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dealloying and control over dealloying conditions (solution type, solution concentration, temperature and etching duration, etc.). The nanoporous structure could be tuned from homogeneous to bimodal/nested and even to hierarchical. Besides pure metals, nanoporous binary, ternary, and multicomponent alloys could also be fabricated by the dealloying strategy. Moreover, through underpotential deposition or displacement reaction, nanoporous metals could be further modified or decorated to enhance their electrocatalytic performance. For practical applications in fuel cells, other issues should also be taken into consideration, such as long-term stability, scale-up, cost, and so on. © 2017 Wiley-VCH Verlag GmbH & Co. KGaA. All rights reserved. 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[pub_year] => 2017 [eissn] => [dom_ranking] => [application_date] => [from_id] => 76 [profession_stu] => [cauthor_ad] => [Zhang, S] Law School of Shandong UniversityChina [cscd_No] => [abstract_en] => [无可用摘要] [document_No] => [institution_type] => [imf_5] => [attachment_text] => [top_article] => [student_No] => [page] => 196-213 [title_cn] => [article_dt] => Book Chapter [name_editor] => [reference] => Bofeng, C., Vexatious Suits, Complaint Letters and Visits and Chinese Legal Tradition--Issues Concerning Vexatious Suits During the Transforming Period of Law [J] (2004) 2 Peking University Law Journal, p. 226; Yujie, N., The Historical Review and Current Situation of Complaint Letters and Visits in China (2010) 11 Chinese Administration Management, p. 36; Jianbing, C., (2006) Research on the Complaint Letters and Visits System [D], Thesis of Master Degree of East China University of Politics and Law, p. 14; Jianbing, C., Research on the Complaint Letters and Visits System [D], Thesis of Master Degree of East China University of Politics and Law, Shanghai (2006), p. 13; Yanwei, Y., Jurisprudential Analysis of the Complaint Letters and Visits System [D] (2004), p. 5. , Thesis of Master Degree of China University of Political Science and Law, Beijing; Xufeng, Z., The Role of Environmental Citizen Society in Environmental Governance [J] (2008) 10 China Social Sciences Documentation, p. 122; Safeguard One\'s Right While Facing the Pollution Accident, How Far Can the Environmental Court Go, , www.acef.com.cn/site2/envlaw/news/38066.shtml; Zhi Ping, L., (2002) Seeking the Harmony in Natural Order, Chinese Edition, p. 199; Jinfan, Z., (2005) The Tradition and Modern Transition of Chinese Law (the Second Edition), p. 270. , Law Press China; Shijun, Z., The Analysis of the Administrative Resolutions of Environmental Disputes (2003) The Rule of Law Forum, 18 (6), p. 60; Songjie, H., On the Path of the Reform of the System of Letters and Visits Under the Background of Social Transformation [J/OL] The Rule of Law Forum, , http://bbs.chinaeoUrt.org/index.PhP?showtoPie=39039; Jiaxing, L., Jianfeng, P., Civil Procedure Law Course, Peking University Press (2008), p. 178; Chi Yang, C., Environmental Law Introduction, China University of Political Science Press, Beijing (2003), p. 304 [series] => [fund_type] => [create_time] => [research_area] => [sponsor] => [awards_title ] => [publication_type] => [fund_No] => [highly_article] => [cssci_No] => [cite_wos] => [author_jg] => [issue] => [email] => [datebase] => Scopus [degree] => [name_tutor1] => [cauthor_back] => [begin_page] => 196 [publisher] => Taylor and Francis [language] => English [author_fn] => [country] => [pubmedID] => [author_in] => [Zhang, S] Law School of Shandong University, China [check_3Y] => [subject_gb1] => [jcr_wos] => [wos_No] => [standard_in] => Law School of Shandong University, China [cauthor] => [author_gro] => [scopus_No] => 2-s2.0-85042017929 [bulletin_date] => [author_en] => Zhang S. 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Mediat.: An Int. Surv. [format_title_en] => 5cee3a9d88a463e5e87b1421afa10382-316312112 [SYS_TAG] => 3 [format_publication_cn] => [sys_priority_field] => 76 [format_publication_en] => 1158cead4365f8fb7068ffffaedfc971-617810000 [sys_author_in_last_arr] => china [company_id] => 0,0,0,0,0,0,0 [author_id] => 25647,25644,25641 [sys_author_id] => [hints] => 23 [id] => xqpj32YBFjIhTVEbjFv2 [tags] => 0 ) [12] => Array ( [grant_bulletin_date] => [abstract_meeting] => [delivery_No] => [producer] => [ei_No] => [discipline_name] => [isbn] => 9783319530642; 9783319530635 [main_cword] => [abstract_cn] => [keyword_plu] => [book_alias] => [controlled_terms] => [complete_time] => [imf] => [publisher_city] => [uncontrolled_terms] => [conference_ad] => [subsection] => [cite_awos] => [imf_once] => [classification_pub] => [publication_iso ] => [oral_time] => [main_eword] => [awards_type] => [bulletin_No] => [publication_29] => Mycorrhiza - Funct., Divers., State of the Art: Fourth Ed. [pub_year] => 2017 [eissn] => [dom_ranking] => [application_date] => [from_id] => 76 [profession_stu] => [cauthor_ad] => [Manchanda, G] Department of Botany, D.A.V. UniversityIndia; [cscd_No] => [abstract_en] => Soil is a complicate environment, where complex systems of multiple interactions between the organisms take place. Plant health is majorly determined by these vital interactions in the soil. The ubiquitous arbuscular mycorrhizal (AM) fungi and a number of microbes interact synergistically to enhance the fitness of each other as well as plants they are associated with. Both the interacting partners are cross facilitators, where AM fungi provide suitable specialized ecological niches as well as nutrients for bacteria, and in turn bacteria improves the mycorrhization, provides pool of available P and N, and helps in management of biotic and abiotic stresses. Given the importance of AM and the interacting microbes in low-input sustainable agriculture, it is important to understand their interactions. © Springer International Publishing AG 2017. All rights reserved. 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This article will also touch upon the theoretical or known mechanisms by which some airborne particles cause toxicity, including how particle physicochemistry can influence particle deposition and clearance patterns and ultimately lead to different patterns of site-specific or broad-based structural changes in the lungs. © 2018 Elsevier Ltd All rights reserved. [from_id] => 76 [cauthor_ad] => [Madl, A.K] University of CaliforniaUnited States; [hx_id] => 2378 [datebase] => Scopus [sys_level_num] => 6_1 [sys_jg_type] => 11 [title_en] => Particle Toxicities [volume] => 15-15 [source_type] => 351 [pub_year] => 2017 [keyword_en] => Ambient particulate matter; Asbestos; Beryllium; Bronchoalveolar duct junction; Coal dust; Concentrated ambient particles; Fibrosis; Particle toxicities; Respiratory bronchioles; Silica [article_id] => 500355 [begin_page] => 263 [hints] => 27 [publisher] => Elsevier Inc. [doi] => 10.1016/B978-0-12-801238-3.02084-5 [language] => English [batch] => 3243 [publication_en] => Comprehensive Toxicology: Third Edition [email] => akmadl@ucdavis.edu [sys_update_time] => 2018-09-05 15:38:05 [publication_iso] => Compr. Toxicol.: Third Ed. 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[format_scopus_No] => 688a1d9b9152d26ebabd637c08677889-1112034985 [format_doi] => 83a50e9a2c804866c4bcb11de2ff2780-1152132934 [author_in] => [Wang, Y] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan, 250100, China@@@[ Hao, J] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan, 250100, China [reference] => Pope, M.T., Müller, A., Polyoxometalate chemistry: an old field with new dimensions in several disciplines (1991) Angew Chem Int Ed Engl, 30, pp. 34-48; Pope, M.T., (1983) Heteropoly and isopoly oxometalates, , Springer, Berlin; Rao, C.N.R., Müller, A., Cheetham, A.K., (2006) The chemistry of nanomaterials: synthesis, properties and applications, , Wiley, New York; Gouzerh, P., Proust, A., Main-group element, organic, and organometallic derivatives of polyoxometalates (1998) Chem Rev, 98, pp. 77-112; Weinstock, I.A., Homogeneous-phase electron-transfer reactions of polyoxometalates (1998) Chem Rev, 98, pp. 113-170; Müller, A., Peters, F., Pope, M.T., Gatteschi, D., Polyoxometalates: very large clusters nanoscale magnets (1998) Chem Rev, 98, pp. 239-272; Mizuno, N., Kamata, K., Catalytic oxidation of hydrocarbons with hydrogen peroxide by vanadium-based polyoxometalates (2011) Coord Chem Rev, 255, pp. 2358-2370; Hill, C.L., Special issue: polyoxometalates in catalysis-foreword (2007) J Mol Catal A: Chem, 262, pp. 1-1; Rhule, J.T., Hill, C.L., Judd, D.A., Schinazi, R.F., Polyoxometalates in medicine (1998) Chem Rev, 98, pp. 327-358; Hasenknopf, B., Polyoxometalates: introduction to a class of inorganic compounds and their biomedical applications (2005) Front Biosci, 10, p. 275; Long, D.L., Burkholder, E., Cronin, L., Polyoxometalate clusters, nanostructures and materials: from self-assembly to designer materials and devices (2007) Chem Soc Rev, 36, pp. 105-121; Kim, K.C., Pope, M.T., Cation-directed structure changes in polyoxometalate chemistry (1999) equilibria between isomers of bis (9-tungstophosphatodioxouranate (VI)) complexes. 