移动式大型植物光合表型测量系统

移动式大型植物光合表型测量系统

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2023-05-22 12:54:22
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慧诺瑞德(北京)科技有限公司

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产品简介

移动式大型植物光合表型测量系统CropReporter采用一体化可见光成像+叶绿素荧光成像+多光谱成像技术对冠层尺寸60cmx74cm范围内的植物进行深入的光合表型和形态结构表型测量分析

详细介绍

 

移动式大型植物光合表型测量系统CropReporter采用一体化“可见光成像+叶绿素荧光成像+多光谱成像”技术对冠层尺寸60cm x 74cm范围内的植物进行深入的光合表型和形态结构表型测量分析。系统成像单元配置白光LED和405 nm、460 nm、520 nm、660 nm、720 nm的LED,成像单元除了能够测量数十个光合荧光参数外,还能够测量叶绿素成像、花青素成像、NDVI和可见光表型等(软件直接生成)。

 

系统配备4个轮子,样品室前后门可拉伸升降,可以方便的实现温室内基于“Sensor-to-Plant”模式的人工辅助高通量测量。

 

功能特性

  • 标准版成像面积74 x 60cm,可以移动,适合在温室内测量
  • 可定制成像面积达200 x 200cm 
  • 在百万像素水平上实现对荧光诱导曲线Fo、FI和FP相的测量
  • 全部采用LED光源来提供红外、远红外、白光和近红外
  • 仪器内置电脑用于成像测量、光照控制和数据存储
  • 实现多光谱测量,在测量光合作用之外,获取叶绿素指数、花青素指数、NDVI、红外成像和RGB成像。
  • 对荧光成像和多光谱成像进行逐个像素分析
  • 无二的大型植物测量技术,成像面积从74 x 60 cm到200 x 200 cm 
  • 定制化设计,可以顶部成像,也可以侧面成像,甚至顶部和侧面都成像
  • 可以集成到基于传送系统的高通量植物表型平台中,进行高通量的光合表型测量
  • 大景深成像技术

 

典型应用

 

 

 

 

 

 

 

主要技术参数

  • 相机传感器类型:CCD
  • 相机分辨率:1.3M像素
  • 图像格式:16位RAW格式、JPG格式
  • 光谱范围:350~950 nm
  • 光学滤光片:6种高质量光学干涉滤光片,包括荧光、红光、绿光、蓝光、花青素和近红外滤光片
  • 多光谱和彩色图像光源:白色LED和和405 nm、460 nm、520 nm、660 nm、720 nm的LED
  • LED控制:恒流电源控制LED强度,不采用脉冲调制控制
  • 成像和计算的参数:Fo成像、Fm成像、Ft成像、Ft=5min成像、Fm成像、Fv/Fm成像、Fq成像、ΦPSII成像、ΦRO成像、NPQ100成像、qN成像、qP成像、Rfd100成像、 NDVI成像、RNIR成像、RChl成像.、RAnth成像、RRed成像、RGreen成像、RBlue成像、叶绿素指数成像、花青素指数成像和可见光成像,能够自动计算投影叶面积、Fv/Fm平均值、低于Fv/Fm的面积百分比、ΦPSII平均值、低于ΦPSII的面积百分比、NPQ100平均值、高于NPQ100的面积百分比、Rfd100平均值、低于Rfd100的面积百分比、平均RGB比值、特殊RGB比值的面积百分比、平均叶绿素指数、低于叶绿素指数的面积百分比、平均花青素指数、低于花青素指数的面积百分比等(具体参数取决于版本) ,以及凸包、最小外接圆、最小外接矩形等相关表型参数。 

 

