Artículos de revistas sobre el tema "Nançay (Cher)"

Odontochilus Blume (1859: 79) comprises about 40 species distributed from the Himalayas and China through Southeast Asia eastwards to the southwestern Pacific islands (Chen et al. 2009, Pearce & Cribb 2002, Pridgeon et al. 2003). Most species are restricted to tropical and warm-temperate regions. The genus is closely related with Anoectochilus Blume (1825: 411) and most of species were in the past included in that genus because both genera have flowers with pectinate or dentate (rarely smooth) lip flanges. However, Odontochilus is separated from Anoectochilus based on the saccate non-exerted spur that is largely enclosed by the bases of the lateral sepals, whereas Anoectochilus has an exerted conical or cylindrical spur (Pridgeon et al. 2003).

Shiing-Shen Chern was a towering figure in mathematics, both for his contributions to differential geometry and as a source of inspiration and encouragement for all mathematicians, and particularly those in China. Born in the final year of the Qing dynasty, and educated at a time when China was only beginning to set up Western-style universities, he lived to preside over the 2002 International Congress of Mathematicians in Beijing. He was a co-founder of the Mathematical Sciences Research Institute in Berkeley and its first Director in 1981; he also set up the Nankai Institute for Mathematics in 1985. His contributions to differential geometry were of foundational importance for the global viewpoint that developed in the postwar years, and the mathematical tools he introduced are now the common currency in geometry, topology and even aspects of theoretical physics.

Abstract China places a great emphasis on boosting its innovative capability, which it says is key to meeting the challenges in economic development and global competition. At the heart of the matter is how the country could produce its own agent of innovation—creative graduates and postgraduates. In a forum chaired by National Science Review's executive associate editor Mu-ming Poo, five panelists from top universities discuss the problems and challenges of higher education in China and in what ways the system needs to be reformed. Yuanfang Chen Physician and Vice Chair of Peking Union Medical College's Expert Committee on Education in Beijing Song Gao Chemist and Vice President of Peking University in Beijing Ke Gong Electronic Engineer and President of Nankai University in Tianjin Yigong Shi Biologist and Dean of Tsinghua University's School of Life Sciences in Beijing Chia-Wei Woo Physicist and Founding President of Hong Kong University of Science and Technology in Hong Kong Mu-ming Poo (Chair) Neuroscientist and Director of Chinese Academy of Sciences’ Institute of Neuroscience in Shanghai

In recent years, intense efforts have been focused on stabilization of silicon-based anode in Li ion secondary batteries due to their remarkably high theoretical capacity. At the same time, strategy has not yet been established on how to stabilize the silicon based anode sufficiently during long cycles so that it will be feasible for practical use. In this talk, several different approaches on stabilization of silicon-based anode will be introduced both in terms of polymer binders design and active materials design. Our group synthesized several self-healing polymer binder and polymer coating material which are efficient for the use in silicon-based anode. Poly(borosiloxane) (PBS)1 was prepared by dehydrocoupling polymerization between mesitylborane and diphenylsilanediol in the presence of transition metal catalyst. PBS was found to show self-healing property at 45oC when coated onto Si electrode. When PBS coated Si electrode was employed for anodic half cell (Si/EC:DEC (1/1=v/v)/Li), it showed much improved durability when compared with PVDF coated Si based cell or bare Si based cell. We also reported a design of BIAN (bis-imino-acenaphthene) based conjugated polymer (P-BIAN) /Poly(acrylic acid) (PAA) composite binder for Si based anode2,3. Due to combination of n-type imine-based conjugated polymer (H-bonding acceptor) and PAA (H-bonding donor), synergistic effect in stabilization of Si/C composite anode was observed due to both of desirable electronic structure of P-BIAN and H-bonding based self-healing properties. In this system, anodic half cell delivered specific discharging capacity of above 2000 mAhg-1 for 600 cycles. As alternative approaches, we are also working on preparation of specific Si based anodic active materials which showed extremely high durability. b-SiC/N-doped carbon4 was found to show excellent durability even in the presence of conventional binder materials due to restricted volumetric changes of b-SiC during lithiation/delithiation. We also report coating of mechanically highly robust silicon oxycarbide on micro silicon5, which was also found to be quite effective. References 1) Patnaik, S. G.; Jayakumar, T. P.; Sawamura, Y. Matsumi, N. ACS Appl. Ener. Mater. 2021, 4, 2241. 2) Gupta, A.; Badam, R.; Matsumi, N. ACS Appl. Ener. Mater. 2022, 5, 7977. 3) Gupta, A.; Badam, R.; Nag, A.; Kaneko, T.; Matsumi, N. ACS Appl. Ener. Mater. 2021, 4, 2231 4) Nandan, R.; Takamori, N.; Higashimine, K.; Badam, R.; Matsumi, N. J. Mater. Chem. A. 2022, 10, 5230. 5) Nandan, R.; Takamori, N.; Higashimine, K.; Badam, R.; Matsumi, N. J. Mater. Chem. A. 2022, 10, 15960.