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Pitois, O., Francois, B., Crystallization of condensation droplets on a liquid surface (1999) Colloid Polym Sci, 277, pp. 574-578; Stenzel, M.H., Formation of regular honeycomb-patterned porous film by self-organization (2002) Aust J Chem, 55, pp. 239-243; Block, M.J., Surface tension as the cause of Bénard cells and surface deformation in a liquid film (1956) Nature, 178, pp. 650-651; Tang, P., Hao, J., Photoluminescent honeycomb films templated by microwater droplets (2010) Langmuir, 26, pp. 3843-3847; Tang, P., Hao, J., Directionally electrodeposited gold nanoparticles into honeycomb macropores and their surface-enhanced Raman scattering (2010) New J Chem, 34, pp. 1059-1062 [format_title_en_publication_en_pub_year] => f69637be367fd20f6d5f71f8cd3075e81576703649 [abstract_en] => Various types of nano-scale polyoxometalates (POMs) with beautiful topologies has been synthesized successfully by destroying the hydration shell of the anions caused by the extremely hydrophilic surface. Their magnetic, electronic, and photoluminescent properties and valuable applications in catalysis, medicine, and material science are discussed. Meanwhile, the last ten years have witnessed a remarkable development in terms of preformed organic-inorganicPOM-based hybrid systems for the rational design of functional architectures, assemblies and materials. Hydrophilic POMs of different sizes and shapes can interact with hydrophobic cationic surfactants, the resulting materials show amphiphilic properties with electrostatic interactions between the hydrophilic and hydrophobic components, called Surfactant-Encapsulated Clusters (SECs) or Surfactant-Encapsulated-POMs (SEPs). This hydrophobic surfactant-encapsulated clusters (HSECs) can fabricated through covalent or non-covalent interaction, which can construct ordered self-assembly, e.g. robust onionlike structures, honeycomb films or giant vesicle. Moreover, This ordered giant vesicle acts as building block to fabricate three dimensional structures. In addition, SECs can further self-assemble to give a variety of nanostructures on various surfaces/interfaces, among them, the most representative nanostructures discussed below is ordered honeycomb films, which is carried out by a simple solvent-evaporation method. It is reasonable to assume that the condensed water microdroplets induced by the quick evaporation of solvents play an important role as template for the formation of pores. Various factors are being investigated to construct thin films with different morphologies. We hope the inorganic-organic hybrid functional materials based on POMs will bridge polyoxometalate chemistry and material chemistry, which can be further explored application in many fields. © Springer Nature Singapore Pte Ltd. 2017. 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9781107176324 [scopus_No] => 2-s2.0-85048082798 [batch2] => 6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-85048082798&doi=10.1017%2f9781316816912.007&partnerID=40&md5=9be06f7fde0ea00ccd6ab2fb56b9a759 [tag] => 0 [author_en] => Shen W. [format_scopus_No] => a13c2eda949fc7c8a16a32f27e00e5b2907181293 [format_doi] => 1bb84491d4d9e52a9ea2a82e95f28807178854712 [author_in] => [Shen, W] Shandong University Law School, China [reference] => Shiyuan, H., PRC CCL and CISG (2011) Jinan Journal (Section of Philosophy and Social Sciences), 2, p. 11; Scott, R.E., The Theory of Self-Enforcing Indefinite Agreements (2003) Columbia Law Review, 103, p. 1641; Kangsheng, H., (1999) Zhonghua Renmin Gongheguo Hetongfa Shiyi, p. 72. , Commentary on the PRC CCL) (PRC: Law Press China; Ling, B., (2002) CCL in China, p. 216. , Hong Kong, Singapore, and Malaysia: Sweet & Maxwell Asia; Farnsworth, E.A., Pre-contractual Liability and Preliminary Agreements: Fair Dealing and Failed Negotiations (1987) Columbia Law Review, 87, p. 222; Liming, W., (2002) Study on CCL, 1, pp. 312-313. , PRC: People’s University Press; Zhang, M., (2006) Chinese CCL, p. 87. , Leiden and Boston: Martinus Nijhoff Publishers; Dongxia, X., Ting, Y., Clarifications and Implications - China’s New Judicial Interpretation of CCL (2012) China Bulletin, , www.lexology.com/library/detail.aspx?g=1c022b01-a408-4666-9a40-86c96f820153, July; Xiaoming, X., (2012) The Comprehension and Application of the Supreme People’s Court Regarding the Interpretation of Sale and Purchase Contracts, p. 61. , Beijing: The People’s Court Press; Hondius, E.H., (1991) Pre-contractual Liability: Reports to the XIIIth Congress of the International Academy of Comparative Law; Giliker, P., A Role for Tort in Precontractual Negotiations? An Examination of English, French, and Canadian Law (2003) International and Comparative Law Quarterly, pp. 52 and 969; Farnsworth, Pre-contractual Liability and Preliminary Agreements, (6), pp. 259-260; Huixing, L., Pre-contractual Liability under the SPC Interpretation 2012, , www.lawinnovation.com/html/zgfx50rlt/7884.shtml, (last visit on 6 January 2013); Furmston, M., (2010) The Law of Contract, p. 447. , UK: LexisNexis 4th ed; Furmston, The Law of Contract, (16), p. 489; Winfield, P.H., (1952) The Law of Quasi-Contracts, p. 53. , London: Sweet & Maxwell; McGhee, J., (2010) Snell’s Equity, , UK: Sweet & Maxwell, 32nd ed; Sen, A., (2009) The Idea of Justice, , London: Penguin Books; Sandel, M.J., (2009) Justice: What’s the Right Thing to Do?, , London: Penguin Books; Scanlon, T.M., (1982) Contractualism and Utilitarianism, pp. 110-112 and 103. , Amartya Sen and Bernard Williams, eds.), Utilitarianism and Beyond (Cambridge: Cambridge University Press; Ikie, F.C., (1967) How Nations Negotiate, pp. 22-23. , New York: Frederick A. Praeger; Fuller, L., Perdue, W.R., Jr., The Reliance Interest in Contract Damages (1937) Yale L. J., 46, pp. 373 and 420. , (Pt. 2); Hamburger, P.A., The Development of the Nineteenth-Century Consensus Theory of Contract (1989) L & Hist. Rev., 7, p. 241; Whitford, W., Ian MacNeil’s Contribution to Contracts Scholarship (1985) Wis. L. Rev., 3, pp. 545 and 546-558; Macaulay, S., Relational Contracts Floating on a Sea of Custom? Thoughts about the Ideas of Ian MacNeil and Lisa Bernstein (1999) NW. U. L. Rev., 94 (3), pp. 775-804; Eisenberg, M.A., Why There Is No Law of Relational Contracts (1999) NW U. L. R., pp. 805-821; Coleman, J.L., A Bargaining Theory Approach to Default Provisions and Disclosure Rules in Contract Law (1989) Harv. J. L. & Pub Policy, 12, pp. 639 and 707-709; Katz, A.W., When Should an Offer Stick? The Economics of Promissory Estoppel in Preliminary Negotiations (1996) Yale L J, 105, p. 1249; Craswell, R., Offer, Acceptance, and Efficient Reliance (1996) Stan. L. Rev., 48, p. 481; Katz, When Should an Offer Stick?, (84), p. 1278; Schwartz, A., Incomplete Contracts (2004) The New Palgrave Dictionary of Economics and the Law, 2, pp. 277 and 278-279. , Peter Newman (ed.), London & New York: Palgrave Macmillan [format_title_en_publication_en_pub_year] => 9555510ae2e51dac9d77b891cee84b001250877294 [abstract_en] => INTRODUCTION Chinese Contract Law (CCL) bears a striking similarity to the Convention on Contracts for the International Sale of Goods (CISG) since it incorporates key elements of the CISG, especially in relation to the formation of contracts, such as the concept of offer and acceptance. As to the conditions which trigger the termination of contract, the CCL, with slight variations in the wording, has embraced the doctrine of “fundamental breach” prescribed in the CISG. The law also follows the CISG and recognises the validity of amendments to or termination of contracts by consensual agreement. In addition, there is no difference between the CISG and the CCL as to the prescriptions for consequences of termination of contract. On top of the similarities relating