利用PhenoVation光合表型成像技术发表的部分文献

  1. Casto A L, Schuhl H, Schneider D, et al. (2021) Analyzing chlorophyll fluorescence images in PlantCV. Earth and Space Science Open Archive:5. https://doi.org/10.1002/essoar..2
  2. Wang L, Liu F, Hao X, et al. (2021) Identification of the QTL-allele System Underlying Two High-Throughput Physiological Traits in the Chinese Soybean Germplasm Population. Frontiers in Genetics, https://doi.org/10.3389/fgene.2021.600444
  3. Farooq M, van Dijk A D J, Nijveen H, et al. (2021) Prior Biological Knowledge Improves Genomic Prediction of Growth-Related Traits in Arabidopsis thaliana. Frontiers in Genetics, 11:609117. doi: 10.3389/fgene.2020.609117
  4. He Y, Li Y, Yao Y et al. (2021) Overexpression of watermelon m6A methyltransferase ClMTB enhances drought tolerance in tobacco by mitigating oxidative stress and photosynthesis inhibition and modulating stress-responsive gene expression. Plant Physiology and Biochemistry, 168: 340-352.
  5. Wang W, Liu D, Qin M et al. (2021) Effects of Supplemental Lighting on Potassium Transport and Fruit Coloring of Tomatoes Grown in Hydroponics. International Journal of Molecular Sciences, 22(5): 2687 https://doi.org/10.3390/ijms
  6. Singh R R, Pajar J A, Audenaert K, et al. (2021) Induced Resistance by Ascorbate Oxidation Involves Potentiating of the Phenylpropanoid Pathway and Improved Rice Tolerance to Parasitic Nematodes. Frontiers in Plant Science, 12:713870. doi: 10.3389/fpls.2021.713870
  7. Vidak M, Lazarevic B, Petek M, et al. (2021) Multispectral Assessment of Sweet Pepper (Capsicum annuum L.) Fruit Quality Affected by Calcite Nanoparticles. Biomolecules, 11(6), 832; https://doi.org/10.3390/biom
  8. Lazarevic B, Satovic Z, Nimac A, et al. (2021) Application of Phenotyping Methods in Detection of Drought and Salinity Stress in Basil (Ocimum basilicum L.). Frontiers in Plant Science, 12:629441. doi: 10.3389/fpls.2021.629441
  9. Romero-Perez A, Ameye M, Audenaert K, et al. (2021) Overexpression of F-Box Nictaba Promotes Defense and Anthocyanin Accumulation in Arabidopsis thaliana After Pseudomonas syringae Infection. Frontiers in Plant Science, 12:692606. doi: 10.3389/fpls.2021.692606
  10. Meng L, Mestdagh H, Ameye M, et al. (2021) Phenotypic variation of Botrytis cinerea Isolates is influenced by spectral light quality. Frontiers in Plant Science, 11:1233. doi: 10.3389/fpls.2020.01233
  11. De Zutter N, Ameye M, Debode J, et al. (2021) Shifts in the rhizobiome during consecutive in planta enrichment for phosphate-solubilizing bacteria differentially affect maize P status. Microbial Biotechnology, doi:10.1111/1751-7915.13824
  12. Stambuk P, Sikuten I, Preiner D, et al. (2021) Screening of Croatian Native Grapevine Varieties for Susceptibility to Plasmopara viticola Using Leaf Disc Bioassay, Chlorophyll Fluorescence, and Multispectral Imaging. Plants, 10, 661. https://doi.org/10.3390/plants
  13. Tan J, de Zutter N, de Saeger S, et al. (2021) Presence of the Weakly Pathogenic Fusarium poae in the Fusarium Head Blight Disease Complex Hampers Biocontrol and Chemical Control of the Virulent Fusarium graminearum Pathogen. Frontiers in Plant Science, https://doi.org/10.3389/fpls.2021.641890
  14. Flood P, Theeuwen T, Schneeberger K, Keizer P, Kruijer W, et al. (2020) Reciprocal cybrids reveal how organellar genomes affect plant phenotypes. Nature Plants, 10.1038/s41477-019-0575-9ff. ffhal-v2f