Japanese species and genera of the tribe Smicromyrmini Bischoff, 1920 are revised. Most of the relevant types were examined. The following eight species in the genera Smicromyrme Thomson, 1870, Nemka Lelej, 1985, Mickelomyrme Lelej, 1995, Andreimyrme Lelej, 1995, Ephucilla Lelej, 1995 and Sinotilla Lelej, 1995 are recognized from Japan: Sm. lewisi Mickel, 1935, ♂♀; N. yasumatsui (Mickel, 1936), stat. rev. et comb. nov., ♂♀; M. hageni (Zavattari, 1913), ♂♀; A. substriolata (Chen, 1957), ♀ (Amami-ôshima Is., Okinawa-jima Is.); E. yoshitakei sp. nov., ♂♀ (Amami-ôshima Is.), E. suginoi sp. nov., ♂♀ (Okinawa-jima Is.), E. brevitegula sp. nov., ♂♀ (Ishigaki-jima Is., Iriomote-jima Is.); Si. jambar sp. nov., ♂ (Okinawa-jima Is.). The genera Andreimyrme and Sinotilla are newly recorded from Japan. Nemka wotani (Zavattari, 1913) and Ephucilla naja (Zavattari, 1913) are excluded from the Japanese fauna. New synonymies are proposed for N. wotani (Zavattari, 1913) [=Smicromyrme chihpenchia Tsuneki, 1993, syn. nov.], N. limi limi (Chen, 1957) [=Smicromyrme limi nanhai Chen, 1957, syn. nov.], A. substriolata [=Smicromyrme tridentiens Chen, 1957, syn. nov.] and Neotrogaspidia pustulata (Smith, 1873) [=Smicromyrme yakushimensis Yasumatsu, 1934, syn. nov.]. Phimenes flavopictus formosanus (Zimmermann, 1931) (Hymenoptera: Vespidae: Eumeninae) is recorded as a host of Ephucilla brevitegula. Other new records include: Mickelomyrme athalia (Pagden, 1934) from China (Guangdong, Fujian, Yunnan) and Vietnam (Hoa Binh), M. bakeri (Mickel, 1934) from Malaysia (Borneo) and Indonesia (Sulawesi), M. pusillaeformis (Hammer, 1962) from Indonesia (Bali), Andreimyrme sarawakensis Lelej, 1996 from Peninsular Malaysia (Kuala Lumpur) and A. substriolata from Laos (Xiengkhouang, Houapanh), Thailand (Chiang Mai), Peninsular Malaysia (Kuala Terengganu) and Indonesia (Sumatra). Distributions of Japanese smicromyrmine species are classified into the following three patterns: Asian continental-Palaearctic Japan (Sm. lewisi and N. yasumatsui), Taiwan-Ryûkyû (M. hageni, E. yoshitakei, E. suginoi, E. brevitegula, Si. jambar) and Asian continental-Ryûkyû (A. substriolata). Species of Asian continental-Palaearctic Japan are widely distributed in Palaearctic part of Japan and eastern part of Eurasia, or have the closest relative in continental Asia. They are considered to be native to Japan since it was a part of Eurasia, or have immigrated to Japan through the land bridge between Korean Peninsula and Japan by the end of the Upper Pleistocene. The Taiwan-Ryûkyû species are immigrants from Taiwan through the land bridge. The Asian continental-Ryûkyû species is presumed to have immigrated to Japan during the Upper Pleistocene when the eastern edge of Eurasian Continent was close to Amami-ôshima Is.

A complete taxonomic catalogue of the Stick and Leaf-insects (Phasmatodea) recorded or described from the mainland China (excluding Taiwan) is presented. 241 valid species are listed, which are currently attributed to 50 genera, 5 families and 7 subfamilies. Genera and species are listed alphabetically. All available type-data is provided based mainly on literary sources for species described by Chinese workers from 1986 to 2006, including documented depository of typespecimens. The catalogue therefore also provides complete lists of the type-material of Phasmatodea housed in the following Chinese institutions: Administration of Baishuijiang Natural Reserve (ABNR), Beijing Forestry University, Beijing (BFU), China Agricultural University, Beijing (CAU), Geological Museum of China, Beijing (GMC), Inca Science Ltd., Chongqing (INCA), Institute of Zoology, Chinese Academy of Sciences, Beijing (IZCAS), Department of Biology, Nankai University, Tianjin (NKU), Northwest Sci-Tech University of Agriculture and Forestry, Shaanxi (NWAU), Institute of Zoology, Shaanxi Normal University, Xi’an (SNU), Institute of Entomology, Sun Yat-sen University (ICRI), Shanghai Institute of Entomology, Academia Sinica, Shanghai (SIES), Tianjin Natural History Museum, Tianjin (TMNH), Zhejiang Museum of Natural History, Hangzhou (ZMNH). The known distribution of each species, inmeans of provinces is provided as well. 14 species are shown to have been recorded from China in error, several of these based on misidentifications. The “Phasmatodea-like” fossil taxa described from the Late Jurassic Yixian Formation of North Hebei and West Liaoning are listed in a separate section. Two new generic synonyms are recognized: Arthminotus Bi, 1995 synonymised with Lopaphus Westwood, 1859 (n. syn.) and Dianphasma Chen & He, 1997 synonymised with Parasosibia Redtenbacher, 1908 (n. syn.). The genus Linocerus Gray, 1835 (Type-species: Linocerus gracilis Gray, 1835) was erroneously synonymised with the mediterranean Bacillus St. Fargeau & Audinet-Serville, 1825 and is here re-established in Phasmatidae: Pachymorphinae: Gratidiini (rev. stat.). Relationship to Clonaria Stål, 1875 (= Gratidia Stål, 1875, = Paraclonaria Brunner v. Wattenwyl, 1893), Sceptrophasma Brock & Seow-Choen, 2000 and Macellina Uvarov, 1940 is obvious. 21 species are transferred to other genera (new combinations): Asceles dilatatus Chen & He, 2004 and Asceles quadriguttatus Chen & He, 1996 to Pachyscia Redtenbacher, 1908, Arthminotus sinensis Bi, 1995 to Lopaphus Westwood, 1859, Baculum dolichocercatum Bi & Wang, 1998 and Baculum politum Chen & He, 1997 to Medauroidea Zompro, 1999, Dixippus hainanensis Chen & He, 2002, Dixippus huapingensis Bi & Li, 1991, Dixippus nigroantennatus Chen & He, 2002, Dixippus parvus Chen & He, 2002 and Entoria bobaiensis Chen, 1986 to Lonchodes Gray, 1835, Sipyloidea obvius Chen & He, 1995 to Sinophasma Günther, 1940, Paramyronides biconiferus Bi, 1993, Paramyronides leishanensis Bi, 1992, Lonchodes chinensis Brunner v. Wattenwyl, 1907, Lonchodes confucius Westwood, 1859 and Phasgania glabra Günther, 1940 to Phraortes Stål, 1875, Gratidia bituberculata Redtenbacher, 1889 and Leptynia xinganensis Chen & He, 1993 to Sceptrophasma Brock & Seow-Choen, 2002, Prosentoria bannaensis Chen & He, 1997 to Paraentoria Chen & He, 1997, and Mantis squeleton Olivier, 1792 to Phanocloidea Zompro, 2002. Acrophylla sichuanensis Chen & He, 2001 remains of unknown generic assignment, but is shown to be not a member of the Australian genus Acrophylla Gray, 1835. Furthermore, as Baculum Saussure, 1861 is a neotropical genus and most Old World species previously attributed to this genus are now listed in Ramulus Saussure, 1861, all Chinese species described in Baculum Saussure are consequently transferred to Ramulus Saussure. Other changes of specific placements are based on published literature and concern to the following three synonymies not recognized by Chinese workers: Abrosoma Redtenbacher, 1906 (= Prosceles Uvarov, 1940), Necroscia Audinet-Serville, 1838 (= Aruanoidea Redtenbacher, 1908), Lopaphus Westwood, 1859 (= Paramyronides Redtenbacher, 1908). Megalophasma Bi, 1995 is transferred from Necrosciinae to Lonchodinae. Four lectotypes are designated and three new specific synonyms revealed. A lectotype is designated for Rhamphophasma modestus Brunner v. Wattenwyl, 1893, the type-species of Rhamphophasma Brunner v. Wattenwyl, 1893, in order to fix this genus and species. The male paralectotype is shown to be a male of Parapachymorpha nigra Brunner v. Wattenwyl, 1893, the type-species of Parapachymorpha Brunner v. Wattenwyl, 1893. Clitumnus porrectus Brunner v. Wattenwyl, 1907 is synonymised with Bacillus ? artemis Westwood, 1859 and a lectotype designated for the former (n. syn.). A lectotype is designated for Oxyartes lamellatus Kirby, 1904 in order to fix this taxon and confirm the synonymy established by Dohrn, 1910 (= Oxyartes honestus Redtenbacher, 1908, = Oxyartes spinosissimus Carl, 1913). Paracentema stephanus Redtenbacher, 1908 is shown to have been erroneously synonymised with Neohirasea japonica (de Haan, 1842) and here synonymised with Neohirasea maerens (Brunner v. Wattenwyl, 1907) (n. syn.). In order to fix this new synonymy a lectotype is designated for Paracentema stephanus Redtenbacher, 1908. Finally, a biogeographic analysis of the Chinese phasmid fauna is presented. This includes brief background information on the topography and biogeography of China along with maps showing the seven zoogeographical subregions currently recognized as well as the 4 municipalities, 23 provinces, 5 autonomous regions and 2 special administrative regions of China. A summary of the taxonomic compilation of the fauna is provided and its relationships with neighbouring regions, of both the Palaearctic and Oriental realms, are discussed. A study is presented on the distribution of the taxa and species densities of each province / autonomous region. Recent ecological studies are summarized and list of the host plants of 42 different species attached. The pest status of certain species which have become of serious importance for agriculture in China is briefly summarized based on literary sources.