to termination of contract, it is observed that there are also strong resemblances between the two instruments with regard to the liability for breach of contract and exemptions from liability, “anticipatory breach” (anticipatory repudiation at common law), and the “insecurity defence” (Unsicherheitseinrede) in the civil law tradition and to the same effect in the CISG. Under the CISG, strict liability applies, which means that fault is not required to establish the liability of a breaching party for compensating losses suffered by the other party, unless the circumstance in question falls within the exceptions to the general rule. Such a mechanism of providing excuse for unforeseen events is incorporated into the CCL since it is a widely regarded trend in contract law development around the world. Furthermore, in calculating losses as to the basis of damage compensation, the CCL follows the CISG in adopting the rule of foreseeability. Despite such similarities, there was no wholesale legal transplant of the CISG into the CCL, particularly in the area of contractual liability rules. This chapter will analyse the features of the CCL relating to “liabilities under pre-contract” and “pre-contractual liabilities.” LIABILITIES UNDER PRE-CONTRACT AND PRE-CONTRACTUAL LIABILITIES Let us imagine how parties usually negotiate a deal and reach an agreement. The whole bargaining process is about reaching consensus and overcoming differences. At some point in time, the positions of the parties will meet and expectation towards each other’s promised performances will emerge. © Cambridge University Press 2018. [from_id] => 76 [cauthor_ad] => [Shen, W] Shandong University Law SchoolChina [hx_id] => 2378 [datebase] => Scopus [sys_level_num] => 6_1 [sys_jg_type] => [title_en] => Liability prior to contract formation in Chinese contract law [source_type] => 351 [pub_year] => 2017 [article_id] => 505594 [begin_page] => 137 [hints] => 17 [publisher] => Cambridge University Press [doi] => 10.1017/9781316816912.007 [language] => English [batch] => 3243 [publication_en] => Chinese Contract Law: Civil and Common Law Perspectives [school_id] => 117 [sys_update_time] => 2018-09-05 15:38:19 [publication_iso] => Chin. Contract Law: Civ. and Common Law Perspectives [SYS_TAG] => 3 [end_page] => 159 [page] => 137-159 [hb_type] => 2 [article_dt] => Book Chapter [jl_language] => english [jl_article_dt] => bookchapter [jl_publication_en] => chinesecontractlawcivilandcommonlawperspectives [jl_country] => 中国 [sys_author_in_last_arr] => china [jl_publisher] => cambridgeuniversitypress [company_id] => 0,0,0,0,0,0,0 [author_id] => 23251 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 沈文 [irtag] => 7 [t_index] => 0 [person_id] => 23251 ) ) [sys_author_id] => [id] => ga_oDWcBFjIhTVEbqbF5 [tags] => 0 ) [17] => Array ( [cite_scopus] => 3 [cauthor] => Li, F(fuchuanli@sdu.edu.cn) [school_id] => 117 [scopus_No] => 2-s2.0-85019432088 [batch2] => 5,6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-85019432088&doi=10.1007%2f5584_2016_54&partnerID=40&md5=0f807b286a914e69ce32602940a6f0a3 [tag] => 0 [author_en] => Wang W.@@@ Wang J.@@@ Li F. [publication_en] => Advances in Experimental Medicine and Biology [format_scopus_No] => f4625238aa614f3f691e8ecc19cbb7e4680537598 [format_doi] => f803a2749a2529afa3188eaba44f88cf-1196739283 [author_in] => [Wang, W] National Glycoengineering Research Center, Shandong University, 27 S. Shanda Road, Jinan, China, Shenzhen Research Institute of Shandong University, Rm A301, Virtual University Park, Nanshan, Shenzhen, China@@@[ Wang, J] School of Foreign Languages, University of Shanghai for Science and Technology, 516 Jungong Road, Shanghai, China@@@[ Li, F] National Glycoengineering Research Center, Shandong University, 27 S. Shanda Road, Jinan, China, Shenzhen Research Institute of Shandong University, Rm A301, Virtual University Park, Nanshan, Shenzhen, China [fund_No] => JCYJ20140418115815063, Shenzhen Graduate School, Peking University; 2012CB822102; 31570071, NSFC, National Natural Science Foundation of China [reference] => Bergefall, K., Trybala, E., Johansson, M., Uyama, T., Naito, S., Yamada, S., Kitagawa, H., Bergström, T., Chondroitin sulfate characterized by the E-disaccharide unit is a potent inhibitor of herpes simplex virus infectivity and provides the virus binding sites on gro2C cells (2005) J Biol Chem, 280 (37), pp. 32193-32199; Boneu, B., Glycosaminoglycans: Clinical use (1995) Seminars in Thrombosis and Hemostasis, 1995, 2, pp. 209-212; Bülow, H.E., Hobert, O., The molecular diversity of glycosaminoglycans shapes animal development (2006) Annu Rev Cell Dev Biol, 22, pp. 375-407; Capila, I., Linhardt, R.J., Heparin-protein interactions (2002) Angew Chem Int Ed Engl, 41 (3), pp. 390-412; Cheng, F., Heinegård, D., Malmström, A., Schmidtchen, A., Yoshida, K., Fransson, L.-A., Patterns of uronosyl epimerization and 4-/6-0-sulphation in chondroitin/dermatan sulphate from decorin and biglycan of various bovine tissues (1994) Glycobiology, 4 (5), pp. 685-696; Cherr, G.N., Yudin, A.I., Overstreet, J.W., The dual functions of GPI-anchored PH-20: Hyaluronidase and intracellular signaling (2001) Matrix Biol, 20 (8), pp. 515-525; Clement, A.M., Nadanaka, S., Masayama, K., Mandl, C., Sugahara, K., Faissner, A., The DSD-1 carbohydrate epitope depends on sulfation, correlates with chondroitin sulfate D motifs, and is sufficient to promote neurite outgrowth (1998) J Biol Chem, 273 (43), pp. 28444-28453; Csoka, A.B., Frost, G.I., Stern, R., The six hyaluronidase-like genes in the human and mouse genomes (2001) Matrix Biol, 20 (8), pp. 499-508; Esko, J.D., Selleck, S.B., Order out of chaos: Assembly of ligand binding sites in heparan sulfate (2002) Annu Rev Biochem, 71 (1), pp. 435-471; Faissner, A., Clement, A., Lochter, A., Streit, A., Mandl, C., Schachner, M., Isolation of a neural chondroitin sulfate proteoglycan with neurite outgrowth promoting properties (1994) J Cell Biol, 126 (3), pp. 783-799; Franzmann, E.J., Schroeder, G.L., Goodwin, W.J., Weed, D.T., Fisher, P., Lokeshwar, V.B., Expression of tumor markers hyaluronic acid and hyaluronidase (HYAL1) in head and neck tumors (2003) Int J Cancer, 106 (3), pp. 438-445; Fraser, J., Laurent, T., Laurent, U., Hyaluronan: Its nature, distribution, functions and turnover (1997) J Intern Med, 242 (1), pp. 27-33; Garg, A., Erson, R., Zaneveld, L., Garg, S., Biological activity assessment of a novel contraceptive antimicrobial agent (2005) J Androl, 26 (3), pp. 414-421; Garg, S., Vermani, K., Garg, A., Erson, R.A., Rencher, W.B., Zaneveld, L.J., Development and characterization of bioadhesive vaginal films of sodium polystyrene sulfonate (PSS), a novel contraceptive antimicrobial agent (2005) Pharm Res, 22 (4), pp. 584-595; Garron, M.-L., Cygler, M., Structural and mechanistic classification of uronic acid-containing polysaccharide lyases (2010) Glycobiology, 20 (12), pp. 1547-1573; Gu, K., Linhardt, R., Laliberte, M., Zimmermann, J., Purification, characterization and specificity of chondroitin lyases and glycuronidase from Flavobacterium heparinum (1995) Biochem J, 312 (2), pp. 569-577; Guo, X., Shi, Y., Sheng, J., Wang, F., A novel hyaluronidase produced by Bacillus sp. 