食品安全快速检测技术的专利文献计量研究
|
摘要
目前,食品安全快速检测技术得到了飞速发展和广泛应用,也是食品安全领域的研究重点,但是对食品安全快速检测技术的专利文献情报研究几乎空白。本文基于德温特专利数据库和德温特专利分析平台对食品安全快速检测技术领域相关专利进行分析,客观揭示技术发展态势、分析主要原创技术的全球专利布局、挖掘前沿研究热点等;并通过分析在华专利,深度透视我国在食品安全快速检测技术领域实施技术创新所面临的国内外形势和存在的问题。我国为食品安全快速检测技术最大的专利申请国,但是我国专利授权比例有待提高。我国在专利布局战略方面倾向于本土专利布局。结合国际专利分类号分析出我国主要的专利技术领域集中在利用光学、单克隆抗体、核酸和遗传工程等方法和手段进行食品安全快速检测。本文还通过专利地图洞悉全球食品安全快速检测技术领域技术布局变迁及当前热点领域,为食品科研工作者提供参考。
Rapid food safety detection technologies have currently seen rapid development and wide applications and have become a research priority. However, there is a lacuna of bibliometric studies on rapid food safety detection technologies in the literature. This article presents an analysis of patents on rapid food safety detection technologies based on the Derwent Innovations Index Database and the Derwent Innovation Patent Analysis Platform with the aim of revealing the technology trends, understanding the worldwide patent portfolio of the main original technologies and finding hot topics of frontier research. Also, this article provides insights into the domestic and international situation China faces in implementing technical innovations for rapid food safety detection and existing problems in this area. China is the world's largest applicant for patents on rapid detection food safety technologies, but the proportion of patent grants in the country still needs to be improved. There is a trend that Chinese inventors prefer to apply for patents in their own country. According to the international patent classification number, the major technical fields in China are focused on the use of optical methods, monoclonal antibody, nucleic acid and genetic engineering for rapid food safety detection. Through the patent map, this article provides a thorough understanding of the technical layout change of rapid food safety detection worldwide and the current hot topics, which will provide useful information for food researchers.
Rapid food safety detection technologies have currently seen rapid development and wide applications and have become a research priority. However, there is a lacuna of bibliometric studies on rapid food safety detection technologies in the literature. This article presents an analysis of patents on rapid food safety detection technologies based on the Derwent Innovations Index Database and the Derwent Innovation Patent Analysis Platform with the aim of revealing the technology trends, understanding the worldwide patent portfolio of the main original technologies and finding hot topics of frontier research. Also, this article provides insights into the domestic and international situation China faces in implementing technical innovations for rapid food safety detection and existing problems in this area. China is the world's largest applicant for patents on rapid detection food safety technologies, but the proportion of patent grants in the country still needs to be improved. There is a trend that Chinese inventors prefer to apply for patents in their own country. According to the international patent classification number, the major technical fields in China are focused on the use of optical methods, monoclonal antibody, nucleic acid and genetic engineering for rapid food safety detection. Through the patent map, this article provides a thorough understanding of the technical layout change of rapid food safety detection worldwide and the current hot topics, which will provide useful information for food researchers.
引文
[1]谢建华,申明月,李昌.我国食品安全状况分析及对策研究[J].食品工程,2010(3):8-12.DOI:10.3969/j.issn.1673-6044.2010.03.002.
[2]句立言,王世平,王勇.食品安全快速检测技术应用进展[J].中国卫生工程学,2011,10(2):165-168;170.
[3]周思,肖小华,李攻科.食品安全快速检测方法的研究进展[J].色谱,2011,29(7):580-586;593.DOI:10.3724/SP.J.1123.2011.00580.
[4]平建峰.基于纳米功能材料的乳品安全和品质快速检测方法与仪器研究[D].杭州:浙江大学,2012:13-14.
[5]International Standardization Organization.ISO 16140:2003Microbiology of food and animal feeding stuffs.protocol for the validation of alternative methods[S].London:British Standards Institution,2003.
[6]中央人民政府.中华人民共和国食品安全法[EB/OL].(2015-04-25)[2017-08-04].http://www.gov.cn/zhengce/2015-04/25/content_2853643.htm.
[7]吴学彦,韩雪冰,孙琳,等.基于DⅡ的转基因玉米领域专利计量分析[J].情报杂志,2013,32(5):99-102;83.DOI:10.3969/j.issn.1002-1965.2013.05.019.
[8]Clarivate Analytics.Derwent Innovations Index[EB/OL].(2018)[2018-10-25].http://wokinfo.com/products_tools/multidisciplinary/dii/.
