
结果发现,(1)应用不同DCX抗体在大脑皮质相邻组织切片中可分别发现DCX强荧光标记的细胞,部分中等偏弱的标记细胞,仅在核周围的局部标记,或者接近完全阴性的标记结果,这些所谓的大脑皮质DCX阳性细胞与成熟神经元的特异性标志物NeuN均有共定位关系;(2)进一步的免疫组织化学染色结果证明,这些共标记结果是由部分DCX抗体的交叉反应,部分二抗的非特异性或组织的自发荧光引起的,但未通过免疫荧光的方法在成年猕猴大脑皮质中发现任何DCX阳性细胞;(3)上述数据证实,除了抗体和自发荧光的交叉反应之外,成年灵长类动物的大脑皮质中并未出现DCX阳性神经发生现象。
探索宇宙奥秘:恒星的形成与演化1. 引言1.1 概述恒星是宇宙中最基本的天体,它们以其巨大的质量和炽热的光芒在银河系中闪耀。
恒星的形成和演化是天文学领域最激动人心的课题之一。
通过对恒星形成和演化过程的深入研究,我们可以更好地理解宇宙的起源和发展。
1.2 文章结构本文将探讨恒星的形成与演化过程,并分析恒星对宇宙的重要性。
首先,我们将介绍分子云的形成与演化,这是恒星形成的基础。
接着,我们将详细描述原恒星的形成过程以及恒星主序演化阶段。
然后,我们将探讨红巨星阶段、超新星爆发以及黑洞和中子星等残骸形成过程。
最后,我们将阐述恒星对宇宙生命起源、能量来源以及对行星系统和生物多样性的影响。
1.3 目的本文旨在提供关于恒星形成和演化方面最新研究进展的全面概览,并强调恒星在宇宙中的重要性。
通过阐明恒星对光、能量和化学元素合成方面的贡献,我们将更好地认识到宇宙中恒星与行星系统以及生命之间的千丝万缕的联系。
同时,本文还将展望未来在恒星形成和演化领域可能的研究方向,为进一步探索宇宙奥秘提供理论基础。
以上是文章“1. 引言”部分内容的详细清晰描述。
2. 恒星的形成2.1 分子云的形成与演化:恒星形成的第一步是由分子云开始。
分子云是巨大的气体和尘埃结构,由氢、氦以及其他重元素组成。
这些分子云通常在银河系中的星际空间中存在。
当这些分子云中的某个区域受到压缩或干扰时,它就会开始坍缩并形成恒星。
整个过程可以追溯到数百万年前,其中引力起着重要作用。
当分子云内部的气体积聚在一点时,引力会增加,导致更多的气体聚集在该点周围。
这种压缩将继续,直到最终形成一个密度非常高且温度很高的区域,我们称之为原恒星诞生地。
2.2 原恒星的形成过程:原恒星是指在恒星形成阶段之后但尚未进入主序演化阶段的恒星。
一旦原恒星诞生地达到足够高的密度和温度,核融合反应将在其中心开始发生。
这些反应使得氢被转化为更重的元素,并释放出大量的能量。
原恒星的形成过程可以分为以下几个阶段:原恒星诞生,原恒星第一次核融合,以及原恒星的演化。
英文作文《宇宙尘埃》200词英文回答:The universe is a vast expanse filled with countless wonders and mysteries. Among these wonders is the phenomenon of cosmic dust, also known as space dust or interstellar dust. This dust consists of tiny particlesthat are scattered throughout the universe, and they play a crucial role in the formation of stars and planets.One of the most fascinating aspects of cosmic dust is its composition. It is made up of various elements and compounds, such as carbon, oxygen, and silicon. These particles are formed through processes like stellar nucleosynthesis and supernova explosions. They can range in size from a few nanometers to a few micrometers, and they are so small that they can easily be influenced by the electromagnetic forces present in space.The presence of cosmic dust has a significant impact onthe universe. It plays a crucial role in the formation of stars and planets. When clouds of gas and dust cometogether under the force of gravity, they can collapse and form protostars. The dust particles act as a catalyst, allowing the gas to cool and condense into solid objects. Over time, these protostars can evolve into fully-fledged stars, with planets forming around them.Furthermore, cosmic dust also has implications for our understanding of the origins of life. It is believed that the building blocks of life, such as amino acids andorganic molecules, can be found within these dust particles. As these particles travel through space, they can be transported to other star systems, potentially seeding the formation of life on other planets.中文回答:宇宙是一个广阔的世界,充满了无数的奇迹和谜团。
精氨酸侧链和核酸碱基间离子氢键作用强度分析李蕾;黄翠英;姜笑楠;高希婵;王长生【摘要】The optimal structures of twenty-two hydrogen-bonded complexes composed of one charged arginine side chain molecule and one nucleic acid base in gas phase were obtained at the MP2/6-31+G( d,p) level. The binding energies in gas phase were evaluated at the MP2/aug-cc-pVTZ level including basis set superposi-tion error( BSSE ) correction. The optimal structures for these hydrogen-bonded complexes in water solvent were further obtained by using PCM model combined with the MP2/6-31+G ( d, p ) method. The binding energies in water solvent were evaluated by using PCM model combined with the MP2/aug-cc-pVTZ method. It is found that the ionic hydrogen bonding strength between the arginine side chain and one of the five nucleic acid bases highly correlates to the charge transfer between the two monomers, the electron density at the hydro-gen bond critical point, and the second-order stabilization energy. Compared to the neutral hydrogen bond, the ionic hydrogen bond exhibits more significant covalent character. It is also found that the stability of the hydrogen-bonded complexes can be predicted according to the enthalpy change of the protonation reaction of the nucleic acid bases. The more negative the enthalpy change of the protonation reaction, the more stable the hydrogen-bonded complexes.%采用MP2/6-31+G( d,p)方法优化得到了22个由精氨酸侧链与碱基尿嘧啶、胸腺嘧啶、胞嘧啶、鸟嘌呤及腺嘌呤形成的氢键复合物的气相稳定结构,使用包含BSSE校正的MP2/aug-cc-pVTZ方法计算得到了复合物的气相结合能,通过 MP2/6-31+G(d,p)方法和 PCM 模型优化得到了复合物的水相稳定结构,采用MP2/aug-cc-pVTZ方法和PCM模型计算得到了复合物的水相结合能。
