植物乙烯氣體監(jiān)測(cè)系統(tǒng)——ETD
日期:2017-03-17 14:42:48

主要功能

本系統(tǒng)是全球檢出限和靈敏度很高的乙烯監(jiān)測(cè)系統(tǒng),主要用于植物研究相關(guān)的乙烯氣體監(jiān)測(cè),如種子發(fā)芽、植物生長(zhǎng)發(fā)育、開(kāi)花生理、植物器官衰老、基因表達(dá)、植物病原體相互作用、植物激素間相互作用、蔬果收貨后保藏、植物抗逆性研究(干旱、高溫、重金屬)等。

其中乙烯氣體檢測(cè)儀 ETD-300 采用先進(jìn)的激光技術(shù)(光聲學(xué)原理),即樣品乙烯在光聲腔吸收激光后釋放熱使光聲腔內(nèi)部產(chǎn)生壓力,隨激光頻率增減形成能被微型麥克風(fēng)檢測(cè)到的壓力差,而乙烯濃度越高壓力差越大,從而據(jù)聲波強(qiáng)度差可實(shí)時(shí)快速測(cè)量乙烯氣體(C2H4)絕對(duì)濃度;閥門(mén)控制箱 VC-6 完全自動(dòng)化和電腦控制,接一個(gè)即可以使單個(gè)氣體檢測(cè)儀實(shí)現(xiàn)6個(gè)樣品的自動(dòng)切換測(cè)量,單個(gè)乙烯氣體檢測(cè)儀可以接一個(gè)或多個(gè)閥門(mén)控制箱;烴分解器 CAT-1 則利用鉑金顆粒催化烴氧化分解為水蒸氣和 CO2,為系統(tǒng)提供無(wú)烴干擾的樣品空氣。


測(cè)量參數(shù)

測(cè)量參數(shù):乙烯濃度(ppbv)、氣體流速(l/h)、背景值、模擬輸入(V)

計(jì)算參數(shù):乙烯產(chǎn)量(nl/h


連續(xù)流動(dòng)測(cè)定(左)和積累測(cè)定(右)的乙烯監(jiān)測(cè)數(shù)據(jù)圖


應(yīng)用領(lǐng)域

用于環(huán)境、醫(yī)學(xué)、農(nóng)業(yè)、工業(yè)、生態(tài)、生物等監(jiān)測(cè)領(lǐng)域。特別適合植物生理、發(fā)育研究的超靈敏乙烯測(cè)量。



主要技術(shù)參數(shù)

參數(shù)

乙烯氣體檢測(cè)儀 ETD-300

閥門(mén)控制箱 VC-6

烴分解器 CAT-1


測(cè)量范圍

0-2 ppm / 0-100 ppm(可調(diào))

/

/


檢出限

0.3 ppbv

/

/


噪音(2σ) 

0.3 ppbv

/

/


精度

<1% 或 0.3 ppbv

0.2% FS

/


穩(wěn)定性

<1% 超過(guò) 24 小時(shí)

/

/


零點(diǎn)漂移

+/-1 ppbv

/

/


測(cè)量時(shí)間

7-9 s

/

/


響應(yīng)時(shí)間

30 s (當(dāng)流量為1 l/h時(shí))

300 ms

/


流量

0.25-5 l/h

0.25-5 l/h

0-30 l/h


校準(zhǔn)

使用標(biāo)準(zhǔn)混合氣,每年一次

/

/


通道數(shù)量

/

6(可增至 12, 18 等)

/


測(cè)量模式

/

連續(xù)測(cè)量,積累測(cè)量

/


氣體供應(yīng)壓力

/

0.5-5 Bar

/


過(guò)壓閥

/

在 5 Bar 時(shí)打開(kāi)

/


濾膜類(lèi)型

/

去除粒徑 >7μm 的微粒

/


最大稀釋濃度

/

/

100 ppm


輸出濃度

/

/

< 100 pptv


壓力

/

/

0-6 atm


活性催化劑

/

/

Pt/SiO2


催化溫度

/

/

150–250 ℃


預(yù)熱時(shí)間

30 min

/

< 10 min


尺寸

42x45x14 cm (48.3cm 3U 機(jī)架)

30x45x10 cm (48.3cm 2U機(jī)架)

33x24x14 cm (48.3 cm 3U 半機(jī)架)


工作溫度/濕度

10-28 ℃ / 0-95 % RH

5-40 ℃ / 0-95 % RH

5-40 ℃ / 0-95 % RH


電源要求

90-264 VAC,47-63 Hz

90-264 VAC,47-63 Hz

90-264 VAC,47-63 Hz


功耗

<150 W

<20 W

85 W


進(jìn)氣接口

接外徑 1/8'' 軟管的快速接頭

接外徑 1/8'' 軟管的快速接頭

接外徑 1/8'' 軟管的快速接頭


模擬輸入

0-5 V

/

/


數(shù)據(jù)輸出

USB,CSV 格式

USB,CSV 格式

/


顯示

觸摸屏

LED 指示燈

/



選購(gòu)指南:

6通道監(jiān)測(cè)系統(tǒng)組成如下:


                         

                                  乙烯氣體檢測(cè)儀ETD-300                  +                        閥門(mén)控制箱VC-6                            +          烴分解器CAT-1