  15. Velivelli S L S, Czymmek K J, Li H, Shaw J B, Buchko G W, Shah D M. (2020) Antifungal symbiotic peptide NCR044 exhibits unique structure and multifaceted mechanisms of action that confer plant protection. PNAS, DOI: 10.1073/pnas.2003526117
  16. Bhatnagar N, Pandey S. (2020) Heterotrimeric G-Protein Interactions Are Conserved Despite Regulatory Element Loss in Some Plants. Plant Physiology, DOI: https://doi.org/10.1104/pp.20.01309
  17. Venneman J, Vandermeersch L, Walgraeve C et al. (2020) Respiratory CO2 Combined With a Blend of Volatiles Emitted by Endophytic Serendipita Strains Strongly Stimulate Growth of Arabidopsis Implicating Auxin and Cytokinin Signaling. Frontiers in Plant Science, https://doi.org/10.3389/fpls.2020.544435
  18. Tan J, Ameye M, Landschoot S et al. (2020) At the scene of the crime: New insights into the role of weakly pathogenic members of the fusarium head blight disease complex. Molecular Plant Pathology, DOI: 10.1111/mpp.12996
  19. Prinzenberg A E, Campos-Dominguez L, Kruijer W, Harbinson J, Aarts M G M. (2020) Natural variation of photosynthetic efficiency in Arabidopsis thaliana accessions under low temperature conditions. Plant Cell & Environment, 1–14. https://doi.org/10.1111/pce.13811
  20. Zhang H, Chen Y, Niu Y, Zhang X, Zhao J, Sun L, Wang H, Xiao J, Wang X. (2020) Characterization and fine mapping of a leaf yellowing mutant in common wheat. Plant Growth Regulation, https://doi.org/10.1007/s10725-020-00633-0
  21. Jin X, Zarco-Tejada P, Schmidhalter U, Reynolds M P et al. (2020) High-throughput estimation of crop traits: A review of ground and aerial phenotyping platforms. IEEE Geoscience and Remote Sensing Magazine, DOI: 10.1109/MGRS.2020.2998816
  22. Sheng X-G, Branca F, Zhao Z-Q et al. (2020) Identification of Black Rot Resistance in a Wild Brassica Species and Its Potential Transferability to Cauliflower. Argonomy, 10: 1400. doi:10.3390/agronomy
  23. Pennisi G, Blasioli S, Cellini A, Maia L, Crepaldi A, Braschi I, Gianquinto G. (2019). Unraveling the Role of Red:Blue LED Lights on Resource Use Efficiency and Nutritional Properties of Indoor Grown Sweet Basil. Frontiers in plant science, 10, 305. doi:10.3389/fpls.2019.00305
  24. Pennisi G, Orsini F, Blasioli S, Cellini A et al. (2019) Resource use efficiency of indoor lettuce (Lactuca sativa L.) c*tion as affected by red:blue ratio provided by LED lighting. Scientific Reports, 9, 14127
  25. Van Es S W, van der Auweraert E B, Silveira S R, Angenent G C, van Dijk A D J, Immink R G H. (2019) Comprehensive phenotyping reveals interactions and functions of Arabidopsis thaliana TCP genes in yield determination. The Plant Journal, doi: 10.1111/tpj.14326
  26. Köhl J, Goossen-van de Geijn H, Groenenboom-de Haas L, et al. (2019) Stepwise screening of candidate antagonists for biological control of Blumeria graminis f. sp. tritici. Biological Control, 136: 104008
  27. Mohd Nadzir M M, Vieira Lelis F M, Thapa B, Ali A, Visser R G F, van Heusden A W, van der Wolf J M. (2019) Development of an in vitro protocol to screen Clavibacter michiganensis subsp. michiganensis pathogenicity in different Solanum species. Plant Phathology, 68(1): 42-48
