HEXAGON-IMAGING-PAM 蜂巢矩陣葉綠素熒光成像系統
- 公司名稱 上海澤泉科技股份有限公司
- 品牌 其他品牌
- 型號 HEXAGON-IMAGING-PAM
- 產地 德國WALZ
- 廠商性質 代理商
- 更新時間 2024/11/11 11:28:49
- 訪問次數 938
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產地類別 | 進口 | 價格區間 | 面議 |
---|---|---|---|
應用領域 | 環保,食品,生物產業,農業 |
蜂巢矩陣葉綠素熒光成像系統
HEXAGON-IMAGING-PAM
葉綠素熒光成像系統的“六邊形戰士”
精度高,面積大,功能全,應用廣,文獻多,數據可視化!
HEXAGON-IMAGING-PAM是德國WALZ公司最新推出的大型蜂巢矩陣葉綠素熒光成像系統。它憑借高精度的脈沖振幅調制(PAM)技術,可以對20×24cm的區域進行成像。分辨率高達1.2 MP(1000 x 1200 px, 2x2 binning技術,實際是2000×2400),像素尺寸3.45 x 3.45 µm。
超高分辨率的基礎是成像區域光場的均勻性,在設計過程中,光源陣列中LED的位置是經過精心布局的,以保證測量區域內無陰影,所有成像區域內的樣品均勻照光,樣品間的差異可以盡收眼底。大功率LED面板的冷卻效果非常好,可以最大限度的延長LED的使用壽命。
增加遠紅光(FR)LED 面板,可用于測量所研究樣品的Fo'值。
HEXAGON-IMAGING-PAM采用蜂巢矩陣式LED面板拼接技術,單個六邊形蜂巢矩陣單元之間LED的不平橫可以獨立補償,初衷是為實現樣品區域的理想照明提供更優選擇。
盡管成像區域很大,但是它依然足夠靈活,可以測量各種類型的樣品,如盆栽植物,穴盤中培養的植物,培養皿上的植物或多孔板中的藻類懸浮液。
滑動門設計,集成安全關閉功能,開門狀態下,飽和脈沖的強度會被抑制以保護操作人員的眼睛。
主要功能
l 原位測量:活體植物葉綠素熒光成像,直觀顯示樣品光合作用光能利用差異,可導出彩色圖像。
l 成像功能:對Ft、Fo、Fm、Fv/Fm、F、Fm’、Y(II)、Y(NO)、Y(NPQ)、NPQ、qN、qP、qL、PS/50=ETR、Inh等參數進行成像分析。測定調節性能量耗散Y(NPQ),反映植物光保護能力,測定非調節性能量耗散Y(NO),反映植物光損傷程度。
l 程序測量功能:可自動程序測量熒光誘導曲線、快速光曲線和暗弛豫,也可手動測量;在測量過程中能自動分析所有熒光參數的變化趨勢;可以預編程進行自定義實驗流程,如模擬波動光。
l AOI功能:可在測量前或測量后任意選擇感興趣的區域(AOI),程序將自動對選擇的AOI的數據進行變化趨勢分析,并在報告文件中顯示相關AOI的數據。所有報告文件中顯示的數據都可導出到EXCEL文件中。
l 成像異質性分析功能:對任意參數任意時間的成像,可在圖像上任意選取兩點,軟件自動對兩點間的數據進行橫向異質性分析,并可導出到EXCEL文件中。
l 成像數據范圍分析功能:對任意參數任意時間的成像,可分析任意兩個熒光數值之間有多少個像素點,多少面積(cm2)。
l 突變株篩選功能:可跟據成像結果快速篩選光合、產氫/油、抗逆(抗鹽、抗旱、抗病等)等突變株。
l 微藻毒理研究功能:可同時測量4塊96孔板,即384個微藻樣品(對照和處理組)的光合活性,軟件自動給出處理組樣品相對于對照組的光合抑制百分比。
應用領域
l 光合作用研究:可以在*相同的條件下同時對大量樣品進行成像
l 植物病理學:病斑部位(包括肉眼不可見時)成像以及病斑擴散的時空動力學
l 植物脅迫生理學:肉眼不可見生物/非生物脅迫損傷的早期檢測
l 遺傳育種:出苗后大規模快速篩選高光合/抗旱/抗熱/抗凍/抗病等植株
l 突變株篩選:快速篩選模式植物的光合突變株、抗逆突變株、產氫微藻突變株等
l 微藻毒理學:不同毒物濃度多個重復的樣品一次測完,軟件自動計算抑制比率
l 其它多種擴展研究
成像參數
Fo, Fm, F, Ft, Fm', Fv/Fm, Y(II), qL, qP, qN, NPQ, Y(NPQ), Y(NO), PS/50=ETR,Inh.等
產地:德國WALZ
參考文獻
數據來源:光合作用文獻Endnote數據庫,原始數據來源:Google Scholar。
注:HEXAGON-IMAGING-PAM為最新產品,暫無文獻發表,最新研究成果可參考M-IMAGING-PAM發表文章。
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014年2月,上海澤泉科技股份有限公司在上海浦東孫橋現代農業園區投資成立了上海乾菲諾農業科技有限公司,建設了AgriPhenoTM “高通量植物基因型-表型-育種服務平臺”,為植物科研和育種單位提供全面的樣品收集和栽培,實驗設計和項目合作,以及表型數據與生物信息學分析綜合服務。平臺成功主持了上海張江國家自主創新示范區專項發展資金重點項目“澤泉科技高通量植物基因型-表型-育種服務平臺”。作為主持單位或合作單位參與了上海市農委和科委的30多項政府科研服務項目以及商業服務項目,如科技興農種業發展項目“農作物分子育種的技術創新研究”和“青菜高通量表型圖譜標準的建立及主要性狀分析”、科技興農重點攻關項目“基于圖像分析及三維建模技術的黃瓜長勢快速評價方法研究”、 “蘭科觀賞花卉分子育種技術研究與產業化應用”等。為了緊追世界科技發展水平,開啟院企合作建立研究型平臺的創新嘗試,上海澤泉科技股份有限公司與上海市農業科學院,結合雙方各自的優勢,于2021年5月在上海農業科學院莊行試驗站聯合成立“上海市農業科學院莊行綜合試驗站澤泉科技植物表型技術研究平臺”,AgriPhenoTM平臺從上海浦東孫橋現代農業園區整體遷出,并入新建的植物表型技術研究平臺。目前平臺除擁有無人機表型平臺、溫室型和實驗室型高通量表型分析系統外,還擁有現代化溫室、生物學實驗室、植物生理生態測量設備、農業氣象測量系統和專業的數據庫平臺,已經具備了對植物、動物基因測序與植物表型研究的各類條件。可以承擔高通量DNA提取、基因測序服務、分子輔助育種、植物生理生態研究等科研實驗任務。同時可以為植物功能基因組、農業育種家提供高通量植物基因型測試、高通量植物表型測試和植物基因型-表型生物信息學數據分析等開放式服務。