是尘埃也是宇宙作文英文回答:Dust, a common substance found on Earth, is also present in the vast expanse of the universe. It may seem insignificant, but dust plays a crucial role in shaping the cosmos. From a scientific perspective, dust particles are made up of various elements, such as carbon, oxygen, and silicon. These particles are created through processes like stellar nucleosynthesis, supernova explosions, and even the collisions between celestial bodies.In the universe, dust serves as the building blocks for the formation of stars and planets. When dust particles come together under the force of gravity, they form dense clouds known as molecular clouds. Within these clouds, the dust particles clump together and eventually become protostars. These protostars undergo further gravitational collapse, leading to the ignition of nuclear fusion and the birth of stars. Without dust, the formation of stars andthe existence of galaxies would not be possible.Not only does dust contribute to the creation of celestial bodies, but it also plays a role in the evolution of galaxies. Dust particles absorb and scatter light, affecting the appearance of distant galaxies. This phenomenon, known as interstellar extinction, can alter the color and brightness of the light emitted by stars within galaxies. By studying the effects of dust on the light from distant galaxies, astronomers can gain insights into the composition and distribution of dust in the universe.Moreover, dust has implications for our understanding of the origins of life. Dust particles contain organic molecules, which are the building blocks of life as we know it. These molecules can be transported across space by comets or meteorites, potentially seeding the formation of life on other planets. In fact, scientists have found amino acids, the building blocks of proteins, in dust particles collected from comets. This discovery suggests that the ingredients necessary for life may be widespread throughout the universe.中文回答:尘埃,一种在地球上常见的物质,也存在于广袤的宇宙中。
分子生物学名词解释大全AAbundance (mRNA 丰度):指每个细胞中mRNA 分子的数目。
Abundant mRNA(高丰度mRNA):由少量不同种类mRNA组成,每一种在细胞中出现大量拷贝。
Acceptor splicing site (受体剪切位点):内含子右末端和相邻外显子左末端的边界。
Acentric fragment(无着丝粒片段):(由打断产生的)染色体无着丝粒片段缺少中心粒,从而在细胞分化中被丢失。
Active site(活性位点):蛋白质上一个底物结合的有限区域。
Allele(等位基因):在染色体上占据给定位点基因的不同形式。
Allelic exclusion(等位基因排斥):形容在特殊淋巴细胞中只有一个等位基因来表达编码的免疫球蛋白质。
Allosteric control(别构调控):指蛋白质一个位点上的反应能够影响另一个位点活性的能力。
Alu-equivalent family(Alu 相当序列基因):哺乳动物基因组上一组序列,它们与人类Alu家族相关。
Alu family (Alu家族):人类基因组中一系列分散的相关序列,每个约300bp长。
每个成员其两端有Alu 切割位点(名字的由来)。
α-Amanitin(鹅膏覃碱):是来自毒蘑菇Amanita phalloides 二环八肽,能抑制真核RNA聚合酶,特别是聚合酶II 转录。
Amber codon (琥珀密码子):核苷酸三联体UAG,引起蛋白质合成终止的三个密码子之一。
Amber mutation (琥珀突变):指代表蛋白质中氨基酸密码子占据的位点上突变成琥珀密码子的任何DNA 改变。
Amber suppressors (琥珀抑制子):编码tRNA的基因突变使其反密码子被改变,从而能识别UAG 密码子和之前的密码子。
Aminoacyl-tRNA (氨酰-tRNA):是携带氨基酸的转运RNA,共价连接位在氨基酸的NH2基团和tRNA 终止碱基的3¢或者2¢-OH 基团上。
巨噬细胞极化在腹主动脉瘤形成中的研究进展①吴亦昊张昊涂思梅殷宇涵韩彦槊(大连理工大学生命科学与药学学院,盘锦 124221)中图分类号R543.1+6 文献标志码 A 文章编号1000-484X(2023)05-1065-08[摘要]慢性炎症反应是腹主动脉瘤(AAA)形成和破裂的核心环节。
有研究证明,循环单核细胞源性巨噬细胞的极化状态可通过多种途径调控AAA的发生发展。
浸润后的巨噬细胞受不同刺激极化为以M1型和M2型巨噬细胞为主的各类极化表型,既能通过释放细胞因子作用于其他免疫细胞调控炎症反应,也能通过细胞间通讯影响细胞外基质(ECM)的重塑过程。
本文就巨噬细胞极化在AAA发生发展中的研究进展进行综述,旨在揭示巨噬细胞极化影响AAA的机制,以期通过作用于巨噬细胞极化的靶点治疗AAA。
[关键词]腹主动脉瘤;巨噬细胞;极化;细胞通讯;靶点Research progress of macrophage polarization in formation of abdominal aortic aneurysmWU Yihao,ZHANG Hao,TU Simei,YIN Yuhan,HAN Yanshuo. School of Life and Pharmaceutical Sciences,Dalian University of Technology, Panjin 124221, China[Abstract]Chronic inflammatory response is the key link in formation and rupture of abdominal aortic aneurysm (AAA). Studies have proved that the polarization types of circulating monocyte-derived macrophages can regulate the occurrence and development of AAA through a variety of ways. Infiltrated macrophages are polarized by different stimuli into various types of polarization phenotypes,mainly M1 and M2 macrophages, which can not only regulate inflammatory response by releasing cytokines on other immune cells, but also through intercellular communication affects the remodeling process of extracellular matrix (ECM). This review summarizes the research progress of macrophage polarization in occurrence and development of AAA, aiming to reveal the mechanism of macrophage polarization affecting AAA, in order to treat AAA by acting on targets of macrophage polarization.[Key words]Abdominal aortic aneurysm;Macrophages;Polarization;Cell communication;Target腹主动脉瘤(abdominal aortic aneurysm,AAA)是由多种因素引起的具有潜在破裂风险的主动脉局部病理扩张性疾病。