[9]Clarivate Analytics.Derwent World Patents Index[EB/OL].(2018)[2018-10-25].https://clarivate.com.cn/products/derwent-worldpatents-index/.
[10]许建武.物联网核心技术的专利主体测度及其发展对策[D].大连:大连理工大学,2013:14.
[11]Clarivate Analytics.Derwent Innovation[EB/OL].(2018)[2018-10-25].https://clarivate.com.cn/products/derwent-innovation/.
[12]Clarivate Analytics.Derwent Data Analyzer[EB/OL].(2018)[2018-10-25].https://clarivate.com.cn/products/derwent-data-analyzer/.
[13]柳倩,桂建军,杨小薇,等.工业机器人传感控制技术研究现状及发展态势:基于专利文献计量分析视角[J].机器人,2016,38(5):612-620.DOI:10.13973/j.cnki.robot.2016.0612.
[14]Armour and Company.Test medium and method for the detection of salmonella:US3704204A[P/OL].1972-11-28[2017-08-11].http://www.derwentinnovation.com.
[15]张忠华,刘云.海洋保护研究的文献及专利计量分析[J].现代情报,2014,34(10):104-111.DOI:10.3969/j.issn.1008-0821.2014.10.022.
[16]张南,马春晖,周晓丽,等.食品科学研究现状、热点与交叉学科竞争力的文献计量学分析[J].食品科学,2017,38(3):310-315.DOI:10.7506/spkx1002-6630-201703049.
[17]李海丽,李玲,曹静.全球太阳能产业专利地图分析[J].科技管理研究,2013,33(22):152-156;161.DOI:10.3969/j.issn.1000-7695.2013.22.034.
[18]李向辉,金福兰,刘玲.基于专利数据的世界农林废弃物循环利用能源技术分析[J].生物质化学工程,2015,49(2):32-38.DOI:10.3969/j.issn.1673-5854.2015.02.007.
[19]吴学彦,韩雪冰,戴磊.基于DⅡ的转基因大豆领域专利计量分析[J].中国生物工程杂志,2013,33(3):143-148.
[20]黄鲁成,石媛嫄,吴菲菲.基于专利数据的太阳能电池研发态势及技术构成分析[J].情报杂志,2015,34(2):116-123.DOI:10.3969/j.issn.1002-1965.2015.02.021.
[21]王静,王淼.我国食品安全快速检测技术发展现状研究[J].农产品质量与安全,2014(2):42-47.
[22]福州大学.一种基于纳米金快速检测牛奶样品中三聚氰胺的方法:CN101718708A[P/OL].2010-06-02[2017-08-11].http://www.derwentinnovation.com.
[23]王学生,冯吉.胶体金免疫浸出和免疫层析结合快速检测药物残留的方法:CN101261274A[P/OL].2008-09-10[2017-08-11].http://www.derwentinnovation.com.
[24]中国人民解放军军事医学科学院放射医学研究所.一套检测常见肠道致病菌的寡核苷酸探针及其用途:CN1683565A[P/OL].2005-10-19[2017-08-11].http://www.derwentinnovation.com.
[25]李欣,黄鲁成.基于文献计量和专利分析的战略性新兴产业研发竞争态势研究:以OLED产业为例[J].科技管理研究,2016,36(8):120-126;132.DOI:10.3969/j.issn.1000-7695.2016.08.022.
[26]徐元浩.基于潜在语义分析的专利文献分析与搜索技术的研究[D].杭州:浙江大学,2010:4-6.
[27]汪满容,刘桂锋,孙华平.基于专利地图的全球大数据技术竞争态势研究[J].现代情报,2017,37(1):148-155.DOI:10.3969/j.issn.1008-0821.2017.01.028.
[28]刘桂锋,王秀红.基于专利地图的薄膜太阳能领域专利引证分析[J].科技管理研究,2012,32(14):197-201.DOI:10.3969/j.issn.1000-7695.2012.14.047.
[29]University Osaka Prefecture.The monoclonal antibody which recognizes ciguatoxins CTX1B and 54-deoxy-CTX1B,and a ciguatoxins detection kit using the same(Clarivate Analytics):JP05757497B2[P/OL].2015-07-29[2017-08-11].http://www.derwentinnovation.com.
[30]Komed Co.Ltd.Monoclonal antibody selectively recognizing listeria monocytogenes,hybridoma producing the antibody,test kit comprising the antibody and detection method of listeria monocytogenes using the antibody:US7390489B2[P/OL].2008-06-24[2017-08-11].http://www.derwentinnovation.com.