注:系統(tǒng)中 3 個(gè)儀器都可以單獨(dú)使用

可酌情選擇單通道系統(tǒng):乙烯氣體檢測(cè)儀 ETD-300+ 烴分解器 CAT-1。


產(chǎn)地:荷蘭Sensor Sense    產(chǎn)地 SensorSense_log.jpg



應(yīng)用舉例

1.1 乙烯測(cè)定在高溫脅迫研究中的應(yīng)用舉例

實(shí)驗(yàn)內(nèi)容簡(jiǎn)介:以生長(zhǎng) 3 周的擬南芥野生型 Col-0,突變體 NahG 和 opr3 植株為材料,研究了其高溫脅迫下的乙烯釋放。其中,野生型 Col-0 高溫脅迫(38℃)下,電導(dǎo)率(電解質(zhì)滲透率)、水楊酸和茉莉酸含量和乙烯釋放增加;突變體 NahG 和 opr3 高溫脅迫(38℃)下電導(dǎo)率、茉莉酸和乙烯釋放也增加,但都低于野生型 Col-0,而高溫脅迫后恢復(fù)階段(水中 22℃)電導(dǎo)率明顯高于 Col-0。研究結(jié)果表明:高溫脅迫下,乙烯迅速產(chǎn)生,其生產(chǎn)受到茉莉酸和水楊酸的調(diào)控。總的來(lái)說(shuō),茉莉酸與水楊酸協(xié)同調(diào)節(jié)植物對(duì)高溫脅迫的耐受,而乙烯主要加快細(xì)胞死亡;突變體 NahG 和 opr3 比野生型 Col-0 的耐熱性差,細(xì)胞死亡多。

圖1 高溫處理下擬南芥植株的水楊酸(a)、電導(dǎo)率(b、c)和乙烯釋放(d、e)

WT:擬南芥野生型;突變株opr3 ;突變株NahG以及培養(yǎng)基agar

Clarke, S.M., et al., Jasmonates act with salicyli c acid to confer basal thermotolerance in Arabidopsis thaliana. New Phytologist, 2009. 182(1): p. 175-187.


1.2 乙烯測(cè)定在營(yíng)養(yǎng)缺乏(Mg)脅迫研究中的應(yīng)用舉例

實(shí)驗(yàn)內(nèi)容簡(jiǎn)介:以生長(zhǎng)5周的水培擬南芥 Col-0 植株為材料,研究了其缺鎂脅迫下的乙烯釋放。缺鎂處理后乙烯生物合成酶基因(例如 At5g43450、At1g06620 和At2g25450)的表達(dá)水平明顯上升,樣品乙烯釋放是對(duì)照組的兩倍多,葉片中抗壞血酸 ASC 和谷胱甘肽 GSH 的氧化態(tài)比例增加。研究結(jié)果表明:植物應(yīng)答缺鎂脅迫存在一些獨(dú)特的信號(hào)通路,且與植物激素有關(guān),而乙烯在應(yīng)答缺鎂過(guò)程中發(fā)揮了關(guān)鍵作用;缺鎂還同步增強(qiáng)了植物抗氧化酶活性。

表 1  鎂元素缺乏處理第 8 天擬南芥新成熟葉片和根系的生理參數(shù)

應(yīng)用舉例-3.png

DHA:ASC,氧化態(tài)脫氫抗壞血酸:抗壞血酸;GSSG : GSH,氧化型谷胱甘肽:谷胱甘肽;Ctrl,鎂元素充足的植株;-Mg,鎂元素缺乏的植株

Hermans, C., et al., Systems analysis of the responses to long-term magnesium deficiency and restoration in Arabidopsis thaliana. New Phytologist, 2010. 187(1): p. 132-144.


1.3 乙烯測(cè)定在病菌感染研究中的應(yīng)用舉例

實(shí)驗(yàn)內(nèi)容簡(jiǎn)介:以品種為 Money Maker 和 Daniela 的成熟番茄果實(shí)為材料,研究了其感染番茄灰霉病菌株 VTF1 的乙烯釋放?;颐共【梢栽隗w外產(chǎn)生乙烯,其乙烯釋放與其說(shuō)與分生孢子萌發(fā)相關(guān),不如說(shuō)與菌絲生長(zhǎng)更相關(guān),且分生孢子濃度越大真菌的乙烯釋放越多。感染灰霉病的兩種番茄的乙烯釋放規(guī)律與灰霉病菌類(lèi)似;但釋放量是其 100 倍。結(jié)合受感染番茄的細(xì)胞學(xué)參數(shù),研究結(jié)果表明:番茄-真菌系統(tǒng)的乙烯釋放不是由番茄灰霉病菌引起的,雖說(shuō)與其內(nèi)部的真菌生長(zhǎng)速率十分同步。

應(yīng)用舉例-4.png

圖 2 真菌(160 μl 懸浮液)的乙烯產(chǎn)量

● 1.5*108 灰霉病菌分生孢子 ml-1  ▲ 2*107 灰霉病菌分生孢子 ml-1  ■ 2*105 灰霉病菌分生孢子 ml-1


應(yīng)用舉例-5.png

圖3  模擬感染和不同濃度番茄灰霉病菌感染的兩種番茄的乙烯釋放

A.番茄品種 Money Maker;B.番茄品種 Daniela;

○ 模擬番茄灰霉病菌感染  ● 1.5*108 灰霉病菌分生孢子 ml-1  ▲ 2*107 灰霉病菌分生孢子 ml-1  ■ 2*105 灰霉病菌分生孢子 ml-1

Cristescu, S.M., et al., Ethylene Production by Botrytis cinerea In Vitro and in Tomatoes. Applied and Environmental Microbiology, 2002. 68 (11): p. 5342-5350.


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