prusiner的科学贡献-回复【Prusiner的科学贡献】Stanley B. Prusiner是美国著名的生物学家和神经学家,因其对于传染性蛋白质疾病(传染性海绵状脑病)的研究和发现,并提出孤立性埃森基似变性病(PrPSc)假说,而获得了2007年诺贝尔生理学或医学奖的殊荣。
Prusiner的贡献不仅深刻地改变了人们对传染病的理解,也为神经退行性疾病、蛋白质聚集性疾病的研究以及治疗提供了宝贵的思路。
那么,Prusiner的科学贡献是如何逐步展开并影响着相关领域的呢?首先,Prusiner于1982年发表的一篇论文中首次提出了突破性的假说,即孤立性埃森基似变性病的传播是由一种异常的蛋白质引起的。
他将这种异常的蛋白质命名为PrPSc,与正常的神经元细胞表面蛋白质称为PrPC。
这一假说提出了一种全新的传染机制,挑战了当时传染病研究领域对于传染体(如病毒或细菌)的传播观念。
Prusiner将PrPSc定义为一种感染物,可以通过蛋白质迭加的方式来传播,并进一步引起神经元的丧失和神经退化。
这个假说第一次明确地将蛋白质聚集与疾病的发生联系在一起,为后续相关疾病的研究打下了坚实的基础。
接下来,Prusiner和他的团队开始通过一系列实验证据来验证PrPSc假说。
他们利用高度纯化的PrPSc蛋白,成功地将其在实验条件下转化为由正常蛋白质PrPC转变而来的PrPSc蛋白,通过蛋白质传播来研究这种转变过程。
这一实验证明了PrPSc可以通过自我复制的方式进行传播,从而引起突变形式的PrPC并且蔓延至周围的细胞。
这些实验为PrPSc假说的有效性提供了强有力的证据,并为后续相关疾病的研究奠定了实验基础。
此后,Prusiner的研究还涉及到其他蛋白质聚集性疾病,如阿尔茨海默病、帕金森病、帕金森误谬病等。
他的团队发现,这些疾病中与传播机制相关的异常蛋白质类似于PrPSc,存在着类似的传播和蔓延过程。
通过对于这些疾病的研究,Prusiner进一步拓展了对于蛋白质聚集性疾病的理解,提出了“传染性蛋白质假说”,并对于其病理机制和治疗方式提供了新思路。
a r X i v :0707.2187v 1 [a s t r o -p h ] 15 J u l 2007Nucleosynthesis in Core-Collapse Supernovae and GRB–Metal-Poor Star Connection K.Nomoto ∗,N.Tominaga ∗,M.Tanaka ∗,K.Maeda †and H.Umeda ∗∗Department of Astronomy,University of Tokyo,Bunkyo-ku,Tokyo 113-0033,Japan †Max-Planck-Institut für Astrophysik,85741Garching,Germany Abstract.We review the nucleosynthesis yields of core-collapse supernovae (SNe)for various stellar masses,explosion energies,and parison with the abundance patterns of metal-poor stars provides excellent opportunities to test the explosion models and their nucleosynthesis.We show that the abundance patterns of extremely metal-poor (EMP)stars,e.g.,the excess of C,Co,Zn relative to Fe,are in better agreement with the yields of hyper-energetic explosions (Hypernovae,HNe)rather than normal supernovae.We note that the variation of the abundance patterns of EMP stars are related to the diversity of the Supernova-GRB connection.We summarize the diverse properties of (1)GRB-SNe,(2)Non-GRB HNe/SNe,(3)XRF-SN,and (4)Non-SN GRB.In particular,the Non-SN GRBs (dark hypernovae)have been predicted in order to explain the origin of C-rich EMP stars.We show that these variations and the connection can be modeled in a unified manner with the explosions induced by relativistic jets.Finally,we examine whether the most luminous supernova 2006gy can be consistently explained with the pair-instability supernova model.Keywords:gamma rays:bursts —nuclear reactions,nucleosynthesis,abundances —stars:abun-dances —stars:Population II —supernovae:general PACS:26.20.+f,26.30.+k,26.50.+x,,97.60.Bw To appear in "Supernova 1987A:20Years After:Supernovae and Gamma-Ray Bursters",eds.S.Immler,K.Weiler,&R.McCray (American Institute of Physics)(2007)INTRODUCTION Massive stars in the range of 8to ∼130M ⊙undergo core-collapse at the end of their evolution and become Type II and Ib/c supernovae (SNe)unless the entire star collapsesinto a black hole with no mass ejection [e.g.,4,33,23].The explosion energies of core-collapse supernovae are fundamentally important quantities,and an estimate of E ∼1×1051ergs has often been used in calculating nucleosynthesis and the impact on the interstellar medium.(In the present paper,we use the explosion energy E for the final kinetic energy of explosion,and E 51=E /1051erg.)A good example is SN1987A in the Large Magellanic Cloud,whose energy is estimated to be E 51=1.0−1.5from its early light curve [e.g.,4,55].One of the most interesting recent developments in the study of supernovae is the dis-covery of some very energetic supernovae,whose kinetic energy (KE)exceeds 1052erg,more than 10times the KE of normal core-collapse SNe.The most luminous and power-ful of these objects,the Type Ic supernova (SN Ic)1998bw,was linked to the gamma-rayparison between the abundance pattern of VMP stars[11](filled circles with error bars)and the IMF integrated yield of Pop III SNe from10M⊙to50M⊙[75]burst GRB980425[25],thus establishing for thefirst time a connection