ABSTRACT The 2019 Nobel Prize in Chemistry was awarded to three pioneers of lithium-ion batteries (LIBs)—Prof. John B. Goodenough at the University of Texas, Prof. M. Stanley Whittingham at the State University of New York and Mr. Akira Yoshino at the Asahi Corporation of Japan, which is a great encouragement to the whole field. LIBs have been developed for several decades with the progress slowing down and their performances approaching some theoretical limits. On the other hand, new types of batteries or power systems, including solid-state batteries, sodium-ion batteries, lithium-sulfur batteries and fuel cells, are being steadily developed, offering new choices for divergent applications. In this panel discussion chaired by NSR editorial board member Huiming Cheng, battery experts gather to discuss the challenges and trends of LIBs, the developments and applications of next-generation batteries, as well as the status quo of the battery research and industry in China. Jun Chen Professor of the College of Chemistry, Nankai University, Tianjin, China Yunhui Huang Professor of the School of Materials Science and Engineering, Huazhong University of Science and Technology, Wuhan, China Hong Li Professor of the Institute of Physics, Chinese Academy of Sciences, Beijing, China Shigang Sun Professor of the College of Chemistry and Chemical Engineering, Xiamen University, Xiamen, China Hongli Zhang Director of the R&D Institute of Battery, Gotion High-Tech Power Energy Co., Ltd., Hefei, China Huiming Cheng (Chair) Professor of the Shenzhen Geim Graphene Center, Tsinghua-Berkeley Shenzhen Institute, Tsinghua University, Shenzhen, China; Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang, China

Abstract If the core of chemistry is making molecules, then the construction of those found in nature—natural products—has long been regarded as one of the highest forms of the art in synthesis. These molecules, produced by living organisms for a variety of purposes, are a key source of pharmaceuticals such as antibiotics and anticancer agents. The medicinal value of natural products has been known for centuries via herbal treatments, and such compounds are still collected, refined and screened for potential drugs today, sometimes being identified from local ‘folk medicine’ practices. By identifying the active ingredients of natural extracts used in traditional medicine, chemists can then synthesize modified forms that may be even more active: this was how the analgesic aspirin was first identified as a derivative of the plant hormone salicylic acid from willow bark. As well as offering such derivatives, natural-product synthesis in organic chemistry can potentially provide a more plentiful alternative source of natural products that are available in only tiny amounts from their natural sources. Efforts to devise cheap and efficient synthetic strategies for molecules such as paclitaxel (Taxol, an anticancer agent present in the Pacific yew) and artemisinin (an anti-malarial extracted from the herb sweet wormwood, qinghao (青蒿), and recognized by the 2015 Nobel Prize for Medicine) are still on-going to satisfy global demand. Organic synthesis is about much more than making natural products: it contributes, for example, to catalysis, polymer chemistry, food science and the development of wholly synthetic drugs. Yet efforts to make complex natural products may supply a motivational testing ground for developing new synthetic techniques with broader applications. Indeed, many chemists prize the discovery of a new synthetic method above the recreation of some complex natural molecule: it is the means, not the end, that matters. The field of organic and natural-product synthesis has a strong history in China, where there is a long tradition of herbal medicine. The use of the qinghao extract for treating malaria is first recorded in AD 340, in a manual that the 2015 Nobel laureate Tu Youyou says she consulted for clues about isolating the compound in the beginning of 1970s. Some say that, in the past decade, Chinese natural-product chemistry has entered a ‘golden era’ (Zheng Q-Y and Li A. Sci China Chem 2016;59: 1059–60). Qi-Lin Zhou of Nankai University and Xiaoming Feng of Sichuan University have been at the forefront of this upsurge. Both of them have developed methods for making so-called chiral molecules: arrangements of atoms that have a handedness, so that they can exist in two mirror-image versions. Natural products typically are chiral molecules, and their biological activity may depend on having the correct handedness. The selective synthesis of chiral molecules (asymmetric synthesis) is therefore vital to natural-product chemistry, and typically involves the use of catalysts that are chiral themselves. National Science Review spoke to Zhou and Feng about their work and their perspectives on organic synthesis in China. Qi-Lin Zhou of College of Chemistry at Nankai University, China. (Courtesy of Q Zhou)