  28. Sall K, Dekkers B J W, Nonogaki M, Katsuragawa Y, Koyari R, Hendrix D, Willems L A J, Bentsink L, Nonogaki H. (2019) DELAY OF GERMINATION  1LIKE  4 acts as an inducer of seed reserve accumulation. The Plant Journal, 100: 7-19.
  29. Li H, Velivelli S L S, Shah D M. (2019) Antifungal Potency and Modes of Action of a Novel Olive Tree Defensin Against Closely Related Ascomycete Fungal Pathogens. Molecular Plant-Microbe Interactions. 32(12): 1646-1664.
  30. Prinzenberg A E, Viquez-Zamora M, Harbinson J, Lindhout P, van Heusden S. (2018) Chlorophyll fluorescence imaging reveals genetic variationand loci for a photosynthetic trait in diploid potato. Physiologia Plantarum, 164: 163-175.
  31. Van Rooijen R, Harbinson J, Aarts M G M. (2018) Photosynthetic response to increased irradiance correlates to variation in transcriptional response of lipidremodeling and heatshock genes. Plant Direct, 2(7): e00069
  32. Van Bezouw R F H M, Keurentjes J J B, Harbinson J, Aarts M G. (2018) Converging phenomics and genomics to study natural variation in plant photosynthetic efficiency. Plant Journal, 97(1): 112-133.
  33. Domazakis E, Wouters D, Visser R G F, Kamoun S, Joosten M H A J, Vleeshouwers V G A A. (2018) The ELR-SOBIR1 Complex Functions as a Two-Component Receptor-Like Kinase to Mount Defense Against Phytophthora infestans. Molecular Plant-Microbe Interactions, 31(8): 795-802.
  34. Bazakos C, Hanemian M, Trontin C, Jimenez-Gomez J M, Loudet O. (2017) New Strategies and Tools in Quantitative Genetics: How to Go from the Phenotype to the Genotype. Annual Review of Plant Biology, 68:435-455
  35. Van Rooijen R, Kruijer W, Boesten R, van Eeuwijk F A, Harbinson J, Aarts M G M. (2017) Natural variation of YELLOW SEEDLING1 affects photosynthetic acclimation of Arabidopsis thaliana. Nature Communications, 8: 1421
  36. Flood P J, Kruijer W, Schnabel S K, van der Schoor R, Jalink H, Snel J F H, Harbinson J, Aarts M G M. (2016) Phenomics for photosynthesis, growth and reflectance in Arabidopsis thaliana reveals circadian and long-term fluctuations in heritability. Plant Methods, 12: 14. https://doi.org/10.1186/s13007-016-0113-y
  37. Mancarella S, Orsini F, van Oosten M J, SAnoubar R, Stanghellini C, Kondo S, Gianquinto G, Maggio A. (2016) Leaf sodium accumulation facilitates salt stress adaptation and preserves photosystem functionality in salt stressed Ocimum basilicum. Environmental and Experimental Botany, 130: 162-173.
  38. Virlet N, Sabermanesh K, Sadeghi-Tehran P, Hawkesford M J. (2016) Field Scanalyzer: An automated robotic field phenotyping platform for detailed crop monitoring. Functional Plant Biology, 44(1): 143-153.
  39. Gorbe Sanchez E, Heuvelink E, de Gelder A, Stanghellini C. (2015) New Non-invasive Tools for Early Plant Stress Detection. Procedia Environmental Sciences, 29: 249-250.
  40. Kastelein P, Krijger M, Czajkowski R, van der Zouwen P S, van der Schoor R, Jalink H, van der Wolf J M. (2014) Development of Xanthomonas fragariae populations and disease progression in strawberry plants after sprayinoculation of leaves. Plant Pathology, 63(2): 255-263.
  41. Harbinson J, Prinzenberg A E, Kruijer W, Aarts M G M. (2012) High throughput screening with chlorophyll fluorescence imaging and its use in crop improvement. Current Opinion in Biotechnology, 23:221
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