between long-duration gamma-ray bursts(GRBs)and the well-studied phenomenon of core-collapse SNe[83].However,SN1998bw was exceptional for a SN Ic:it was as luminous at peak as a SN Ia,indicating that it synthesized∼0.5M⊙of56Ni,and its KE was estimated at E51∼30[35].In the present paper,we use the term’Hypernova(HN)’to describe such a hyper-energetic supernova with E∼>1052ergs without specifying the explosion mechanism [57].Following SN1998bw,other“hypernovae”of Type Ic have been discovered or recognized[59].Nucleosynthesis features in such hyper-energetic(and hyper-aspherical)supernovae must show some important differences from normal supernova explosions.This might be related to the unpredicted abundance patterns observed in the extremely metal-poor (EMP)halo stars[e.g.,32,6].This approach leads to identifying the First Stars in the Universe,i.e.,metal-free,Population III(Pop III)stars which were born in a primordial hydrogen-helium gas cloud.This is one of the important challenges of the current astronomy.ABUNDANCE PATTERS OF METAL-POOR STARSWe have calculated the nucleosynthesis yields for various stellar masses,explosion energies,and metallicities[61,39,75].From the light curve and spectrafitting of individual supernova,the relations between the mass of the progenitor,explosion energy, and produced56Ni mass have been obtained.The enrichment by a single SN can dominate the preexisting metal contents in the early universe.Therefore,the comparison between the SN model and the abundance patterns of EMP stars can provide a new way tofind out the individual SN nucleosyn-thesis.FIGURE3.Averaged elemental abundances of stars with[Fe/H]=−3.7[11]compared with the hypernova yield(20M⊙,E51=10).model of15M⊙and E51=1(Fig.2)[60,75].In the normal SN model(Fig.2),the mass-cut is determined to eject Fe of mass0.14 M⊙).Then the yields are in reasonable agreements with the observations for[(Na,Mg, Si)/Fe],but give too small[(Mn,Co,Ni,Zn)/Fe]and too large[(Ca,Cr)/Fe].In the HN model(Fig.3),these ratios are in much better agreement with observations. The ratios of Co/Fe and Zn/Fe are larger in higher energy explosions since both Co and Zn are synthesized in complete Si burning at high temperature region(see the next subsection).To account for the observations,materials synthesized in a deeper complete Si-burning region should be ejected,but the amount of Fe should be small.This is realized in the mixing-fallback models[78,79].SUPERNOV A–GAMMA-RAY BURST CONNECTIONWe have shown that nucleosynthesis in HNe is in better agreement with the abundance pattern of EMP stars.Thus it would be useful to examine the GRB-SN connection in relation to the GRB-First Star connection.GRBs at sufficiently close distances(z<0.2)have been found to be ac-companied by luminous core-collapse SNe Ic(GRB980425/SN1998bw[25]; GRB030329/SN2003dh[68,34];GRB031203/SN2003lw[43]).Such GRB-SN connection is now revealing quite a large diversity as follows.(1)GRB-SNe:The three SNe Ic associated with the above GRBs have similar prop-erties;showing broader lines than normal SNe Ic(Fig.4:so-called broad-lined SNe [83,50]).These three GRB-SNe have been all found to be Hypernovae(HNe),i.e.,very energetic supernovae,whose isotropic kinetic energy(KE)exceeds1052erg,about10 times the KE of normal core-collapse SNe[35,57,59].(2)Non-GRB HNe/SNe:These SNe show broad line features but are not associated with GRBs(SN1997ef[36];SN2002ap[44];SN2003jd[45]).These are either lessgive the estimates of M ej and E.The timescale of the LC around maximum brightness reflects the timescale for optical photons to diffuse[3].For larger M ej and smaller E, the LC peaks later and the LC width becomes broader because it is more difficult for photons to escape.From the synthetic spectra and light curves,it was interpreted as the explosion of a massive star,with E51∼30and M ej∼10M⊙[35].Also the very high luminosity of SN1998bw indicates that a large amount of56Ni(∼0.5M⊙)was synthesized in the explosion.The ejected56Ni mass is estimated to be M(56Ni)∼0.3−0.7M⊙(e.g.,[46])which is 4to10times larger than typical SNe Ic(M(56Ni)∼0.07M⊙[54]).The other two GRB-SNe,2003dh and2003lw,are also characterized by the very broad line features and the very