Abstract Non-small cell lung cancers (NSCLCs) in non-smokers are mostly driven by mutations in the oncogenes EGFR, ERBB2, and MET, and fusions involving ALK and RET. We term these “non-smoking-related oncogenes” (NSROs). NSRO-driven tumors account for approximately half of NSCLCs in East Asia, and, alarmingly, their age-adjusted incidence is increasing for unknown reasons. In addition to occurring in non-smokers, NSRO-driven tumors also occur in smokers. However, the clonal architecture and genomic landscape of these tumors remain largely unexplored. Here, we investigated genomic and transcriptomic alterations in 173 tumor sectors from 48 patients with NSRO-driven or typical-smoking NSCLCs. Overall, NSRO-driven NSCLCs in smokers and non-smokers had similar genomic landscapes and clonal architectures that were distinct from those in typical-smoking NSCLCs. Surprisingly, even in patients with prominent smoking histories, the mutational signature caused by tobacco smoking was essentially absent in NSRO-driven NSCLCs. We confirmed this unexpected finding in two large NSCLC data sets from other geographic regions. However, we observed differences in the tumor transcriptomes of NSRO-driven NSCLCs in smokers and non-smokers, with tumors in smokers displaying higher transcriptomic activities related to regulation of the cell cycle. This suggested that smoking does have an impact on tumor phenotype in NSCRO-driven NSCLC, likely through non-genetic mechanisms. We concluded that NSRO-driven NSCLCs, whether in non-smokers or smokers, constitute an important disease entity that is very different from typical-smoking NSCLC. Citation Format: Chen-Yang Huang, Nanhai Jiang, Meixin Shen, Gillianne Lai, Aaron C. Tan, Amit Jain, Stephanie P. Saw, Mei-Kim Ang, Quan Sing Ng, Darren Wan-Teck Lim, Ravindran Kanesvaran, Eng-Huat Tan, Wan Ling Tan, Boon-Hean Ong, Kevin L. Chua, Devanand Anantham, Angela Takano, Tony KH Lim, Wai Leong Tam, Ngak Leng Sim, Anders J. Skanderup, Daniel S.W. Tan, Steven G. Rozen. Dearth of smoking-induced mutations in oncogene-driven NSCLCs despite smoking exposure [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 1748.

Antonova, O. (2012). The essence of the concept of creativity: problems and searches. Theoretical and applied aspects of the development of creative education in higher educational establisjments: a monograph, edited by O.A. Dubasenyuk. Zhytomyr: I. Franko Publishing house, 14–41. (In Ukrainian) Batyuta, T., & Dychkivs’ka, I. (2001). Basics of the pedagogical innovation. Rivne: Rivne state humanistic university. (In Ukrainian) Dychkivs’ka, I. (2011). Basics of the pedagogical innovation. Rivne: Rivne state humanistic university. (In Ukrainian) Edens, D., Dy, H., Dalske, J., & Strain, C. (2015). Cognitive Skills Development Among Transfer College Students: An Analysis by Student Gender and Race. Journal of Education and Training, 2, 117-135. https://doi.org/10.5296/jet.v2i2.7227 Glazkova, I., Khatuntseva, S., & Yaroshchuk, L. (2020). Professional pedagogical culture. Historical culturological aspect. Romanian magazine for multidimensional education, 12(3), 144-161. https://doi.org/10.18662/rrem/12.3/314 Jackson, N. (2013). Developing Students' Creativity through a Higher Education. International Symposium on «Cultivation of Creativity in University Students», Macao Polytechnic Institute. https://acortar.link/Cp736f Khymynets’, V. (2009). Innovative educational activity. Ternopil: Mandrivets’. (In Ukrainian) Kurok, V., Tkachenko, N., Burchak, S., Kurok, R., & Burchak, L. (2022). Developing Intending Teachers’ Creativity in the Process of Their Professional Training in the Context of Educational Transformations. Romanian Magazine for Multidimensional Education, 14(1), 246-262. Lubart, T. (2010). Children’s creative potential: an empirical study of measurement issues. Learning and Individual Differences, 20, 388-392. Marieiev, D., Marieievа T., Yaroshevska, L., Kaminskyy, V., & Viesova, O. (2023). Modern Teacher Education in Ukraine and EU Countries: Transformation, Vectors of Development. Journal of Higher Education Theory and Practice, 23(5). https://doi.org/10.33423/jhetp.v23i5.5947 Nerubasska, A., & Maksymchuk, B. (2020). The Demarkation of creativity, talent and genius in humans: a systemic aspect. Postmodern openings, 11(2), 240-255. https://doi.org/10.18662/po/11.2/172 Novolokova, N. (2019). Encyclopedia of the pedagogical technologies and innovations. Kharkiv: Osnova. (In Ukrainian) Onyshchenko, I. (2016). Ways of forming the creative potential of the future primary school teacher in the process of the professional training. Pedagogical sciences: theory, history, innovative technologies, 7, 397-403. (In Ukrainian) Petrovych, O. (2014). Designing the creative educational environment based on the subject-subject interaction of the teacher and future language teachers. Scientific Bulletin of Bohdan Khmelnytsky Melitopol State Pedagogical University. Series: Pedagogy. Melitopol: MDPU, 311–315. (In Ukrainian) Stojanova, B. (2010). Development of creativity as a basic task of the modern educational system. Procedia Social and Behavioral Sciences, 2, pp. 3395-3400. https://doi.org/10.1016/j.sbspro.2010.03.522 Sydorenko, V., & Dmytrenko P. (2000). Basics of the scientific research. Kyiv: Publishing centre «DINIT”. (In Ukrainian)» Tan, K., Albakri, K., Lim, K., Fei, G., & Sang Long, C. (2018). Characteristics of Creative Students Versus Academic Performance. International Journal of Human Resource Studies, 8, 69. https://doi.org/10.5296/ijhrs.v8i2.12718 Tokman’ H. (2012). Methods of teaching Ukrainian literature in secondary school. K.: Academia. (In Ukrainian) Vaganova, O., Ilyashenko, L, Smirnova, Z., Bystrova, N., & Kaznacheeva, S. (2019). Students’ creative abilities development in higher educational institution. Amazonia Investiga, 8(22), 701-710. Retrieved from https://www.amazoniainvestiga.info/index.php/amazonia/article/view/822 Wen, L., Zhou, M., & Lu, Q. (2017). The influence of leader’s creativity on employees’ and team creativity: Role of identification with leader. Nankai Business Review International, 8(1), 22-38. Wu, H.Y., Wu, H.S., Chen, I.S., & Chen, H.C. (2014). Exploring the critical influential factors of creativity for college students: A multiple criteria decision-making approach. Thinking skills and creativity, 11(2014), 1-21.