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GAG-degrading enzymes with different activities have been found in various animals and microorganisms, and they play an irreplaceable role in the structure and function studies of GAGs. As two kind of important GAG-degrading enzymes, hyaluronidase (HAase) and chondroitinase (CSase) have been widely studied and increasing evidence has shown that, in most cases, their substrate specificities overlap and thus the “HAase” or “CSase” terms may be improper or even misnomers. Different from previous reviews, this article combines HAase and CSase together to discuss the traditional classification, substrate specificity, degradation pattern, new resources and naming of these enzymes. © 2016, Springer International Publishing Switzerland. [from_id] => 76 [cauthor_ad] => Li, F.; National Glycoengineering Research Center, Shandong University, 27 S. Shanda Road, China; 电子邮件: fuchuanli@sdu.edu.cn [hx_id] => 2378,2378,2357 [classification_pub] => 0121103 [doi] => 10.1007/5584_2016_54 [datebase] => Scopus [sys_level_num] => 6_1 [sys_jg_type] => 11 [title_en] => Hyaluronidase and chondroitinase [index_keyword] => beta glucuronidase; beta n acetylhexosaminidase; chondroitin ABC lyase; chondroitin sulfate; chondroitinase AC; chondroitinase B; depolymerase; dermatan sulfate; enzyme; glycosaminoglycan; heparan sulfate; heparin; hyaluronic acid; hyaluronidase; hydrolase; keratan sulfate; lyase; n acetylgalactosamine 4 sulfatase; unclassified drug; chondroitin ABC lyase; glycosaminoglycan; hyaluronoglucosaminidase; carbohydrate analysis; enzyme activity; enzyme degradation; enzyme mechanism; enzyme specificity; glycosaminoglycan metabolism; human; nomenclature; nonhuman; priority journal; protein function; structure analysis; animal; bacterium; chemistry; classification; conformation; cytology; enzymology; eukaryotic cell; extracellular matrix; hydrolysis; isolation and purification; kinetics; metabolism; virus; Animals; Bacteria; Carbohydrate Conformation; Carbohydrate Sequence; Chondroitinases and Chondroitin Lyases; Eukaryotic Cells; Extracellular Matrix; Glycosaminoglycans; Humans; Hyaluronoglucosaminidase; Hydrolysis; Kinetics; Substrate Specificity; Viruses [standard_in] => National Glycoengineering Research Center, Shandong University, 27 S. Shanda Road, Jinan, China; Shenzhen Research Institute of Shandong University, Rm A301, Virtual University Park, Nanshan, Shenzhen, China; School of Foreign Languages, University of Shanghai for Science and Technology, 516 Jungong Road, Shanghai, China [volume] => 925 [source_type] => 351 [pub_year] => 2017 [keyword_en] => Chondroitin sulfate/dermatan sulfate; Chondroitinase; Glycosaminoglycan; Hyaluronic acid; Hyaluronidase [article_id] => 502968 [begin_page] => 75 [hints] => 20 [publisher] => Springer New York LLC [substance] => beta glucuronidase, 9001-45-0; beta n acetylhexosaminidase, 37211-57-7, 9012-33-3, 9027-52-5; chondroitin ABC lyase, 9024-13-9; chondroitin sulfate, 9007-28-7, 9082-07-9; dermatan sulfate, 24967-94-0; heparan sulfate, 9050-30-0; heparin, 37187-54-5, 8057-48-5, 8065-01-8, 9005-48-5; hyaluronic acid, 31799-91-4, 9004-61-9, 9067-32-7; hyaluronidase, 9001-54-1, 9055-18-9, 488712-31-8; hydrolase, 9027-41-2; keratan sulfate, 69992-87-6, 9056-36-4; lyase, 9055-04-3; n acetylgalactosamine 4 sulfatase, 55354-43-3, 9012-81-1; hyaluronoglucosaminidase, 37326-33-3; Chondroitinases and Chondroitin Lyases; Glycosaminoglycans; Hyaluronoglucosaminidase [language] => English [issn] => 652598 [batch] => 3243,0 [pubmedID] => 27677277 [email] => fuchuanli@sdu.edu.cn [sys_update_time] => 2018-09-05 15:38:11 [format_title_en_issn_pub_year] => e431ca06569915aa11ce889f489b8de51195904193 [publication_iso] => Adv. Exp. Med. Biol. [SYS_TAG] => 3 [end_page] => 87 [page] => 75-87 [hb_type] => 2 [article_dt] => Book Chapter [hb_batch] => grant_no [imf_once] => [author_first] => [imf_5] => [jcr_wos] => [profession_stu] => [thesis_au] => [format_title] => [author_fn] => Wang, Wenshuang@@@ Wang, Junhong@@@ Li, Fuchuan [highly_article] => [student_No] => [grant_bulletin_No] => [dom_ranking] => [province] => [complete_time] => 20170907 [clc] => AEMBA [bulletin_date] => [publication_29] => Adv. Exp. Med. Biol. [fund_amount] => JCYJ20140418115815063, Shenzhen Graduate School, Peking University; 2012CB822102; 31570071, NSFC, National Natural Science Foundation of China [eissn] => [attachment_text] => [name_editor] => [subject_gb1] => [phone] => [book_alias] => [abstract_meeting] => [title_cn] => [application_date] => 2017/09/08 06:00 [keyword_plu] => *Chondroitin sulfate/dermatan sulfate; *Chondroitinase; *Glycosaminoglycan; *Hyaluronic acid; *Hyaluronidase [publication_cn] => [suppl] => [subsection] => IM [fund_ab] => [fund_type] => [format_title_en] => 72154a154f6e27232bbbf64b127adc5e-1687042248 [publisher_city] => United States [isbn_10] => [classification_No] => 0 (Glycosaminoglycans); EC 3.2.1.35 (Hyaluronoglucosaminidase); EC 4.2.2.- (Chondroitinases and Chondroitin Lyases) [cssci_No] => [responsibility] => [uncontrolled_terms] => [controlled_terms] => Animals; Bacteria/chemistry/enzymology; Carbohydrate Conformation; Carbohydrate Sequence; Chondroitinases and Chondroitin Lyases/*chemistry/classification/isolation & purification/metabolism; Eukaryotic Cells/*chemistry/cytology; Extracellular Matrix/*chemistry; Glycosaminoglycans/chemistry/*metabolism; Humans; Hyaluronoglucosaminidase/*chemistry/classification/isolation & purification/metabolism; Hydrolysis; Kinetics; Substrate Specificity; Viruses/chemistry/enzymology [top_article] => [reference_No] => [student_type] => [agency] => [cite_awos] => [wos_No] => [wos_sub] => [author_cn] => [series] => Adv Exp Med Biol. 2017;925:75-87. doi: 10.1007/5584_2016_54. [publisher_ad] => [country] => [cite_wos] => [author_jg] => [keyword_cn] => Chondroitin sulfate/dermatan sulfate; Chondroitinase; Glycosaminoglycan; Hyaluronic acid; Hyaluronidase [check_3Y] => [open_time] => [delivery_No] => [pages] => 75-87 [institution_first] => Shandong University [ei_No] => [fund_CSSCI] => [school_stu] => [main_cword] => [create_time] => 2016/09/29 06:00 [researcherID] => [degree] => chondroitin ABC lyase, 9024-13-9; hyaluronoglucosaminidase, 37326-33-3; Chondroitinases and Chondroitin Lyases; Glycosaminoglycans; Hyaluronoglucosaminidase [job_no] => [orcID] => [publication_type] => [volume_label] => [main_eword] => [numerical_index] => chondroitin ABC lyase; glycosaminoglycan; hyaluronoglucosaminidase; animal; bacterium; carbohydrate analysis; chemistry; classification; conformation; cytology; enzyme specificity; enzymology; eukaryotic cell; extracellular matrix; human; hydrolysis; isolation and purification; kinetics; metabolism; virus; Animals; Bacteria; Carbohydrate Conformation; Carbohydrate Sequence; Chondroitinases and Chondroitin Lyases; Eukaryotic Cells; Extracellular Matrix; Glycosaminoglycans; Humans; Hyaluronoglucosaminidase; Hydrolysis; Kinetics; Substrate Specificity; Viruses [author_gro] => [producer] => NOTNLM [format_publication_cn] => [awards_type] => [birthday] => 20160928 [sponsor] => [imf] => 1.881 [bulletin_No] => [institution_name] => [grant_bulletin_date] => 2016/09/30 06:00 [pubmed]; 2017/09/08 06:00 [medline]; 2016/09/29 06:00 [entrez] [pub_date] => 2017 [department_tutor1] => [abstract_type] => [legal_status] => [email_c] => [discipline_name] => [institution_type] => [conference_spo] => [conference_pro] => [cscd_No] => [abstract_cn] => [sys_priority_field] => 76 [research_area] => [oral_time] => 20170907 [name_tutor1] => [cauthor_back] => [check_180] => [special_is] => [positional_titles] => [format_publication_en] => 6fd72d55da7352f96c4d7304db90e40a-7443899 [jl_language] => english [jl_article_dt] => bookchapter [jl_publication_en] => advancesinexperimentalmedicineandbiology [jl_country] => 中国 [jl_keyword_en] => chondroitinsulfatedermatansulfate,hyaluronidase,glycosaminoglycan,chondroitinase,hyaluronicacid [sys_author_in_last_arr] => china [jl_keyword_cn] => chondroitinsulfatedermatansulfate,hyaluronidase,glycosaminoglycan,chondroitinase,hyaluronicacid [jl_clc] => aemba [jl_publisher] => springernewyorkllc [company_id] => 0,200,211 [author_id] => 21642,21643,21644,21645,24212,24213,24211,24205,24214,21587,24224 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 3 [name] => 黎峰 [irtag] => 7 [t_index] => 0 [person_id] => 21587 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 王文 [irtag] => 7 [t_index] => 0 [person_id] => 24224 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 3 [name] => 李飞 [irtag] => 7 [t_index] => 0 [person_id] => 21642 ) [3] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 3 [name] => 李飞 [irtag] => 7 [t_index] => 0 [person_id] => 21643 ) [4] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 3 [name] => 李峰 [irtag] => 7 [t_index] => 0 [person_id] => 21644 ) [5] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 3 [name] => 李峰 [irtag] => 7 [t_index] => 0 [person_id] => 21645 ) [6] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24211 ) [7] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24212 ) [8] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24213 ) [9] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24214 ) [10] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 王巍 [irtag] => 7 [t_index] => 0 [person_id] => 24205 ) ) [sys_author_id] => [sys_subject_sort] => 0,0 [college_parent_id] => 200,211 [company_test] => Array,Array [id] => za_oDWcBFjIhTVEb7LIU [tags] => 0 ) [18] => Array ( [standard_in] => College of Environmental Science and Engineering, Shandong University, Jinan, China; Faculty of Chemistry, University of Belgrade, Belgrade, Serbia [cauthor] => Wang, R(wangrui@sdu.edu.cn) [isbn] => 9781536126907; 9781536126891 [school_id] => 117 [scopus_No] => 2-s2.0-85044258986 [batch2] => 6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-85044258986&partnerID=40&md5=8145f3ba479304fac41ab7eb835a58c9 [tag] => 0 [author_en] => Li J.