鐵蛋白(FE)檢測試劑盒(酶聯(lián)免疫吸附試驗法)
ELISA Kit for Ferritin (FE)
- 編號SEA518Ga
- 物種Chicken (Gallus,雞) 相同的名稱,不同的物種。
- 實驗方法雙抗夾心
- 反應時長3h
- 檢測范圍6.25-400ng/mL
- 靈敏度最小可檢測劑量小于等于2.24ng/mL.
- 樣本類型Serum, plasma, tissue homogenates, cell lysates, cell culture supernates and other biological fluids
- 下載 英文說明書 中文說明書
- 規(guī)格 48T96T 96T*5 96T*10 96T*100
- 價格 ¥ 2873 ¥ 4104 ¥ 18468 ¥ 34884 ¥ 287280
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特異性
本試劑盒用于檢測鐵蛋白(FE),經檢測與其它相似物質無明顯交叉反應。
由于受到技術及樣本來源的限制,不可能完成對所有相關或相似物質交叉反應檢測,因此本試劑盒有可能與未經檢測的其它物質有交叉反應。
回收率
分別于定值血清及血漿樣本中加入一定量的鐵蛋白(FE)(加標樣品),重復測定并計算其均值,回收率為測定值與理論值的比率。
樣本 | 回收率范圍(%) | 平均回收率(%) |
serum(n=5) | 80-97 | 94 |
EDTA plasma(n=5) | 97-104 | 101 |
heparin plasma(n=5) | 92-101 | 95 |
精密度
精密度用樣品測定值的變異系數(shù)CV表示。CV(%) = SD/mean×100
批內差:取同批次試劑盒對低、中、高值定值樣本進行定量檢測,每份樣本連續(xù)測定20 次,分別計算不同濃度樣本的平均值及SD值。
批間差:選取3個不同批次的試劑盒分別對低、中、高值定值樣本進行定量測定,每個樣本使用同一試劑盒重復測定8次,分別計算不同濃度樣本的平均值及SD值。
批內差: CV<10%
批間差: CV<12%
線性
在定值血清及血漿樣本內加入適量的鐵蛋白(FE),并倍比稀釋成1:2,1:4,1:8,1:16的待測樣本,線性范圍即為稀釋后樣本中鐵蛋白(FE)含量的測定值與理論值的比率。
樣本 | 1:2 | 1:4 | 1:8 | 1:16 |
serum(n=5) | 88-99% | 81-95% | 95-105% | 91-99% |
EDTA plasma(n=5) | 98-105% | 85-93% | 80-105% | 81-101% |
heparin plasma(n=5) | 80-101% | 85-99% | 86-101% | 94-101% |
穩(wěn)定性
經測定,試劑盒在有效期內按推薦溫度保存,其活性降低率小于5%。
為減小外部因素對試劑盒破壞前后檢測值的影響,實驗室的環(huán)境條件需盡量保持一致,尤其是實驗室內溫度、濕度及溫育條件。其次由同一實驗員來進行操作可減少人為誤差。
實驗流程
1. 實驗前標準品、試劑及樣本的準備;
2. 加樣(標準品及樣本)100µL,37°C孵育1小時;
3. 吸棄,加檢測溶液A100µL,37°C孵育1小時;
4. 洗板3次;
5. 加檢測溶液B100µL,37°C孵育30分鐘;
6. 洗板5次;
7. 加TMB底物90µL,37°C孵育10-20分鐘;
8. 加終止液50µL,立即450nm讀數(shù)。
實驗原理
將鐵蛋白(FE)抗體包被于96孔微孔板中,制成固相載體,向微孔中分別加入標準品或標本,其中的鐵蛋白(FE)與連接于固相載體上的抗體結合,然后加入生物素化的鐵蛋白(FE)抗體,將未結合的生物素化抗體洗凈后,加入HRP標記的親和素,再次徹底洗滌后加入TMB底物顯色。TMB在過氧化物酶的催化下轉化成藍色,并在酸的作用下轉化成最終的黃色。顏色的深淺和樣品中的鐵蛋白(FE)呈正相關。用酶標儀在450nm波長下測定吸光度(O.D.值),計算樣品濃度。
相關產品
編號 | 適用物種:Chicken (Gallus,雞) | 應用(僅供研究使用,不用于臨床診斷!) |
SEA518Ga | 鐵蛋白(FE)檢測試劑盒(酶聯(lián)免疫吸附試驗法) | Enzyme-linked immunosorbent assay for Antigen Detection. |
LMA518Ga | 鐵蛋白(FE)等多因子檢測試劑盒(流式熒光發(fā)光法) | FLIA Kit for Antigen Detection. |
參考文獻
雜志 | 參考文獻 |
Molecular Endocrinology | PGC-1α regulates hepatic hepcidin expression and iron homeostasis in response to inflammation. [Pubmed: 23438894] |
experimental oncology | Redox-regulation of gelatinases during growth of cisplatin-sensitive and resistant Guerin carcinoma. [PubMed: 25804229] |
J Cancer Sci Ther | Host H68D Genotype Affects Tumor Growth in Mouse Melanoma [Open-Access: 1948-5956-1000353] |
Food Funct | The effects of polysaccharides from the root of Angelica sinensis on tumor growth and iron metabolism in H22-bearing mice [Pubmed:26757699] |
Physiological research | The Labile Iron Pool in Monocytes Reflects the Activity of the Atherosclerotic Process in Men with Chronic Cardiovascular Disease [pubmed:27782743] |
Expert?Review?of Hematology | 4 (th) Mediterranean Multidisciplinary Course on Iron Anemia April 29 (th)-30 (th) 2016, Madrid, Spain. [pubmed:27615544] |
Oxidative Medicine and Cellular Longevity | Acidic Polysaccharide from Angelica sinensis Reverses Anemia of Chronic Disease Involving the Suppression of Inflammatory Hepcidin and NF-κB Activation [pubmed:29147463] |