[31]Koninklijke Philips Electronics NV.Biotechnological device including an actuation means for changing the mobility of preselected biomolecules:IN200903867P4[P/OL].2010-06-11[2017-08-11].http://www.derwentinnovation.com.
[32]皇家飞利浦电子股份有限公司.包括结构化水凝胶渗透层的生物技术设备:CN101548188A[P/OL].2009-09-30[2017-08-11].http://www.derwentinnovation.com.
[33]南京农业大学.水稻或水稻加工品中B t基因快速检测方法:CN103205496A[P/OL].2013-07-17[2017-08-11].http://www.derwentinnovation.com.
[34]深圳出入境检验检疫局动植物检验检疫技术中心.大豆检疫性病毒病害多重实时荧光PCR检测方法及试剂盒:CN101857904B[P/OL].2013-10-16[2017-08-11].http://www.derwentinnovation.com.
[35]Mmonitor Inc..Primer for detecting salmonella using lamp and use thereof:KR2017030746A[P/OL].2017-03-20[2017-08-11].http://www.derwentinnovation.com.
[36]山东出入境检验检疫局检验检疫技术中心.一种环介导等温扩增技术快速检测胡萝卜成分用的引物组:CN103937900A[P/OL].2014-07-23[2017-08-11].http://www.derwentinnovation.com.
[37]南开大学.一种维生素B 2的酶联免疫检测试剂盒:CN102809658A[P/OL].2012-12-05[2017-08-11].http://www.derwentinnovation.com.
[38]镇江先创生物科技有限公司.一种快速检测动物源食品中三氮脒残留的酶联免疫试剂盒:CN106405089A[P/OL].2017-02-15[2017-08-11].http://www.derwentinnovation.com.
[39]广州泰思科学仪器有限公司.一种食品快速检测仪:CN205656117U[P/OL].2016-10-19[2017-08-11].http://www.derwentinnovation.com.
[40]天津灵卫科技发展有限公司.一种保鲜食品检测样品箱:CN205366565U[P/OL].2016-07-06[2017-08-11].http://www.derwentinnovation.com.
[41]燕慧泉,张仁琼,王磊,等.基于文献计量的诺贝尔奖成果专利垄断战略情报分析:1993年诺贝尔化学奖PCR技术的实证分析[J].科技管理研究,2017,37(7):157-163.DOI:10.3969/j.issn.1000-7695.2017.07.025.
[42]南京财经大学,南京理工大学.粮食品质近红外快速检测无线系统:CN102042968B[P/OL].2012-05-02[2017-08-11].http://www.derwentinnovation.com.
[43]NARIN F.Patent bibliometrics[J].Scientometrics,1994,30(1):147-155.
[44]GRILICHES Z.Patent statistics as economic indicators:a survey[J].Journal of Economic Literature,1990,28(4):1661-1707.DOI:10.3386/w3301.
[45]TSENG C,WU L.Innovation quality in the automobile industry:measurement indicators and performance implications[J].International Journal of Technology Management,2007,37(1/2):162-177.DOI:10.1504/IJTM.2007.011809.
[46]YOON J,PARK Y,KIM M,et al.Tracing evolving trends in printed electronics using patent information[J].Journal of Nanoparticle Research,2014,16(7):1-15.DOI:10.1007/s11051-014-2471-6.
[47]张群,张柏秋.基于Innography的零反式脂肪酸食品专利情报研究[J].情报杂志,2014,33(4):59-64.DOI:10.3969/j.issn.1002-1965.2014.04.011.
[48]韩大平,吴洪.基于“食品科学与工程”学科的专利合作网络结构研究[J].科学管理研究,2013,31(6):110-113.DOI:10.19445/j.cnki.15-1103/g3.2013.06.029.
[49]国家中长期科学和技术发展规划纲要(2006-2020年)[EB/OL].(2006-02-06)[2017-08-11].http://www.most.gov.cn/mostinfo/xinxifenlei/gjkjgh/200811/t20081129_65774.htm.
[50]郑代良.改革开放以来中国高新技术产业政策研究[D].武汉:华中科技大学,2011:98-99.
[2]句立言,王世平,王勇.食品安全快速检测技术应用进展[J].中国卫生工程学,2011,10(2):165-168;170.
[3]周思,肖小华,李攻科.食品安全快速检测方法的研究进展[J].色谱,2011,29(7):580-586;593.DOI:10.3724/SP.J.1123.2011.00580.
[4]平建峰.基于纳米功能材料的乳品安全和品质快速检测方法与仪器研究[D].杭州:浙江大学,2012:13-14.
[5]International Standardization Organization.ISO 16140:2003Microbiology of food and animal feeding stuffs.protocol for the validation of alternative methods[S].London:British Standards Institution,2003.