This special issue on ICT Based Disaster Resilient Society features ten articles resulting from a collaborative research project on natural disaster management conducted by the Kyoto University Disaster Prevention Research Institute (DPRI) researchers and information and communication technology (ICT) experts from Nippon Telegram and Telegraph Co. Ltd (NTT). For the last two years, they have been studying on how to make society more disaster resilient through proper ICT use focusing on cloud computing, the 20th century’s greatest invention. In part of a formal research partnership agreement signed in 2005, Kyoto University and NTT have been promoting new research in disaster management. The first two years showed with little concrete achievement beyond implementing one small research project - not exactly what the agreement envisioned. In 2008, volunteers from Kyoto University and NTT meeting to determine the reason found a tactical mistake - starting by picking projects collaboratively assuming that DPRI and NTT’s disaster management research section shared the same vision and understanding of disaster management. Fundamental differences in research focus also raised problems in finding suitable collaborative research activities. Briefly, at least three tiers existed for promoting ICT based disaster resilient society: 1) the ICT system infrastructure, 2) the operating system, and 3) individual applications in making society more disaster resilient. NTT was focusing on the first two tiers and DPRI on the last top tier. With this common understanding clarified, collaborative research was set in 2008 on ICT Based Disaster Resilient Society to formulate common ground between the two groups of researchers sharing a common operational picture. One result was a 2009 book from Nikkei BP Publications disseminating to the general public what disaster resilient society looks like, what can be done, and how to do it. This special issue goes one step further by delivering these research efforts to a worldwide audience. The first three articles, from the NTT group, describe the ICT basis for making society more disaster resilient, focusing on recent cloud computing advances as the projected venue for disaster management information systems. In article 1, Iwatsuki et al. introduce the autonomous, scattered, but coordinated network concept in a brief history of “Realization of Resilient Society with Information Technology Revolution.” Article 2 has Maeda et al. explained how the ICT system infrastructure, the next-generation network (NGN), provides better disaster management services in “Next Generation ICT Services Underlying the Resilient Society.” In article 3, Higashida et al. detail how organizational structures and information processing systems operate and are improved continuously through the NGN-based ICT infrastructure in “Risk Management and Intelligence Management During Emergency.” Six articles, from the DPRI group, deal with how ICT based information systems help calculate different damage due to different natural hazards, help strategically in compiling disaster management planning, and help implement effective emergency response and recovery. Kamai proposes how local communities can use land-slide databases offered through cloud computing in “Neural Network-Based Risk Assessment of Artificial Fill Slope in Residential Urban Region.” Fukuoka introduces an attempt to set up worldwide landslide databases in “Application of ICT to Contribution to Resilient Society Against Landslides.” Kobayashi et al. analyze the relationship between flooding and economic loss using detailed numerical simulation in “Development of a Framework for the Flood Economic Risk Assessment Using Vector GIS Data.” Chen et al. estimate possible impact of the Tokai-Tonakai-Nankai earthquake predicted in the 2030s taking into account Japan’s dwindling population from a disaster planning perspective in “Adapting the Demographic Transition in Preparation for the Tokai-Tonankai-Nankai Earthquake.” One objective of ICT based information infrastructures is to help society recover quickly from disaster impact through minimal damage and loss. Hatayama et al. introduce two risk-adaptive regional management information system (RARMIS) concept applications in “Implementation Technology for a Disaster Response Support System for Local Government.” Urakawa et al. introduce elaborated ICT based life recovery for disaster victims implemented in Kashiwazaki City, devastated by the 2007 Niigata Chuetsu-oki earthquake, in “Building Comprehensive Disaster Victim Support System.” The last article, “Risk Management for Hospitals Using the Incident Report,” reports wider collaborative research covering risk areas outside of natural hazards and the formulation of a research group going beyond DPRI. Takeda et al. introduce an ICT based system to help risk managers at Kyoto University Hospital by automatically analyzing medical incident reports. We editors would like to sincerely thank the Kyoto University and NTT collaborative researchers on ICT Based Disaster Resilient Society for their contribution and support. We would like to note with sincere appreciation that this publication is made possible in part by the support from “Special Project for Metropolitan Earthquake Disaster Mitigation in Tokyo Metropolitan Area (2007-2011)” by the Ministry of Education, Culture, Sports, Science, and Technology of Japan (MEXT). We also thank Wakai of Fuji Technology Press Ltd. for his dedicated compilation of this special issue.