European Journal of Pharmaceutical Sciences | sucrosomial? iron absorption studied by in vitro and ex-vivo models [pubmed:29055735] |
Journal of Food Science and Technology | In vitro assessment of bio-augmented minerals from peanut oil cakes fermented by Aspergillus oryzae through Caco-2 cells. [pubmed:29051659] |
International Journal of Cuban Health & Medicine | Anemia and Iron Deficiency Related to Inflammation, Helicobacter pylori Infection and Adiposity in Reproductive-age Cuban Women [10.1590/MEDICC.2017.1902030004?] |
Oman Medical Journal | The Role of Insulin Therapy in Correcting Hepcidin Levels in Patients with Type 2 Diabetes Mellitus. [pubmed:28584599] |
Food Bioscience | Preparation of lactose-iron complex and its cyto-toxicity, in-vitro digestion and bioaccessibility in Caco-2 cell model system [10.1016/j.fbio.2017.10.001] |
Nutrients. | Long-Term Dexamethasone Exposure Down-Regulates Hepatic TFR1 and Reduces Liver Iron Concentration in Rats [pubmed:28629118] |
Food?Chemistry | Physicochemical characterization of mineral (iron/zinc) bound caseinate and their mineral uptake in Caco-2 cells [Pubmed:29622185] |
Animal Feed Science and Technology | Super-dosing phytase improves the growth performance of weaner pigs fed a low iron diet [10.1016:j.anifeedsci.2018.01.012] |
American Journal of Hematology | Iron homeostasis in pregnancy and spontaneous abortion [Pubmed: 30394565] |
The Nigerian postgraduate medical journal the official publication of the National Postgraduate Medical College of Nigeria | Assessment of iron deficiency anaemia and its risk factors among adults with chronic kidney disease in a tertiary hospital in Nigeria [] |
Haematologica | New thiazolidinones reduce iron overload in mouse models of hereditary hemochromatosis and β-thalassemia [Pubmed: 30792208] |
博士論文 | PHYSIOLOGICAL ADAPTATIONS TO HEAT ACCLIMATION; REPERCUSSIONS ON CYCLING PERFORMANCE [] |
Synthesis, characterization and cellular mineral absorption of nanoemulsions of Rhododendron arboreum flower extracts stabilized with gum arabic [] | |
Cell Research | Transferrin plays a central role in coagulation balance by interacting with clotting factors [Pubmed: 31811276] |
international journal of biological macromolecules | Gum arabic capped copper nanoparticles: Synthesis, characterization, and applications [Pubmed: 31904465] |
journal of the american college of nutrition | Improvement of Mineral Absorption and Nutritional Properties of Citrullus vulgaris Seeds Using Solid-State Fermentation [Pubmed: 32255407] |
LWT-FOOD SCIENCE AND TECHNOLOGY | Whey protein-iron or zinc complexation decreases pro-oxidant activity of iron and increases iron and zinc bioavailability [] |
J Mol Cell Cardiol | Systemic iron deficiency does not affect the cardiac iron content and progression of heart failure [34139233] |
European Journal of Pharmacology | The mechanism of the imbalance between proliferation and ferroptosis in pulmonary artery smooth muscle cells based on the activation of SLC7A11 [Pubmed:35700835] |