@@@ Wang R.@@@ Jovančićević B. [format_scopus_No] => d3541912087c30095bf2a009d7095a16-546659829 [author_in] => [Li, J] College of Environmental Science and Engineering, Shandong University, Jinan, China@@@[ Wang, R] College of Environmental Science and Engineering, Shandong University, Jinan, China@@@[ Jovančićević, B] Faculty of Chemistry, University of Belgrade, Belgrade, Serbia [reference] => Ono, Y., Catalysis in the production and reactions of dimethyl carbonate, an environmentally benign building block (1997) Applied Catalysis A: General, 155, pp. 133-166; Cao, Y., Research Progress in the Direct Synthesis of Dimethyl Carbonate from CO2 and Methanol (2012) Catalysis Surveys from Asia, 16 (3), pp. 138-147; Kumar, P., Active ceria-calcium oxide catalysts for dimethyl carbonate synthesis by conversion of CO2 (2017) Powder Technology, 309, pp. 13-21; Zhao, H., Hydroxyl-functionalized ionic liquid for activation and conversion of CO2 and methanol into dimethyl carbonate (2015) Journal of CO2 Utilization, 12, pp. 49-53; Garcia-Herrero, I., Environmental Assessment of Dimethyl Carbonate Production: Comparison of a Novel Electrosynthesis Route Utilizing CO2 with a Commercial Oxidative Carbonylation Process (2016) ACS Sustainable Chemistry & Engineering, 4 (4), pp. 2088-2097; Zhao, W., Synthesis of Dimethyl Carbonate from Methyl Carbamate and Methanol with Zinc Compounds as Catalysts (2008) Ind. Eng. Chem. Res, 47, pp. 5913-5917; Aymes, D., A comparative study of methanol carbonation on unsupported SnO2 and ZrO2 (2009) Catalysis Today, 147 (2), pp. 62-67; Wu, C., Zhao, X., Wang, Y., Effect of reduction treatment on catalytic performance of Zn-based catalyst for the alcoholysis of urea to dimethyl carbonate (2005) Catalysis Communications, 6 (10), pp. 694-698; Peng, W., Direct synthesis of salicylamide from phenol and urea over ZnO catalyst (2008) Catalysis Communications, 9, pp. 1219-1223; Zhao, W., Zinc oxide as the precursor of homogenous catalyst for synthesis of dialkyl carbonate from urea and alcohols (2009) Catalysis Communications, 10 (5), pp. 655-658; Bian, J., Graphite oxide as a novel host material of catalytically active Cu-Ni bimetallic nanoparticles (2009) Catalysis Communications, 10 (11), pp. 1529-1533; He, X., Study on the reaction between bisphenol A and dimethyl carbonate over organotin oxide (2013) Catalysis Communications, 33, pp. 20-23; Kumar, P., Srivastava, V.C., Mishra, I.M., Synthesis and characterization of Ce-La oxides for the formation of dimethyl carbonate by transesterification of propylene carbonate (2015) Catalysis Communications, 60, pp. 27-31; Kumar, P., Srivastava, V.C., Mishra, I.M., Dimethyl Carbonate Synthesis from Propylene Carbonate with Methanol Using Cu-Zn-Al Catalyst (2015) Energy fuel, 29, pp. 2664-2675; Li, L., One-step synthesis of dimethyl carbonate from carbon dioxide, propylene oxide and methanol over alkali halides promoted by crown ethers (2015) Journal of Organometallic Chemistry, 794, pp. 231-236; Zhao, S., An in situ infrared study of dimethyl carbonate synthe sis from carbon dioxide and methanol over well-shaped CeO2 (2017) Chine se Chemical Letters, 28, pp. 65-69; Kumar, P., Conversion of carbon dioxide along with methanol to dimethyl carbonate over ceria catalyst (2015) Journal of Environmental Chemical Engineering, 3, pp. 2943-2947; Marin, C., Kinetic and mechanistic investigations of the direct synthesis of dimethylcarbonate from carbon dioxide over ceria nanor od catalysts (2016) Journal of Catalysis, 340, pp. 295-301; Santos, B.A.V., Kinetic study for the direct synthesis of dimethyl carbonate from methanol and CO2 over CeO2 at high pressure conditions (2013) Applied Catalysis A: General, 455, pp. 219-226; Santos, B.A.V., Corrigendum to \"Kinetic study for the direct synthesis of dimethyl carbonate from methanol and CO2 over CeO2 at high pressure conditions (2014) Applied Catalysis A: General, 471, p. 106. , [Appl. Catal. A: Gen. 455 (2013) 219-226]; Pimprom, S., Synthesis of copper-nickel/SBA-15 from rice husk ash catalyst for dimethyl carbonate production from methanol and carbon dioxide (2015) Journal of Industrial and Engineering Chemistry, 31, pp. 156-166; Tamboli, A.H., Chaugule, A.A., Kim, H., Highly selective and multifunctional chitosan/ionic liquids catalyst for conversion of CO2 and methanol to dimethyl carbonates at mild reaction conditions (2016) Fuel, 166, pp. 495-501; Marin, C.M., Kinetic and mechanistic investigations of the direct synthesis of dimethyl carbonate from carbon dioxide over ceria nanorod catalysts (2016) Journal of Catalysis, 340, pp. 295-301; Kabra, S.K., Direct synthesis of dimethyl carbonate from methanol and carbon dioxide: A thermodynamic and experimental study (2016) The Journal of Supercritical Fluids, 117, pp. 98-107; Cui, Z., Effect of calcination atmospheres on the catalytic performance of nano-CeO2 in direct synthesis of DMC from methanol and CO2 (2017) Korean Journal of Chemical Engineering, 34 (1), pp. 29-36; Bansode, A., Urakawa, A., Continuous DMC Synthesis from CO2 and Methanol over a CeO2 Catalyst in a Fixed Bed Reactor in the Presence of a Dehydrating Agent (2014) ACS Catalysis, 4 (11), pp. 3877-3880; Orrego-Romero, A.F., Pelletization of catalysts supported on activated carbon. A Case Study: clean synthesis of dimethyl carbonate from methanol and CO2 (2015) Revista Facultad de Ingeniería Universidad de Antioquia, 78, pp. 38-47; Feng, Q., New Method for Electrochemical Activation of Nbenzyl Ideneaniline to Dibutyl Phthalate in the Present of Carbon dioxide (2016) Int. J. Electrochem. Sci, 11, pp. 692-699; Zhao, G., Electrochemical reduction of supercritical carbon dioxide in ionic liquid 1-n-butyl-3-methylimidazolium hexafluorophosphate (2004) The Journal of Supercritical Fluids, 32 (1-3), pp. 287-291; Zhang, L., Electrochemical activation of CO2 in ionic liquid (BMIMBF4): synthesis of organic carbonates under mild conditions (2008) Green Chem., 10 (2), pp. 202-206; Yang, H., Electrochemical activation of carbon dioxide in ionic liquid: synthesis of cyclic carbonates at mild reaction conditions (2002) Chem Commun (Camb), (3), pp. 274-275; Maiti, A., Theoretical screening of ionic liquid solvents for carbon capture (2009) ChemSuschem, 2, pp. 628-631; Kathiresan, M., Velayutham, D., Ionic liquids as an electrolyte for the electro synthesis of organic compounds (2015) Chem Commun (Camb), 51 (99), pp. 17499-17516; Alvarez-Guerra, M., Ionic liquids in the electrochemical valorisation of CO2 (2015) Energy Environ. Sci, 8 (9), pp. 2574-2599; Yuan, D., Electrochemical activation of carbon dioxide for synthesis of dimethyl carbonate in an ionic liquid (2009) Electrochimica Acta, 54 (10), pp. 2912-2915; Feng, Q., Nanoporous copper incorporated platinum composites for electrocatalytic reduction of CO2 in ionic liquid BMIMBF4 (2012) Applied Surface Science, 258 (12), pp. 5005-5009; Liu, F., Electrochemical synthesis of dimethyl carbonate with carbon dioxide in 1-butyl-3-methylimidazoliumtetrafluoborate on indium electrode (2012) Int. J. Electrochem. Sci., 7, pp. 4381-4387; Zhang, L., Electrochemical activation of CO2 in ionic liquid (BMIMBF4): synthesis of organic carbonates under mild conditions (2008) Green Chemistry, 10 (2), pp. 202-206; Wang, X.Y., Fixation of CO2 by electrocatalytic reduction to synthesis of dimethyl carbonate in ionic liquid using effective silver coated nanoporous copper composites (2010) Chinese Chemical Letters, 21 (8), pp. 987-990; Yan, C., Electrochemical synthesis of dimethyl carbonate from methanol, CO2 and propylene oxide in an ionic liquid (2011) Journal of Chemical Technology and Biotechnology, 86, pp. 1413-1417; Feng, Q., Electrochemical reduction behaviour of CO2 on Cu Electrode in ionic liquid (BmimBF4) during synthesis of dimethyl carbonate (2011) Asian Journal of Chemistry, 23 (11), pp. 4823-4826; Yuan, X., Electrochemical conversion of methanol and carbon dioxide to dimethyl carbonate at graphite-Pt electrode system (2012) J. Electrochem. Soc., 159 (12), pp. E183-186; Lu, B., Electrochemical conversion of CO2 into dimethyl carbonate in a functionalized ionic liquid (2013) Journal of CO2 Utilization, (3-4), pp. 98-101; Yuan, D.D., Electrochemical Fixation of Carbon Dioxide for Synthesis Dimethyl Carbonate in Ionic Liquid BMimBr (2014) Advanced