Background:Upadacitinib (UPA) has been shown to be effective in patients with active ankylosing spondylitis (AS) [1]. However, improvements in global functioning and health-related quality of life (HRQoL) in these patients, and their relationship with established clinical response measures have not been fully characterized.Objectives:To evaluate the effect of UPA on the Assessment of SpondyloArthritis international Society Health Index (ASAS HI) and Ankylosing Spondylitis Quality of Life (ASQoL) questionnaire and quantify incremental improvements in ASAS HI and ASQoL response in patients achieving established AS disease activity and physical function improvements at Week (Wk) 14.Methods:This was a post-hoc analysis of the SELECT-AXIS 1 trial [1]. Patients received either UPA 15 mg once daily or placebo (PBO) for 14 wks. Mean change in ASAS HI and ASQoL from baseline (BL) to Wks 4, 8 and 14 for UPA and PBO were calculated and UPA vs PBO responses were compared. Changes in ASAS HI and ASQoL above the minimum clinically important difference (MCID ≥3-point improvement for both measures) and ASAS HI ‘good health state’ (ASAS HI score ≤5) at Wk 14 were determined. Changes from BL in ASAS HI and ASQoL were assessed within the combined UPA and PBO group reaching established improvement thresholds across AS clinical response measures (ASAS response criteria, ASDAS improvement criteria, and BASFI MCID) at Wk 14. Mean ASAS HI and ASQoL changes across groups within each measure and magnitude of ASAS HI and ASQoL change between responders and non-responders were compared.Results:UPA treatment resulted in significant improvement from BL in ASAS HI and ASQoL at Wk 14 with more patients achieving a MCID and ASAS HI good health state vs PBO (Table). Significant improvements were observed earlier for ASAS HI than for ASQoL, starting at Wk 4. At Wk 14, achievement of clinical improvement thresholds was associated with increasing improvements in both ASAS HI and ASQoL scores (Figures 1 and 2). The magnitude of improvement between the best and worst response categories was greater for ASAS HI than ASQoL: 43-fold vs 7-fold for ASAS response, 5-fold vs 3.8-fold for ASDAS improvement, and 34-fold vs 10.4-fold for BASFI MCID achievement.Table.ASAS HI and ASQoL Outcomes at Week 14ASAS HIASQoLOutcomeUPA(n=93)PBO(n=94)UPA(n=93)PBO(n=94)LSM change from baseline-2.8a-1.4-4.2a-2.7Achievement of MCID (≥3-point improvement)c, n/N (%)38/85 (44.7)b24/89 (27.0)51/83 (61.4)b37/86 (43.0)ASAS HI good health state (ASAS HI score ≤5)d, n/N (%)33/74 (44.6)b15/71 (21.1)NANAap<0.05 vs PBO based on mixed-effects model for repeated measuresbp<0.05 vs PBO based on Cochran-Mantel-Haenszel test with non-responder imputationcIn patients with ASAS HI/ASQoL score ≥3 at baselinedIn patients with ASAS HI >5 at baselineLSM, least squares mean; NA, not applicableConclusion:UPA treatment in patients with active AS resulted in clinically meaningful improvements vs PBO in global functioning and HRQoL as measured by ASAS HI and ASQoL, with both measures showing discriminatory ability. Earlier UPA vs PBO response and greater magnitude of change across known clinical response groups suggests that ASAS HI may demonstrate greater responsiveness and ability to capture improvements in AS disease activity and physical function achieved with treatment.References:[1]van der Heijde D, et al.Lancet2019;394:2108–17.Acknowledgments:Financial support for the study was provided by AbbVie. AbbVie participated in interpretation of data, review, and approval of the abstract. All authors contributed to development of the abstract and maintained control over final content. Medical writing services, provided by Joann Hettasch of JK Associates Inc., were funded by AbbVie.Disclosure of Interests:Uta Kiltz Grant/research support from: AbbVie, Amgen, Biogen, Novartis, Pfizer, Consultant of: AbbVie, Biocad, Eli Lilly and Company, Grünenthal, Janssen, Novartis, Pfizer, UCB, Speakers bureau: AbbVie, MSD, Novartis, Pfizer, Roche, UCB, Joachim Sieper Consultant of: AbbVie, Boehringer Ingelheim, Eli Lilly and Company, Janssen, Merck, Novartis, Pfizer, Roche, and UCB Pharma, Speakers bureau: AbbVie, Boehringer Ingelheim, Eli Lilly and Company, Janssen, Merck, Novartis, Pfizer, Roche, and UCB Pharma, Atul Deodhar Grant/research support from: AbbVie, Eli Lilly, GSK, Novartis, Pfizer, UCB, Consultant of: AbbVie, Amgen, Boehringer Ingelheim, Bristol Myer Squibb (BMS), Eli Lilly, GSK, Janssen, Novartis, Pfizer, UCB, Speakers bureau: AbbVie, Amgen, Boehringer Ingelheim, Bristol Myer Squibb (BMS), Eli Lilly, GSK, Janssen, Novartis, Pfizer, UCB, Patrick Zueger Shareholder of: AbbVie, Employee of: AbbVie, In-Ho Song Shareholder of: AbbVie Inc., Employee of: AbbVie Inc., Naijun Chen Shareholder of: AbbVie Inc, Employee of: AbbVie Inc, Désirée van der Heijde Consultant of: AbbVie, Amgen, Astellas, AstraZeneca, BMS, Boehringer Ingelheim, Celgene, Cyxone, Daiichi, Eisai, Eli-Lilly, Galapagos, Gilead Sciences, Inc., Glaxo-Smith-Kline, Janssen, Merck, Novartis, Pfizer, Regeneron, Roche, Sanofi, Takeda, UCB Pharma; Director of Imaging Rheumatology BV

AbstractIn April through July 2010, archaeological excavation was conducted to the sunken ship “Nan'ao I” of the Ming Dynasty in the sea area of Shantou (Swatow) City, Guangdong Province. The discovered ship body was about 20m long with 17 bulkheads and 16 compartments, the longest one of which was 7.5m in length. Over 10,000 pieces of artifacts of various categories were recovered, most of which were porcelains, followed by potteries, bronzes and iron and tin wares, as well as over 15,000 bronze coins. Most of the porcelains were blue-andwhite wares produced in Zhangzhou Kiln at the end of the 16th and the beginning of the 17th centuries, and the date of the sinking of the ship would be roughly the same. The discovery and recovering of “Nan'ao I” provided direct evidence for the researches on the material cultural interchanges among different civilizations and regions.

Review Exhaust Gas After-Treatment Systems for Gasoline and Diesel Vehicles Liye Bao 1, Jihua Wang 2, Lihui Shi 2, and Haijun Chen 1, * 1 College of Electronic Information and Optical Engineering, Nankai University, Tianjin 300350, China 2 Valiant Co., Ltd., Yantai 264006, China * Correspondence: chenhj@nankai.edu.cn Received: 5 October 2022 Accepted: 10 November 2022 Published: 25 December 2022 Abstract: Exhaust gases released from vehicle engines have been a major cause of air pollution, and the emission limits have become much stricter in recent years due to a worldwide concern about the impact of air pollution on public health. These regulations have been complied to minimize the emissions of carbon monoxide (CO), hydrocarbons (HCs), nitrogen oxides (NO x) and particulate matter (PM) from gasoline and diesel vehicles engines. Different after-treatment systems (ATS) have been developed for the treatment of exhaust gases from gasoline and diesel engines, respectively. The ATS for gasoline engine based on the three-way catalysts (TWCs), as well as the ATS for diesel engines including diesel oxidation catalysts (DOC), selective catalytic reduction (SCR), diesel particulate filters (DPF) and ammonia slip catalysts (ASC), are summarized in this mini-review.