high luminosity.M ej and E are estimated from synthetic spectra and light curves and summarized in Figure7[53,15,46].It is clearly seen that GRB-SNe are the explosions of massive progenitor stars(with the main sequence mass of M ms∼35−50M⊙),have large explosion kinetic energies(E51∼30−50),synthesized large amounts of56Ni(∼0.3−0.5M⊙).These GRB-associated HNe(GRB-HNe)are suggested to be the outcome of very energetic black hole(BH)forming explosions of massive stars(e.g.,[35]).Non-GRB HypernovaeThese HNe show spectral features similar to those of GRB-SNe but are not known to have been accompanied by a GRB.The estimated M ej and E,obtained from synthetic light curves and spectra,show that there is a tendency for non-GRB HNe to have smaller M ej and E,and lower luminosities as summarized in Figures7and8.SN1997ef is found to be the HN class of energetic explosion,although E/M ej is a factor3smaller than GRB-SNe.It is not clear whether SN1997ef is not associated with GRB because of this smaller E/M ej or it was actually associated with the candidate GRB 971115.SN2002ap was not associated a GRB and no radio has been observed.It has similar spectral features,but narrower and redder(Fig.4),which was modeled as a smaller energy explosion,with E51∼4and M ej∼3M⊙[44].The early time spectrum of SN2003jd is similar to SN2002ap.Interestingly,its neb-ular spectrum shows a double peak in O-emission lines[45].This has exactly confirmed the theoretical prediction by the asymmetric explosion model[41].In this case,the ori-entation effect might cause the non-detection of a GRB.XRF–SupernovaeGRB060218is the second closest event as ever(∼140Mpc).The GRB was weak [10]and classified as X-Ray Flash(XRF)because of its soft spectrum.The presence of SN2006aj was soon confirmed[64,49].Here we summarize the properties of SN2006aj by comparing with other SNe Ic.SN 2006aj has several features that make it unique.It is less bright than the other GRB/SNe (Fig.4).Its rapid photometric evolution is very similar to that of a dimmer,non-GRB SN 2002ap[44],but it is somewhat faster.Although its spectrum is character-ized by broader absorption lines as in SN 1998bw and other GRB/SN,they are not as broad as those of SN 1998bw,and it is much more similar to that of SN 2002ap (Fig.4).The most interesting property of SN 2006aj is surprisingly weak oxygen lines,much weaker than in Type Ic SNe.By modeling the spectra and the light curve,we derive for SN 2006aj M ej ∼2M ⊙and E 51∼ck of oxygen in the spectra indicates ∼1.3M ⊙of O,and oxygen is still the dominant element.We synthesize the theoretical light curve and find that the best match is achieved with a total 56Ni mass of 0.21M ⊙in which 0.02M ⊙is located above 20,000km s −1(Fig.4).The properties of SN 2006aj (smaller E and smaller M ej )suggest that SN 2006aj is not the same type of event as the other GRB-SNe known thus far.One possibility is that the initial mass of the progenitor star is much smaller than the other GRB-SNe,so that the collapse/explosion generated less energy.If M ms is ∼20−25M ⊙,the star would be at the boundary between collapse to a black hole or to a neutron star.In this mass range,there are indications of a spread in both E and the mass of 56Ni synthesized[29].The fact that a relatively large amount of 56Ni is required in SN 2006aj possibly suggests that the star collapsed only to a neutron star because more core material would be available to synthesize 56Ni in the case.Although the kinetic energy of E 51∼2is larger than the canonical value (1×1051erg,[54])in the mass range of M ms ∼20−25M ⊙,such an energy might be obtained from magnetar-type activity.XRFs may be associated with less massive progenitor stars than those of canonical GRBs,and that the two groups may be differentiated by the formation of a neutron star[52]or a BH.In order for the progenitor star to have been thoroughly stripped of its H and He envelopes,the progenitor may be in a binary system.Non-SN Gamma-Ray BurstsFor recently discovered nearby long-duration GRB 060505(z =0.089,[18])and GRB 060614(z =0.125,[26,18,13,27]),no SN has been detected.Upper limits to brightness of the possible SNe are about 100times fainter than SN 1998bw.These correspond to upper limits to the ejected 56Ni mass of M (56Ni )∼10−3M ⊙.Tominaga et al.