[6]中央人民政府.中华人民共和国食品安全法[EB/OL].(2015-04-25)[2017-08-04].http://www.gov.cn/zhengce/2015-04/25/content_2853643.htm.
[7]吴学彦,韩雪冰,孙琳,等.基于DⅡ的转基因玉米领域专利计量分析[J].情报杂志,2013,32(5):99-102;83.DOI:10.3969/j.issn.1002-1965.2013.05.019.
[8]Clarivate Analytics.Derwent Innovations Index[EB/OL].(2018)[2018-10-25].http://wokinfo.com/products_tools/multidisciplinary/dii/.
[9]Clarivate Analytics.Derwent World Patents Index[EB/OL].(2018)[2018-10-25].https://clarivate.com.cn/products/derwent-worldpatents-index/.
[10]许建武.物联网核心技术的专利主体测度及其发展对策[D].大连:大连理工大学,2013:14.
[11]Clarivate Analytics.Derwent Innovation[EB/OL].(2018)[2018-10-25].https://clarivate.com.cn/products/derwent-innovation/.
[12]Clarivate Analytics.Derwent Data Analyzer[EB/OL].(2018)[2018-10-25].https://clarivate.com.cn/products/derwent-data-analyzer/.
[13]柳倩,桂建军,杨小薇,等.工业机器人传感控制技术研究现状及发展态势:基于专利文献计量分析视角[J].机器人,2016,38(5):612-620.DOI:10.13973/j.cnki.robot.2016.0612.
[14]Armour and Company.Test medium and method for the detection of salmonella:US3704204A[P/OL].1972-11-28[2017-08-11].http://www.derwentinnovation.com.
[15]张忠华,刘云.海洋保护研究的文献及专利计量分析[J].现代情报,2014,34(10):104-111.DOI:10.3969/j.issn.1008-0821.2014.10.022.
[16]张南,马春晖,周晓丽,等.食品科学研究现状、热点与交叉学科竞争力的文献计量学分析[J].食品科学,2017,38(3):310-315.DOI:10.7506/spkx1002-6630-201703049.
[17]李海丽,李玲,曹静.全球太阳能产业专利地图分析[J].科技管理研究,2013,33(22):152-156;161.DOI:10.3969/j.issn.1000-7695.2013.22.034.
[18]李向辉,金福兰,刘玲.基于专利数据的世界农林废弃物循环利用能源技术分析[J].生物质化学工程,2015,49(2):32-38.DOI:10.3969/j.issn.1673-5854.2015.02.007.
[19]吴学彦,韩雪冰,戴磊.基于DⅡ的转基因大豆领域专利计量分析[J].中国生物工程杂志,2013,33(3):143-148.
[20]黄鲁成,石媛嫄,吴菲菲.基于专利数据的太阳能电池研发态势及技术构成分析[J].情报杂志,2015,34(2):116-123.DOI:10.3969/j.issn.1002-1965.2015.02.021.
[21]王静,王淼.我国食品安全快速检测技术发展现状研究[J].农产品质量与安全,2014(2):42-47.
[22]福州大学.一种基于纳米金快速检测牛奶样品中三聚氰胺的方法:CN101718708A[P/OL].2010-06-02[2017-08-11].http://www.derwentinnovation.com.
[23]王学生,冯吉.胶体金免疫浸出和免疫层析结合快速检测药物残留的方法:CN101261274A[P/OL].2008-09-10[2017-08-11].http://www.derwentinnovation.com.
[24]中国人民解放军军事医学科学院放射医学研究所.一套检测常见肠道致病菌的寡核苷酸探针及其用途:CN1683565A[P/OL].2005-10-19[2017-08-11].http://www.derwentinnovation.com.
[25]李欣,黄鲁成.基于文献计量和专利分析的战略性新兴产业研发竞争态势研究:以OLED产业为例[J].科技管理研究,2016,36(8):120-126;132.DOI:10.3969/j.issn.1000-7695.2016.08.022.
[26]徐元浩.基于潜在语义分析的专利文献分析与搜索技术的研究[D].杭州:浙江大学,2010:4-6.
[27]汪满容,刘桂锋,孙华平.基于专利地图的全球大数据技术竞争态势研究[J].现代情报,2017,37(1):148-155.DOI:10.3969/j.issn.1008-0821.2017.01.028.
[28]刘桂锋,王秀红.基于专利地图的薄膜太阳能领域专利引证分析[J].科技管理研究,2012,32(14):197-201.DOI:10.3969/j.issn.1000-7695.2012.14.047.