We gratefully acknowledge the presence of all participants on the 2021 International Conference on Mechanical Automation and Electronic Information Engineering (MAEIE 2021), which was successfully held in Zhuhai from 24th to 26th September, 2021. MAEIE 2021 aimed to provide a platform for experts and scholars, engineers and technicians, and R&D personnel to share scientific research results and cutting-edge technologies, understand academic development trends, broaden research ideas, strengthen academic research and discussion, and promote cooperation in the industrialization of academic results. MAEIE 2021 focused on professional fields such as Mechanical Integration, Artificial Intelligence, Intelligent Information Processing, Information Engineering, etc. About 80 participants from academic, high-education institutes and other organizations took part in the conference. The conference model was divided into two sessions, including oral presentations and keynote speeches. In the first part, some scholars, whose submissions were selected as the excellent papers, were given 15 minutes to perform their oral presentations one by one. Then in the second part, keynote speakers were each allocated 30-45 minutes to hold their speeches. In the keynote presentation part, we invited 12 professors as our keynote speakers. The first keynote speaker, Prof. Junlong Chen, IEEE Fellow, from South China University of Technology, China. The second keynote speaker, Prof. Guoliang Chen, from Shenzhen University, China. The others keynote speaker as follow: Prof. Anhui Liang, Shandong University of Science and Technology, China; Prof. Weijia Jia, IEEE Fellow, ACM Fellow, Beijing Normal University - Hong Kong Baptist University United International College, China; Prof. Nong Xiao, from Sun Yat-sen University, China; Prof. Yutong Lu, Sun Yat-sen University, China; Prof. Young Liang, Macau University of Science and Technology, China; Prof. Jianxin Wang, IEEE Senior Member, from Central South University, China; Prof. Xiaofeng Zhu, University of Electronic Science and Technology of China; Prof. Yang Yue, Nankai University, China; Prof. Li Na, from Xi’ dian University, China; Assoc. Prof. Zhengtian Fang, from University of Macau, China. They had outstanding research in Mechanical Automation and Electronic Information Engineering and other related area. The proceedings present a selection of high-quality papers submitted to the conference by researchers from universities, research institutes, and industry. All papers were subjected to peer-review by conference committee members and international reviewers. The papers were selected based on their quality and their relevance to the conference. The proceedings present recent advances in the fields of Mechanical, Force and Tactile Sensors, Industrial Tribology, Machine Vision, Algorithm and Data Structure and others related research. I would like to express special gratitude to members of the conference committee and organizers of the conference. I would also like to thank the reviewers for their valuable time and advice which helped in improving the quality of the papers selected for presentation at the conference and for publication in the proceedings. Finally, I want to thank the authors, the members of the organizing committee, the reviewers, the chairpersons, sponsors, and all other conference participants for their support of MAEIE 2021. The Committee of MAEIE 2021 List of Committee member are available in this pdf.

LANGUAGE NOTE | Document text in Chinese; abstract also in English. 1908年6月，廣東肇慶、南海、東莞、清遠、四會及廣西桂林等地，遭遇特大洪災，牆傾屋摧，崩決百丈，田園徧成澤國，平民葬身魚腹，宛如末日降臨。這場百年不遇的大洪災，將一個人推到了臺前。在這次大洪災中，他每天在報章上刊發自己所撰寫的題爲“救命詞”的詩篇，呼籲大衆關注。許多女子刺繡他的詩義賣，捐錢助賑，爲他贏得了“繡詩樓主人”的雅號。在他的呼籲和感召下，官員、醫院、善堂，甚至優伶娼妓都投身到這次大型賑濟之中，充分體現了香港作爲慈善之都的深切意涵。同時他開創的賣物義賑演變成爲當今香港賣旗的源頭，對當今香港慈善理念的形成都有促進意義。進而，他的後續行爲還揭開了香港保良局領婚領育神秘的面紗之一角，使我們得以窺見粵港融合的過程中少爲人知的另一面。而且他以商人的身分出任香港保良局總理，其一系列的行爲包括賑災、領婚、領育、興辦教育，實際上是承擔了地方官或者地方鄉紳的一部分職能。這實際上是光緒廢科舉之後，不能夠學而優則仕的一部分讀書人，從“士子”轉型爲“紳商”，將“民胞物與，修齊治平”的理念予以現代化轉型及實踐的典型。 In June 1908, a disastrous flood inundated many counties of Guangdong province, such as Zhaoqing, Nanhai, Dongguan, Qingyuan, and Sihui, as well as Guilin in Guangxi province. Thousands of houses were destroyed, millions of people were made homeless, and their fields were all flooded— as though it was the end of the world. Chen Buchi (1870-1934) rose to the historic arena during this very rare catastrophe. In the flood period, Chen published his poems entitled “Save Lives” in the newspaper every day to attract the attention of the public. These poems were embroidered on pieces of cloth by many ladies who sold them to raise funds for victims of the flood. This won Chen the fine sobriquet of Master of Studio of Embroidered Poems. In response to Chen’s call to salvation, many people from different sectors, such as government offices, hospitals, charity bodies, and even actors, actresses, and prostitutes, joined these charity activities. This illustrates Hong Kong’s fine renown of a charity city. In addition, Chen’s invention of selling goods for charity marks the origin of selling flags, which has long been an important fundraising activity in Hong Kong. This enhanced the significance of the concept of charity in today’s Hong Kong. Chen’s later careers unravel part of the mystery about the practices of adoption of orphans and arranged marriages executed by the Po Leung Kuk of Hong Kong. This enables us to learn about this part of history in the integration process between Guangdong Province and Hong Kong, which otherwise could have been unknown to us. As a businessman, Chen became president of the Po Leung Kuk. He conducted a series of social welfare activities, such as salvation of natural disasters, arrangement of marriages, adoption of orphans, and establishment of schools. His work substantially shared certain responsibilities with local officials or gentries. To a certain extent, Chen’s deeds reveal a significant change in the career of intellectuals. Since the abolishment of the imperial examination announced in the reign of Emperor Guangxu (r. 1875-1908), some intellectuals found no way to serve the government after the completion of their study and therefore changed their role from “intellectual” to “gentry businessman.” They became stereotypes for those who modernized the notion of “caring for people by giving them goods” and put it into practice.