[74]calculated the jet-induced explosions (e.g.,[42,51])of the 40M ⊙stars [79,75]by injecting the jets at a radius R ∼900km,corresponding to an enclosed mass of M ∼1.4M ⊙.They investigated the dependence of nucleosynthesis outcome on ˙Edep for a range of ˙E dep ,51≡˙E dep /1051ergss −1=0.3−1500.The diversity of ˙E dep is consistent with the wide range of the observed isotropic equivalent γ-ray energies and timescales of GRBs ([1]and references therein).Variations of activities of the central engines,possibly corresponding to different rotational velocities or magnetic fields,may well produce the variation of ˙Edep .FIGURE5.Top:the ejected56Ni mass(red:explosive nucleosynthesis products,blue:the jet contribu-tion)as a function of the energy deposition rate.The background color shows the corresponding SNe(red: GRB-HNe,yellow:sub-luminous SNe,blue:faint SNe,green:GRBs060505and060614).Vertical lines divide the resulting SNe according to their brightness.Bottom:the dependence of abundance ratio[C/Fe] on the energy deposition rate.The background color shows the corresponding metal-poor stars(yellow: EMP,red:CEMP,blue:HMP stars).NUCLEOSYNTHESIS IN JET-INDUCED EXPLOSIONS Nucleosynthetic properties found in the above diversity are connected to the variation of the abundance patterns of extremely-metal-poor stars,such as the excess of C,Co,Zn relative to Fe.Such a connection are modeled in a unified manner with the jet-induced explosion model.We have computed hydrodynamics and nucleosynthesis for the explosions induced by relativistic jets.We have shown that(1)the explosions with large energy deposition rate,˙Edep,are observed as GRB-HNe and their yields can explain the abundances of normal EMP stars,and(2)the explosions with small˙E dep are observed as GRBs without bright SNe and can be responsible for the formation of the CEMP and the HMP stars.We thus propose that GRB-HNe and GRBs without bright SNe belong to a continuous series of BH-forming massive stellar deaths with the relativistic jets of different˙E dep.-10123-101234551015202530Z[X /F e ]FIGURE 6.A comparison of the abundance patterns of metal-poor stars and of our models.Top :typical EMP (red dots ,[11])and CEMP (blue triangles ,CS 22949–37,[16])stars and models with ˙E dep ,51=120(solid line )and =3.0(dashed line ).Bottom :HMP stars:HE 1327–2326,(red dots ,e.g.,[20]),and HE 0107–5240,(blue triangles ,[12,8])and models with ˙Edep ,51=1.5(solid line )and =0.5(dashed line ).Diversity of 56Ni MassThe top panel of Figure 5shows the dependence of the ejected M (56Ni )on the energy deposition rate ˙Edep .For lower ˙E dep ,smaller M (56Ni )is synthesized in explosive nucleosynthesis because of lower post-shock densities and temperatures (e.g.,[42,51]).If ˙E dep ,51∼>3,the jet injection is initiated near the bottom of the C+O layer,leading to the synthesis of M (56Ni )∼>10−3M ⊙.If ˙E dep ,51<3,on the other hand,the jet injection is delayed and initiated near the surface of the C+O core;then the ejected 56Ni is as small as M (56Ni )<10−3M ⊙.56Ni contained in the relativistic jets is only M (56Ni )∼10−6−10−4M ⊙because the total mass of the jets is M jet ∼10−4M ⊙in our model with Γjet =100and E dep =1.5×1052ergs.Thus the 56Ni production in the jets dominates over explosive nucleosynthesis in the stellar mantle only for ˙E dep ,51<1.5in the present model.For high energy deposition rates (˙E dep ,51∼>60),the explosions synthesize large M (56Ni )(∼>0.1M ⊙)being consistent with GRB-HNe.The remnant mass was M start rem ∼1.5M ⊙when the jet injection was started,but it grows as material is accreted from the equatorial plane.The final BH masses range from M BH =10.8M ⊙for ˙Edep ,51=60toM BH =5.5M ⊙for ˙E dep ,51=1500,which are consistent with the observed masses of stellar-mass BHs [5].The model with ˙Edep ,51=300synthesizes M (56Ni )∼0.4M ⊙and the final mass of BH left after the explosion is M BH =6.4M ⊙.For low energy deposition rates (˙Edep ,51<3),the ejected 56Ni masses (M (56Ni )<10−3M ⊙)are smaller than the upper limits for GRBs 060505and 060614.The final BH mass is larger for smaller ˙Edep .While the material ejected along the jet-direction involves those from the C+O