Materials Research, 953 (954), pp. 1180-1183; Garcia-Herrero, I., Alvarez-Guerra, M., Irabien, A., CO2 electrovalorization to dimethyl carbonate from methanol using potassium methoxide and the ionic liquid [bmim][Br] in a filter-press electrochemical cell (2014) Journal of Chemical Technology & Biotechnology, 90 (8), pp. 1433-1438; Garcia-Herrero, I., Alvarez-Guerra, M., Irabien, A., Electrosynthesis of dimethyl carbonate from methanol and CO2 using potassium methoxide and the ionic liquid [bmim][Br] in a filter-press cell: a study of the influence of cell configuration (2016) Journal of Chemical Technology & Biotechnology, 91 (2), pp. 507-513; MacDowell, N., An overview of CO2 capture technologies (2010) Energy & Environmental Science, 3 (11), p. 1645; Bara, J.E., Guide to CO2 Separations in Imidazolium-Based Room-Temperature Ionic Liquids (2009) Ind. Eng. Chem. Res., 48, pp. 2739-2751; Grills, D.C., Electrocatalytic CO2 Reduction with a Homogeneous Catalyst in Ionic Liquid: High Catalytic Activity at Low Overpotential (2014) The Journal of Physical Chemistry Letters, 5 (11), pp. 2033-2038; Jitaru, M., Electrochemical reduction of carbon dioxide on flat metallic cathodes (1997) Journal of Applied Electrochemistry, 27, pp. 875-889; Rees, N.V., Compton, R.G., Electrochemical CO2 sequestration in ionic liquids; a perspective (2011) Energy Environ. Sci., 4 (2), pp. 403-408 [format_title_en_publication_en_pub_year] => e8af6c565fd79143d9881f4ad23c3e86557683782 [abstract_en] => Dimethyl carbonate (DMC) is a rapidly developing green chemical product. It can be used as substitutes for basic organic chemical raw materials to replace toxic phosgene, methyl chloride, methyl chloroformate and other substances, which has important meaning for environmental protection. On one hand, CO2 is the most important greenhouse gas, causing environmental problems. On the other hand, it is also a rich and cheap carbon source. The synthesis of dimethyl carbonate from CO2 and methanol has received much attention in the past years. However, due to the thermodynamic stability and kinetic inertness of CO2, the direct synthesis of dimethyl carbonate from CO2 and methanol can only be carried out under the conditions of high temperature and high pressure or in the presence of catalysts, and even so the yield is not high. Electrochemical fixation of CO2 to dimethyl carbonate can improve the utilization of CO2 and enable the reaction to proceed under mild condition. Especially the use of green solvent ionic liquids in the study of CO2 fixation has more practical significance. Here we will introduce the process and mechanism of electrochemical synthesis of DMC in ionic liquids. The yield of DMC is affected by various factors such as ionic liquids, cathode materials, temperature, reaction time, working potential and the types of electrolytic cell. We reviewed herein the influence of several factors on the yield of DMC. © 2017 by Nova Science Publishers, Inc. All rights reserved. [from_id] => 76 [cauthor_ad] => [Wang, R] College of Environmental Science and Engineering, Shandong UniversityChina; [hx_id] => 2378 [datebase] => Scopus [sys_level_num] => 6_1 [sys_jg_type] => 11 [title_en] => The application of ionic liquids in the electrochemical synthesis of dimethyl carbonate from CO2 and methanol [source_type] => 351 [pub_year] => 2017 [keyword_en] => CO2; Dimethyl carbonate; Electrochemical; Ionic liquids [article_id] => 503049 [begin_page] => 63 [hints] => 13 [publisher] => Nova Science Publishers, Inc. [language] => English [batch] => 3243 [publication_en] => Ionic Liquids: Electrochemistry, Uses and Challenges [email] => wangrui@sdu.edu.cn [sys_update_time] => 2018-09-05 15:38:12 [publication_iso] => Ionic Liq.: Electrochem., Uses and Chall. [SYS_TAG] => 3 [end_page] => 82 [page] => 63-82 [hb_type] => 2 [article_dt] => Book Chapter [jl_language] => english [jl_article_dt] => bookchapter [jl_publication_en] => usesandchallenges,ionicliquidselectrochemistry [jl_country] => 中国 [jl_keyword_en] => electrochemical,co2,dimethylcarbonate,ionicliquids [sys_author_in_last_arr] => china [jl_publisher] => novasciencepublishers,inc [company_id] => 0,165 [author_id] => 24146,21742,24144,21722,21747,21746,21744,21725,21749,21748,21750,21751,21727,21726,21740,26383,24148,21741,21730,21743 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 2 [name] => 王然 [irtag] => 7 [t_index] => 0 [person_id] => 24144 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 2 [name] => 王蓉 [irtag] => 7 [t_index] => 0 [person_id] => 24146 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 2 [name] => 王瑞 [irtag] => 7 [t_index] => 0 [person_id] => 24148 ) [3] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李军 [irtag] => 7 [t_index] => 0 [person_id] => 21748 ) [4] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李军 [irtag] => 7 [t_index] => 0 [person_id] => 21749 ) [5] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李军 [irtag] => 7 [t_index] => 0 [person_id] => 21750 ) [6] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李俊 [irtag] => 7 [t_index] => 0 [person_id] => 21751 ) [7] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李静 [irtag] => 7 [t_index] => 0 [person_id] => 21742 ) [8] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李静 [irtag] => 7 [t_index] => 0 [person_id] => 21743 ) [9] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李静 [irtag] => 7 [t_index] => 0 [person_id] => 21744 ) [10] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李娟 [irtag] => 7 [t_index] => 0 [person_id] => 21746 ) [11] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李娟 [irtag] => 7 [t_index] => 0 [person_id] => 21747 ) [12] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李健 [irtag] => 7 [t_index] => 0 [person_id] => 21722 ) [13] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李洁 [irtag] => 7 [t_index] => 0 [person_id] => 21725 ) [14] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李洁 [irtag] => 7 [t_index] => 0 [person_id] => 21726 ) [15] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李洁 [irtag] => 7 [t_index] => 0 [person_id] => 21727 ) [16] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李进 [irtag] => 7 [t_index] => 0 [person_id] => 21730 ) [17] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李静 [irtag] => 7 [t_index] => 0 [person_id] => 21740 ) [18] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李静 [irtag] => 7 [t_index] => 0 [person_id] => 21741 ) [19] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 1 [name] => 李坚 [irtag] => 7 [t_index] => 0 [person_id] => 26383 ) ) [sys_author_id] => [sys_subject_sort] => 0 [college_parent_id] => 165 [company_test] => Array [id] => Hq_oDWcBFjIhTVEb7LMV [tags] => 0 ) [19] => Array ( [grant_bulletin_date] => [abstract_meeting] => [delivery_No] => [producer] => [ei_No] => [discipline_name] => [isbn] => 9781522523260; 1522523251; 9781522523253 [main_cword] => [abstract_cn] => [keyword_plu] => [book_alias] => [controlled_terms] => [complete_time] => [imf] => [publisher_city] => [uncontrolled_terms] => [conference_ad] => [subsection] => [cite_awos] => [imf_once] => [classification_pub] => [publication_iso ] => [oral_time] => [main_eword] => [awards_type] => [bulletin_No] => [publication_29] => Handb. of Res. on Inventive Bioremediation Tech. [pub_year] => 2017 [eissn] => [dom_ranking] => [application_date] => [from_id] => 76 [profession_stu] => [cauthor_ad] => [Singh, R.P] Shandong UniversityChina [cscd_No] => [abstract_en] => Bioremediation of hazardous substances from environment is a major human and environmental health concern but can be managed by the microorganism due to their variety of properties that can effectively change the complexity. Microorganisms convey endogenous genetic, biochemical and physiological assets that make them superlative proxies for pollutant remediation in habitat. But, the crucial step is to degrade the complex ring structured pollutants. Interestingly, the integration of genomics and proteomics technologies that allow us to use or alter the genes and proteins of interest in a given microorganism towards a cell-free bioremediation approach. Resultantly, efforts have been finished by developing the genetically modified (Gm) microbes for the remediation of ecological contaminants. Gm microorganisms mediated bioremediation can affect the solubility, bioavailability and mobility of complex hazardous. © 2017, IGI Global. All rights reserved. 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1. Functional Crystals SCOPUS SCOPUS