[29]University Osaka Prefecture.The monoclonal antibody which recognizes ciguatoxins CTX1B and 54-deoxy-CTX1B,and a ciguatoxins detection kit using the same(Clarivate Analytics):JP05757497B2[P/OL].2015-07-29[2017-08-11].http://www.derwentinnovation.com.
[30]Komed Co.Ltd.Monoclonal antibody selectively recognizing listeria monocytogenes,hybridoma producing the antibody,test kit comprising the antibody and detection method of listeria monocytogenes using the antibody:US7390489B2[P/OL].2008-06-24[2017-08-11].http://www.derwentinnovation.com.
[31]Koninklijke Philips Electronics NV.Biotechnological device including an actuation means for changing the mobility of preselected biomolecules:IN200903867P4[P/OL].2010-06-11[2017-08-11].http://www.derwentinnovation.com.
[32]皇家飞利浦电子股份有限公司.包括结构化水凝胶渗透层的生物技术设备:CN101548188A[P/OL].2009-09-30[2017-08-11].http://www.derwentinnovation.com.
[33]南京农业大学.水稻或水稻加工品中B t基因快速检测方法:CN103205496A[P/OL].2013-07-17[2017-08-11].http://www.derwentinnovation.com.
[34]深圳出入境检验检疫局动植物检验检疫技术中心.大豆检疫性病毒病害多重实时荧光PCR检测方法及试剂盒:CN101857904B[P/OL].2013-10-16[2017-08-11].http://www.derwentinnovation.com.
[35]Mmonitor Inc..Primer for detecting salmonella using lamp and use thereof:KR2017030746A[P/OL].2017-03-20[2017-08-11].http://www.derwentinnovation.com.
[36]山东出入境检验检疫局检验检疫技术中心.一种环介导等温扩增技术快速检测胡萝卜成分用的引物组:CN103937900A[P/OL].2014-07-23[2017-08-11].http://www.derwentinnovation.com.
[37]南开大学.一种维生素B 2的酶联免疫检测试剂盒:CN102809658A[P/OL].2012-12-05[2017-08-11].http://www.derwentinnovation.com.
[38]镇江先创生物科技有限公司.一种快速检测动物源食品中三氮脒残留的酶联免疫试剂盒:CN106405089A[P/OL].2017-02-15[2017-08-11].http://www.derwentinnovation.com.
[39]广州泰思科学仪器有限公司.一种食品快速检测仪:CN205656117U[P/OL].2016-10-19[2017-08-11].http://www.derwentinnovation.com.
[40]天津灵卫科技发展有限公司.一种保鲜食品检测样品箱:CN205366565U[P/OL].2016-07-06[2017-08-11].http://www.derwentinnovation.com.
[41]燕慧泉,张仁琼,王磊,等.基于文献计量的诺贝尔奖成果专利垄断战略情报分析:1993年诺贝尔化学奖PCR技术的实证分析[J].科技管理研究,2017,37(7):157-163.DOI:10.3969/j.issn.1000-7695.2017.07.025.
[42]南京财经大学,南京理工大学.粮食品质近红外快速检测无线系统:CN102042968B[P/OL].2012-05-02[2017-08-11].http://www.derwentinnovation.com.
[43]NARIN F.Patent bibliometrics[J].Scientometrics,1994,30(1):147-155.
[44]GRILICHES Z.Patent statistics as economic indicators:a survey[J].Journal of Economic Literature,1990,28(4):1661-1707.DOI:10.3386/w3301.
[45]TSENG C,WU L.Innovation quality in the automobile industry:measurement indicators and performance implications[J].International Journal of Technology Management,2007,37(1/2):162-177.DOI:10.1504/IJTM.2007.011809.
[46]YOON J,PARK Y,KIM M,et al.Tracing evolving trends in printed electronics using patent information[J].Journal of Nanoparticle Research,2014,16(7):1-15.DOI:10.1007/s11051-014-2471-6.
[47]张群,张柏秋.基于Innography的零反式脂肪酸食品专利情报研究[J].情报杂志,2014,33(4):59-64.DOI:10.3969/j.issn.1002-1965.2014.04.011.
[48]韩大平,吴洪.基于“食品科学与工程”学科的专利合作网络结构研究[J].科学管理研究,2013,31(6):110-113.DOI:10.19445/j.cnki.15-1103/g3.2013.06.029.
[49]国家中长期科学和技术发展规划纲要(2006-2020年)[EB/OL].(2006-02-06)[2017-08-11].http://www.most.gov.cn/mostinfo/xinxifenlei/gjkjgh/200811/t20081129_65774.htm.
[50]郑代良.改革开放以来中国高新技术产业政策研究[D].武汉:华中科技大学,2011:98-99.