core,the material along the equatorial plane fall back.If the explosion is viewed from the jet direction,we would observe GRB without SN re-brightening.This may be the situation for GRBs 060505and 060614.In particular,for ˙Edep ,51<1.5,56Ni cannot be synthesized explosively and the jet component of the Fe-peak elements dominates the total yields (Fig.6).The models eject very little M (56Ni )(∼10−6M ⊙).For intermediate energy deposition rates (3∼<˙E dep ,51<60),the explosions eject10−3M ⊙∼<M (56Ni )<0.1M ⊙and the final BH masses are 10.8M ⊙∼<M BH <15.1M ⊙.The resulting SN is faint (M (56Ni )<0.01M ⊙)or sub-luminous (0.01M ⊙∼<M (56Ni )<0.1M ⊙).Nearby GRBs with faint or sub-luminous SNe have not been observed.This may be because they do not occur intrinsically in our neighborhood or because the number of observed cases is still too small.In the latter case,further observations may detect GRBs with a faint or sub-luminous SN.Abundance Patterns of C-rich Metal-Poor StarsThe bottom panel of Figure 5shows the dependence of the abundance ratio [C/Fe]on ˙Edep .Lower ˙E dep yields larger M BH and thus larger [C/Fe],because the infall decreases the amount of inner core material (Fe)relative to that of outer material (C)(see also [42]).As in the case of M (56Ni ),[C/Fe]changes dramatically at ˙Edep ,51∼3.The abundance patterns of the EMP stars are good indicators of SN nucleosynthesis because the Galaxy was effectively unmixed at [Fe/H]<−3(e.g.,[76]).They are classified into three groups according to [C/Fe]:(1)[C/Fe]∼0,normal EMP stars (−4<[Fe/H]<−3,e.g.,[11]);(2)[C/Fe]∼>+1,Carbon-enhanced EMP (CEMP)stars (−4<[Fe/H]<−3,e.g.,CS 22949–37[16]);(3)[C/Fe]∼+4,hyper metal-poor (HMP)stars ([Fe/H]<−5,e.g.,HE 0107–5240[12,8];HE 1327–2326[20]).Figure 6shows that the general abundance patterns of the normal EMP stars,the CEMP star CS 22949–37,and the HMP stars HE 0107–5240and HE 1327–2326are reproduced by models with ˙Edep ,51=120,3.0,1.5,and 0.5,respectively.The model for the normal EMP stars ejects M (56Ni )∼0.2M ⊙,i.e.a factor of 2less than SN 1998bw.On the other hand,the models for the CEMP and the HMP stars eject M (56Ni )∼8×10−4M ⊙and 4×10−6M ⊙,respectively,which are always smaller than the upper limits for GRBs 060505and 060614.The N/C ratio in the models for CS 22949–37and HE 1327–2326is enhanced by partial mixing between the He and H layers during presupernova evolution [37].FIGURE7.The kinetic explosion energy E as a function of the main sequence mass M of the progenitors for several supernovae/hypernovae.SNe that are observed to show broad-line features are indicated.Hypernovae are the SNe with E51>10.FIGURE8.The ejected56Ni mass as a function of the main sequence mass M of the progenitors for several supernovae/hypernovae.DISCUSSIONThe large Zn and Co abundances and the small Mn and Cr abundances observed in very metal-poor stars can better be explained by introducing HNe.This would imply that HNe have made significant contributions to the early Galactic chemical evolution,In theoretical models,some element ratios,such as(K,Sc,Ti,V)/Fe,are too small, while some ratios such as Cr/Fe are too large compared with the observed abundance ratios[11].Underproduction of Sc and K may require significantly higher entropyenvironment for nucleosynthesis,e.g.,the“low density”progenitor models for K,Sc, and Ti[79,24].GRBs would have possible nucleosynthesis site,such as accretion disks around the black hole[65].Neutrino processes in the deepest layers of SN ejecta and a possible accretion disk around a black hole would open a new window for SN nucleosynthesis[65,21,22,80].GRB,Hypernovae,and Broad-LinesFigures7and8summarize the properties of core-collapse SNe as a function of the main-sequence mass M ms of the progenitor star[58].The broad-line SNe include both GRB-SNe and Non-GRB SNe.(1)GRB vs.Non-GRB:Three GRB-SNe are all similar Hypernovae(i.e.,E51∼>10. Thus E could be closely related to the formation of GRBs.SN1997ef seems to be a marginal case.E/M ej could be more important because SN1997ef has significantly smaller E/M ej than GRB-SNe.