FluorPen手持式叶绿素荧光仪 叶绿素测定仪/叶绿素含量测定仪

FluorPen手持式叶绿素荧光仪 叶绿素测定仪/叶绿素含量测定仪

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2023-06-06 09:45:39
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FluorPen手持式叶绿素荧光仪

详细介绍

FluorPen手持式叶绿素荧光仪

image.pngFluorPen FP110手持式叶绿素荧光仪用于实验室、温室和野外快速测量植物叶绿素荧光参数,具有便携性强、精确度高、性价比高等特点;双键操作,具图形显示屏,内置锂电和数据存储,广泛应用于研究植物的光合作用、胁迫监测、除草剂检测或突变体筛选,还可用于生态毒理的生物检测,如通过不同植物对土壤或水质污染的叶绿素荧光响应,找出敏感植物作为生物传感器用于生物检测。FP110配备多种叶夹型号,用于不同的样品与研究。

应用领域

适用于光合作用研究和教学,植物及分子生物学研究,农业、林业,生物技术领域等。研究内容涉及光合活性、胁迫响应、农药药效测试、突变筛选等。

·植物光合特性研究

·光合突变体筛选与表型研究

·生物和非生物胁迫的检测

·植物抗胁迫能力或者易感性研究

·农业和林业育种、病害检测、长势与产量评估

·除草剂检测

功能特点:

§结构紧凑、便携性强,LED光源、检测器、控制单元集成于仅手机大小的仪器内,重量仅188g

§功能强大,是叶绿素荧光技术的结晶产品,具备了大型荧光仪的所有功能,可以测量所有叶绿素荧光参数

§内置了所有通用叶绿素荧光分析实验程序,包括3套荧光淬灭分析程序、3套光响应曲线程序、OJIP快速荧光动力学曲线等

§高时间分辨率,可达10万次每秒,自动绘出OJIP曲线并给出26个OJIP–test参数image.png

§FluorPen专业软件功能强大,可下载、展示叶绿素荧光参数图表,也可以通过软件直接控制仪器进行测量

§具备无人值守自动监测功能

§内置蓝牙与USB双通讯模块,GPS模块,输出带时间戳和地理位置的叶绿素荧光参数图表

§配备多种叶夹型号:固定叶夹式(适于实验室内暗适应或夜间快速测量)、分离叶夹式(适用于野外暗适应测量)、探头式(透明光纤探头,用于非接触性测量监测或光适应条件下的叶绿素荧光监测)、用户定制式等

§可选配野外自动监测式荧光仪,防水防尘设计

测量程序与功能

·Ft:瞬时叶绿素荧光,暗适应完成后Ft=F0

·QY:量子产额,表示光系统II 的效率,等于Fv/Fm(暗适应状态)或ΦPSII (光适应状态)。

·OJIP:快速荧光动力学曲线,用于研究植物暗适应后的快速荧光动态变化

·NPQ:荧光淬灭动力学曲线,用于研究植物从暗适应到光适应状态的荧光淬灭变化过程。

·LC:光响应曲线,用于研究植物对不同光强的荧光淬灭反应。

·PAR:光合有效辐射,测量环境中植物生长可以利用的400-700nm实际光强(限PAR型号)。

技术参数

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操作软件与实验结果

image.png

产地:捷克

应用案例:

image.png

2017年4月,美国国家航空*(NASA)新一代*植物培养器(Advanced Plant Habitat,APH)搭载联盟号MS-04货运飞船抵达空间站。宇航员使用FluorPen手持仪叶绿素荧光仪在其中开展植物生理学及太空食物种植(growth of fresh food in space)的研究。

参考文献

1. Singh, S., Mohan Prasad, S. & Pratap Singh, V. Additional calcium and sulfur manages hexavalent chromium toxicity in Solanum lycopersicum L. and Solanum melongena L. seedlings by involving nitric oxide. Journal of Hazardous Materials 398, 122607 (2020).

2. Ariyarathna, R. a. I. S., Weerasena, S. L. & Beneragama, C. K. Application of Polyphasic OJIP Chlorophyll Fluorescent Transient Analysis as an Indicator for Testing of Seedling Vigour of Common Bean (Phaseolus vulgaris L.). Tropical Agricultural Research 31, 106–115 (2020).

3. Prity, S. A. et al. Arbuscular mycorrhizal fungi mitigate Fe deficiency symptoms in sorghum through phytosiderophore-mediated Fe mobilization and restoration of redox status. Protoplasma (2020) doi:10.1007/s00709-020-01517-w.