作者:Ye N.; Wang J.-Y.; Boughton R.I.; Hong M.-C.

作者机构:[Ye, N] Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, Fuzhou, China;[ Wang, J.-Y] Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, Fuzhou, China, Shandong University, Jinan, China;[ Boughton, R.I] Bowling Green State University, Bowling Green, OH, United States;[ Hong, M.-C] Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, Fuzhou, China

来源:Modern Inorganic Synthetic Chemistry: Second Edition,2017575-611

资源类型:期刊论文

2. Measuring service quality SCOPUS SCOPUS

作者:Liu A.; Ma E.; Ng C.Y.N.

作者机构:[Liu, A] Shandong University, Weihai Campus, China;[ Ma, E] Griffith University, Australia;[ Ng, C.Y.N] Institute for Tourism Studies (IFT), Macau, China

来源:The Routledge Handbook of Consumer Behaviour in Hospitality and Tourism,2017116-127

资源类型:期刊论文

3. The application of ionic liquids in the electrochemical reduction of CO2 SCOPUS

作者:Liu X.; Qiao S.; Wang R.; Jovančićević B.

作者机构:[Liu, X] College of Environmental Science and Engineering, Shandong University, Jinan, China;[ Qiao, S] College of Environmental Science and Engineering, Shandong University, Jinan, China;[ Wang, R] College of Environmental Science and Engineering, Shandong University, Jinan, China;[ Jovančićević, B] Faculty of Chemistry, University of Belgrade, Belgrade, Serbia

来源:Ionic Liquids: Electrochemistry, Uses and Challenges,201783-104

资源类型:期刊论文

4. Polybenzoxazine/Organosiloxane SCOPUS SCOPUS

作者:Gao S.; Lu Z.

作者机构:[Gao, S] Shandong University, Jinan, China;[ Lu, Z] Shandong University, Jinan, China

来源:Advanced and Emerging Polybenzoxazine Science and Technology,2017413-424

资源类型:期刊论文

5. A practical guide to recombineering in Photorhabdus and Xenorhabdus SCOPUS SCOPUS

作者: Yin, Jia; Wang, Hailong; Li, Ruijuan; Ravichandran, Vinothkannan; Bian, Xiaoying; Li, Aiying; Tu, Qiang; Francis Stewart, A; Fu, Jun; Zhang, Youming

作者机构:[Yin, J] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Wang, H] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Li, R] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Ravichandran, V] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Bian, X] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Li, A] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Tu, Q] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China;[ Francis Stewart, A] Department of Genomics, Dresden University of Technology, BioInnovations-Zentrum, Tatzberg 47-51, Dresden, 01307, Germany;[ Fu, J] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China, Department of Genomics, Dresden University of Technology, BioInnovations-Zentrum, Tatzberg 47-51, Dresden, 01307, Germany;[ Zhang, Y] Helmholtz Institute of Biotechnology, State Key Laboratory of Microbial Technology, School of Life Science, Shandong University, Shanda Nanlu 27, Jinan, 250100, China

来源:Current Topics in Microbiology and Immunology,2017,Vol.402,195-213

最新影响因子:3.719

资源类型:期刊论文

6. Honeycomb Films with Ordered Patterns and Structures SCOPUS SCOPUS

作者:Dong C.; Hao J.

作者机构:[Dong, C] Shandong University, Jinan, China;[ Hao, J] Shandong University, Jinan, China

来源:Comprehensive Supramolecular Chemistry II,2017,Vol.9,207-229

资源类型:期刊论文

7. Heat transfer with ice-water phase change in porous media: Theoretical model, numerical simulations, and application in cold-region tunnels SCOPUS SCOPUS

作者:Chen W.; Tan X.

作者机构:[Chen, W] Research Center of Geotechnical and Structural Engineering, Shandong University, Jinan, Shandong, China, State Key Laboratory of Geomechanics and Geotechnical Engineering, Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan, Hubei, China;[ Tan, X] State Key Laboratory of Geomechanics and Geotechnical Engineering, Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan, Hubei, China

来源:Rock Mechanics and Engineering,2017,Vol.5,243-290

资源类型:期刊论文

8. Complications and other conditions in refractory status epilepticus that require attention SCOPUS SCOPUS

作者:Zhou S.; Wang X.

作者机构:[Zhou, S] Department of Neurology, Qilu Hospital of Shandong University and Brain Science Research Institute, Shandong University, 107 Wenhuaxi Road, Jinan, Shandong, 250012, China;[ Wang, X] Department of Neurology, The First Affiliated Hospital of Wenzhou Medical University, Nanbaixiang Street, Ouhai District, Wenzhou City, Zhejiang Province, 325015, China

来源:Refractory Status Epilepticus: Diagnosis and Treatment,2017291-324

资源类型:期刊论文

9. Introductory Note: The international criminal court in 2015 SCOPUS

作者:Knoops G.-J.A.