The 2022 International Conference on Electronics Technology and Artificial Intelligence (ETAI 2022) was successfully held on September 23rd-25th, 2022 in Chongqing, China (online conference). ETAI 2022 promoted scientific innovation, expanded channels of international academic exchange in science and technology, boosted the development of the Greater Bay Area, and strengthened academic cooperation between China and the outside world. In the conference, we were greatly honored to have Prof. Zhikui Chen from Dalian University of Technology, China to serve as our Conference General Chair. The conference was composed of keynote speeches, oral presentations and online Q&A discussion, attracting 100 delegates worldwide. Firstly, the keynote speakers were each allocated 30-45 minutes to address their speeches. Then in the next part, oral presentations, the excellent papers we had selected were presented by their authors one by one. Four distinguished professors were invited to hold keynote speeches during the conference. Primarily, Prof. Ning Sun from Nankai University, China performed a keynote speech on Modeling, Dynamics, and Intelligent Control of Complicated Underactuated Cranes: Theory and Experiments. And then, Prof. Huajun Dong from Dalian Jiaotong University, China made a report on the title Researches on Characteristics of Vacuum Switching Arc and Actuator. Moreover, Assoc. Prof. Guanglei Wu from Dalian University of Technology, China reported on Path Planning of Industrial Robots for Obstacle Avoidance. Last but not the least, Prof. Bhanu Prakash Kolla from K L University, India shared with us his research: Quantum Computing. All of them combined their own research areas with the conference theme to make dramatic keynote speeches, which triggered heated discussion in the conference. Every participant praised this conference for disseminating insightful knowledge. We are glad to share with you that we’ve selected a bunch of high-quality papers from the submissions and compiled them into the proceedings after rigorously reviewing them. These papers feature but are not limited to the following topics: Electronic Signals, Advanced Electromagnetics, Intelligent Automation, Fuzzy Logic, etc. All the papers have been checked through rigorous review and processes to meet the requirements of publication. We would like to acknowledge all of those who supported ETAI 2022 and made it a great success. In particular, we would like to thank the Journal of Physics: Conference Series, for the hard work of all its colleagues in publishing this paper volume. We sincerely hope that ETAI 2022 turned out to be a forum for excellent discussions that enable new ideas to come about, promoting collaborative research. The Committee of ETAI 2022 List of Committee member is available in this Pdf.

In order to accelerate the development of advanced manufacturing, promote in-depth integration of the Internet, big data, artificial intelligence and the real economy, and foster new growth areas and new drivers in such areas as high-end and medium consumption, innovation-driven development, green and low-carbon development, sharing economy, modern supply chain and human capital services. Computer Academy of Guangdong, Association of Computing Education in Chinese Universities, and Zhuhai Ton-Bridge Medical Technology together with AEIC Academic Exchange Information Center, hosted the 2021 Guangdong-Hong Kong-Macao Greater Bay Area Artificial Intelligence and Big Data Forum (AIBDF 2021) in Zhuhai, China during September 24 to 26, 2021. This conference focused on artificial intelligence, big data and medical and big health AI science, aimed to provide a platform for experts and scholars, engineers and researchers to share scientific research results and cutting-edge technologies, understand academic development trends, broaden research ideas, strengthen academic research and discussion, and promote cooperation in the industrialization of academic achievements. About 300 participants from academic, high-education institutes and other organizations took part in the conference. The conference model was divided into two sessions, including oral presentations and keynote speeches. In the first part, some scholars, whose submissions were selected as the excellent papers, were given 15 minutes to perform their oral presentations one by one. Then in the second part, keynote speakers were each allocated 30-45 minutes to hold their speeches. We were very honored to have Prof. Guoqiang Han, from South China University of Technology as our Conference Chairman. In the keynote presentation part, we invited 16 professors as our keynote speakers. The first keynote speaker, Prof. Junlong Chen, Distinguished Chair Professor, Doctoral Supervisor, Dean of School of Computer Science and Engineering, from South University of Technology. The others keynote speakers as follow: Prof. Guoliang Chen, Parallel algorithms, high performance computing experts; Prof. Anhui Liang, the director of the interdisciplinary research center of optical fiber communication and bio-optics, Shandong University of Science and Technology; Prof. Weijia Jia, from International College of Beijing Normal University-Hong Kong Baptist University; Prof. Zhengtian Fang, from La Trobe University in Australia; Prof. Yutong Lu, from Sun Yat-sen University; Prof. Young Liang, from Macau University of Science and Technology; Prof. Nong Xiao, from Sun Yat-sen University; Prof. Xiaofeng Zhu, from University of Electronic Science and Technology of China; Prof. Jianxin Wang, from Central South University; Prof. Xuan Wang, from Harbin Institute of Technology institute; Prof. Guoqiang Zhong, a member of ACM, IEEE, IAPR and China computer society; Prof. Bing Shi, a member of IEEE, ACM and CCF; Assoc. Prof. Chunjiang Duanmu, from Zhejiang Normal University; Prof. Yang Yue, from Nankai University; Prof. Na Li, from Xi’dian University. The proceedings present a selection of high-quality papers submitted to the conference by researchers from universities, research institutes, and industry. All papers were subjected to peer-review by conference committee members and international reviewers. The papers were selected based on their quality and their relevance to the conference. The proceedings present recent advances in the fields of Direction of Big data, Direction of Artificial Intelligence, Direction of Medical and health care and others related research. I would like to express special gratitude to members of the conference committee and organizers of the conference. I would also like to thank the reviewers for their valuable time and advice which helped in improving the quality of the papers selected for presentation at the conference and for publication in the proceedings. Finally, I want to thank the authors, the members of the organizing committee, the reviewers, the chairpersons, sponsors, and all other conference participants for their support of AIBDF 2021. The Committee of AIBDF 2021 List of Committee member are available in this pdf.

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), a novel coronavirus , is causing a serious worldwide COVID-19 pandemic. The emergence of strains with rapid spread and unpredictable changes is the cause of the increase in morbidity and mortality rates. A number of drugs as well as vaccines are currently being used to relieve symptoms, prevent and treat the disease caused by this virus. However, the number of approved drugs is still very limited due to their effectiveness and side effects. In such a situation, medicinal plants and bioactive compounds are considered a highly valuable source in the development of new antiviral drugs against SARS-CoV-2. This review summarizes medicinal plants and bioactive compounds that have been shown to act on molecular targets involved in the infection and replication of SARS-CoV-2. Keywords: Medicinal plants, bioactive compounds, antivirus, SARS-CoV-2, COVID-19 References [1] R. Lu, X. Zhao, J. Li, P. Niu, B. Yang, H. 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