4. Rahman, M. A. et al. Arbuscular Mycorrhizal Symbiosis Mitigates Iron (Fe)-Deficiency Retardation in Alfalfa (Medicago sativa L.) Through the Enhancement of Fe Accumulation and Sulfur-Assisted Antioxidant Defense. International Journal of Molecular Sciences 21, 2219 (2020).

5. Vitorino, L. C. et al. Biocontrol Potential of Sclerotinia sclerotiorum and Physiological Changes in Soybean in Response to Butia archeri Palm Rhizobacteria. Plants 9, 64 (2020).

6. Aalifar, M. et al. Blue Light Improves Vase Life of Carnation Cut Flowers Through Its Effect on the Antioxidant Defense System. Front. Plant Sci. 11, 511 (2020).

7. Muthusamy, M., Yoon, E. K., Kim, J. A., Jeong, M.-J. & Lee, S. I. Brassica Rapa SR45a Regulates Drought Tolerance via the Alternative Splicing of Target Genes. Genes 11, 182 (2020).

8. Muthusamy, M., Kim, J. Y., Yoon, E. K., Kim, J. A. & Lee, S. I. BrEXLB1, a Brassica rapa Expansin-Like B1 Gene Is Associated with Root Development, Drought Stress Response, and Seed Germination. Genes 11, 404 (2020).

9. Herritt, M. T. & Fritschi, F. B. Characterization of Photosynthetic Phenotypes and Chloroplast Ultrastructural Changes of Soybean (Glycine max) in Response to Elevated Air Temperatures. Front. Plant Sci. 11, (2020).

10.Kasampalis, D. S., Tsouvaltzis, P. & Siomos, A. S. Chlorophyll fluorescence, non-photochemical quenching and light harvesting complex as alternatives to color measurement, in classifying tomato fruit according to their maturity stage at harvest and in monitoring postharvest ripening during storage. Postharvest Biology and Technology 161, 111036 (2020).

11.Soares, J. S., Santiago, E. F. & Sorgato, J. C. Conservation of Schomburgkia crispa Lindl. (Orchidaceae) by reintroduction into a fragment of the Brazilian Cerrado. Journal for Nature Conservation 53, 125754 (2020).

12.Poblete, T. et al. Detection of Xylella fastidiosa infection symptoms with airborne multispectral and thermal imagery: Assessing bandset reduction performance from hyperspectral analysis. ISPRS Journal of Photogrammetry and Remote Sensing 162, 27–40 (2020).

13.Chiluwal, A. et al. Deterioration of ovary plays a key role in heat stress-induced spikelet sterility in sorghum. Plant, Cell & Environment 43, 448–462 (2020).

14.Maai, E., Nishimura, K., Takisawa, R. & Nakazaki, T. Diurnal changes in chloroplast positioning and photosynthetic traits of C4 grass finger millet. Plant Production Science 0, 1–13 (2020).

15.De Micco, V. et al. Dust accumulation due to anthropogenic impact induces anatomical and photochemical changes in leaves of Centranthus ruber growing on the slope of the Vesuvius volcano. Plant Biol J 22, 93–102 (2020).

附:OJIP参数及计算公式

Bckg = background

Fo: = F50µs; fluorescence intensity at 50 µs

Fj: = fluorescence intensity at j-step (at 2 ms)

Fi: = fluorescence intensity at i-step (at 60 ms)

Fm: = maximal fluorescence intensity

Fv: = Fm - Fo (maximal variable fluorescence)

Vj = (Fj - Fo) / (Fm - Fo)

Fm / Fo = Fm / Fo

Fv / Fo = Fv / Fo

Fv / Fm = Fv / Fm

Mo = TRo / RC - ETo / RC

Area = area between fluorescence curve and Fm

Sm = area / Fm - Fo (multiple turn-over)

Ss = the smallest Sm turn-over (single turn-over)

N = Sm . Mo . (I / Vj) turn-over number QA

Phi_Po = (I - Fo) / Fm (or Fv / Fm)

Phi_o = I - Vj

Phi_Eo = (I - Fo / Fm) . Phi_o

Phi_Do = 1 - Phi_Po - (Fo / Fm)

Phi_Pav = Phi_Po - (Sm / tFM); tFM = time to reach Fm (in ms)

ABS / RC = Mo . (I / Vj) . (I / Phi_Po)

TRo / RC = Mo . (I / Vj)

ETo / RC = Mo . (I / Vj) . Phi_o)

DIo / RC = (ABS / RC) - (TRo / RC)

上一篇:叶绿素检测仪:专门测量植物叶片中叶绿素含量 下一篇:便携式叶绿素仪的数据转换步骤
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