作者机构:[Knoops, G.-J.A] University of Amsterdam, Netherlands, Shandong University, Jinan, China

来源:The Global Community: Yearbook of International Law and Jurisprudence 2016,2017379-384

资源类型:期刊论文

10. Comparing Political Values in China and the West: What Can Be Learned and Why It Matters SCOPUS SSCI

作者:Bell, Daniel A.

作者机构:[Bell, Daniel A.] Shandong Univ, Fac Polit & Publ Adm, Qingdao 26637, Peoples R China.; [Bell, Daniel A.] Tsinghua Univ, Schwarzman Coll, Beijing 100084, Peoples R China.

来源:ANNUAL REVIEW OF POLITICAL SCIENCE, VOL 20,2017,Vol.20,93-110

WOS被引数:1

资源类型:期刊论文

WOS:000401334000006

11. Design and Fabrication of Dealloying-driven Nanoporous Metallic Electrocatalyst SCOPUS SCOPUS

作者:Zhang Z.; Ying W.

作者机构:[Zhang, Z] Shandong University, School of Materials Science and Engineering, Key Lab. for Liquid-Solid Structural Evolution and Processing of Materials (Ministry of Education), Jinan, 250061, China;[ Ying, W] Shandong University, School of Materials Science and Engineering, Key Lab. for Liquid-Solid Structural Evolution and Processing of Materials (Ministry of Education), Jinan, 250061, China

来源:Electrocatalysts for Low Temperature Fuel Cells: Fundamentals and Recent Trends,2017533-555

资源类型:期刊论文

12. The environmental complaint letters and visits system in China SCOPUS SCOPUS

作者:Zhang S.

作者机构:[Zhang, S] Law School of Shandong University, China

来源:Environmental Mediation: An International Survey,2017196-213

资源类型:期刊论文

13. Mycorrhiza: Creating good spaces for interactions SCOPUS SCOPUS

作者:Manchanda G.; Singh R.P.; Li Z.F.; Zhang J.J.

作者机构:[Manchanda, G] Department of Botany, D.A.V. University, Jalandhar, Punjab, India;[ Singh, R.P] State Key Laboratory of Microbial Technology, College of Life Science, Shandong University, Jinan, Shandong, 250100, China;[ Li, Z.F] State Key Laboratory of Microbial Technology, College of Life Science, Shandong University, Jinan, Shandong, 250100, China;[ Zhang, J.J] College of Food and Bioengineering, Zhengzhou University of Light Industry, Zhengzhou, Henan, 450000, China

来源:Mycorrhiza - Function, Diversity, State of the Art: Fourth Edition,201739-60

资源类型:期刊论文

14. Q-switching of ytterbium lasers by a graphene saturable absorber SCOPUS

作者:Loiko P.; Serres J.M.; Mateos X.; Yu H.; Zhang H.; Liu J.; Yumashev K.; Griebner U.; Petrov V.; Aguiló M.; Díaz F.

作者机构:[Loiko, P] Center for Optical Materials and Technologies, Belarusian National Technical University, 65/17 Nezavisimosti Ave., Minsk, 220013, Belarus, Física i Cristal_lografia de Materials i Nanomaterials (FiCMA-FiCNA), Universitat Rovira i Virgili (URV), Campus Sescelades, c/Marcel_lí Domingo, s/n., Tarragona, E-43007, Spain;[ Serres, J.M] Física i Cristal_lografia de Materials i Nanomaterials (FiCMA-FiCNA), Universitat Rovira i Virgili (URV), Campus Sescelades, c/Marcel_lí Domingo, s/n., Tarragona, E-43007, Spain;[ Mateos, X] Física i Cristal_lografia de Materials i Nanomaterials (FiCMA-FiCNA), Universitat Rovira i Virgili (URV), Campus Sescelades, c/Marcel_lí Domingo, s/n., Tarragona, E-43007, Spain;[ Yu, H] State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China;[ Zhang, H] State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China;[ Liu, J] College of Physics, Qingdao University, 308 Ning-Xia Road, Qingdao, 266071, China;[ Yumashev, K] Center for Optical Materials and Technologies, Belarusian National Technical University, 65/17 Nezavisimosti Ave., Minsk, 220013, Belarus;[ Griebner, U] Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, Max-Born-Str. 2a, Berlin, D-12489, Germany;[ Petrov, V] Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, Max-Born-Str. 2a, Berlin, D-12489, Germany;[ Aguiló, M] Física i Cristal_lografia de Materials i Nanomaterials (FiCMA-FiCNA), Universitat Rovira i Virgili (URV), Campus Sescelades, c/Marcel_lí Domingo, s/n., Tarragona, E-43007, Spain;[ Díaz, F] Física i Cristal_lografia de Materials i Nanomaterials (FiCMA-FiCNA), Universitat Rovira i Virgili (URV), Campus Sescelades, c/Marcel_lí Domingo, s/n., Tarragona, E-43007, Spain

来源:NATO Science for Peace and Security Series B: Physics and Biophysics,2017533-535

资源类型:期刊论文

15. Particle Toxicities SCOPUS

作者:Madl A.K.; Sun X.; Silva R.M.; Kadir T.; Pinkerton K.E.

作者机构:[Madl, A.K] University of California, Davis, CA, United States, Cardno ChemRisk, Aliso Viejo, CA, United States;[ Sun, X] University of California, Davis, CA, United States, Shandong University, Jinan, China;[ Silva, R.M] University of California, Davis, CA, United States;[ Kadir, T] University of California, Davis, CA, United States;[ Pinkerton, K.E] University of California, Davis, CA, United States

来源:Comprehensive Toxicology: Third Edition,2017,Vol.15-15,263-301

资源类型:期刊论文

16. Inorganic-organic hybrid materials based on nanopolyoxometalates SCOPUS

作者:Wang Y.; Hao J.

作者机构:[Wang, Y] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan, 250100, China;[ Hao, J] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan, 250100, China

来源:Supramolecular Chemistry of Biomimetic Systems,2017355-394

资源类型:期刊论文

17. Liability prior to contract formation in Chinese contract law SCOPUS

作者:Shen W.

作者机构:[Shen, W] Shandong University Law School, China

来源:Chinese Contract Law: Civil and Common Law Perspectives,2017137-159

资源类型:期刊论文

18. Hyaluronidase and chondroitinase SCOPUS SCOPUS

作者: Wang, Wenshuang; Wang, Junhong; Li, Fuchuan

作者机构:[Wang, W] National Glycoengineering Research Center, Shandong University, 27 S. Shanda Road, Jinan, China, Shenzhen Research Institute of Shandong University, Rm A301, Virtual University Park, Nanshan, Shenzhen, China;[ Wang, J] School of Foreign Languages, University of Shanghai for Science and Technology, 516 Jungong Road, Shanghai, China;[ Li, F] National Glycoengineering Research Center, Shandong University, 27 S. Shanda Road, Jinan, China, Shenzhen Research Institute of Shandong University, Rm A301, Virtual University Park, Nanshan, Shenzhen, China

来源:Advances in Experimental Medicine and Biology,2017,Vol.925,75-87

最新影响因子:1.881

资源类型:期刊论文

19. The application of ionic liquids in the electrochemical synthesis of dimethyl carbonate from CO2 and methanol SCOPUS

作者:Li J.; Wang R.; Jovančićević B.

作者机构:[Li, J] College of Environmental Science and Engineering, Shandong University, Jinan, China;[ Wang, R] College of Environmental Science and Engineering, Shandong University, Jinan, China;[ Jovančićević, B] Faculty of Chemistry, University of Belgrade, Belgrade, Serbia

来源:Ionic Liquids: Electrochemistry, Uses and Challenges,201763-82

资源类型:期刊论文

20. Insight of proteomics and genomics in environmental bioremediation SCOPUS SCOPUS

作者:Singh R.P.; Manchanda G.; Li Z.-F.; Rai A.R.

作者机构:[Singh, R.P] Shandong University, China;[ Manchanda, G] D.A.V. University, India;[ Li, Z.-F] Shandong University, China;[ Rai, A.R] Seth Kasarimal Porwal College, India

来源:Handbook of Research on Inventive Bioremediation Techniques,201746-69

资源类型:期刊论文

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