(2)Broad-Line features:The mass contained at v>30,000km s−1(or even higher boundary velocity)might be critical in forming the broad-line features,although further modeling is required to clarify this point[61].Black Holes vs.Neutron StarsThe discovery of XRF060218/SN2006aj and their properties extend the GRB-HN connection to XRFs and to the HN progenitor mass as low as∼20M⊙.The XRF060218 may be driven by a neutron star rather than a black hole.Thefinal fate of20-25M⊙stars show interesting variety.Even normal SN Ib2005bf is very different from previously known SNe/HNe[73,19].This mass range corresponds to the transition from the NS formation to the BH formation.The NSs from this mass range could be much more active than those from lower mass range because of possibly much larger NS masses(near the maximum mass)or possibly large magneticfield (magnetar).XRFs and GRBs from the mass range of20-25M⊙might form a different population.Hypernovae of Type II and Type Ib?Suppose that smaller losses of mass and angular momentum from low metallicity massive stars lead to the formation of more rapidly rotating NSs or BHs and thus more energetic explosions.Then we predict the existence of Type Ib and Type II HNe[30]. So far all observed HNe are of Type Ic.However,most of SNe Ic are suggested to have some He[9].If even the small amount of radioactive56Ni is mixed in the He layer, the He feature should be seen[40,56].For HNe,the upper mass limit of He has been estimated to be∼2M⊙[44]for the case of no He mixing.If He features would beA b s o l u t e m a g n i t u d e s Days since the explosion date-22-21-20-19-18-17M a g n i t u d e s Days FIGURE 9.(Left)Comparison between LCs of SNe 1998bw (open square [25]),2002ic (open circle [28]),and 2006gy (fulled triangle [66]).(Right)Comparison between R-and r-band LCs of SN 2006gy[63,66]and synthetic LCs for a model with M ej =53M ⊙,E 51=64,and M (56Ni )=15M ⊙and a PISNmodel with M ej =166M ⊙,E 51=65,and M (56Ni )=15M ⊙.seen in future HN observations,it would provide an important constraint on the models,especially,the fully mixed WR models [85,84,48].MOST LUMINOUS SUPERNOV A 2006GYRecently,several extremely luminous supernovae have been discovered,which includesSNe IIa 1997cy,2002ic,and SN Ic 1999as (Fig.9:left).The energy sources of theseSN light curves (LC)are closely related to SN nucleosynthesis.The post-maximumlight curves (LCs)of SNe IIa are powered by circumstellar interaction [14],althoughwhether the underlying SNe are Ia or Ic is under debate [7].SN 2006gy is the most luminous SN [63,66].It shows hydrogen emission featureslike SNe IIn and IIa to indicate circumstellar interaction.However,the X-ray luminosityis too low to explain the observed optical luminosity [66].This suggests that the LC ofSN 2006gy may be powered by the decays of 56Ni →56Co →56Fe,and the requiredlarge 56Ni mass,M (56Ni ),suggests that SN 2006gy could be a pair-instability supernova(PISN)[78,31]rather than a core-collapse [63,66].We have constructed the LC model of the PISN model as shown by the solid linewith 166M in Fig.9(right).Here we have calculated the evolution from the main-sequence with extensive mass loss to expose a C+O core.The star undergoes PISNwith M ej =166M ⊙,E 51=65,and M (56Ni )=15M ⊙.Here the explosion energy is not afree parameter (like a core-collapse model)but obtained from the nuclear energy releaseassociated with the production of M (56Ni ).Such a large M ej ,which is necessary toproduce large enough M (56Ni ),is too large for the LC.The model LC evolves muchslower than the observed LC of SN 2006gy (red points in Fig.9:right).In order to reproduce the LC of SN 2006gy,we artificially reduce the ejected massof the above exploding model down to M ej =53M ⊙,keeping E 51=64,and M (56Ni )=15M ⊙(the 53M line in Fig.9).In other words,the progenitor should have lost muchmore mass than the actual model,yet produced a large enough amount of 56Ni.These results imply whether SN2006gy is a core-collapse SN or a PISN is not clear yet.The PISN model can produce enough M(56Ni)but M ej might be too large.The core-collapse models currently available could produce too small M(56Ni).Also,the mass loss from such a massive star with solar metallicity would be too large to keep hydrogen-rich circumstellar matter as observed like SNe IIn and IIa[63]. 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