Calcium detection

The indicator used in the titration is zincon (Section 10.48) which gives rise to an indirect end point with calcium. Detection of the end point is dependent upon the reaction... 

The sensor reported by Shirai(69) used a natural carboxylic polyether antibiotic (Aem = 481 nm) for the detection of magnesium and calcium. Detection limits of I0 5 and KT4 M, respectively, were reported but, interference from other metals was difficult to overcome. Ishibashi(69) used a bulkier hexadecyl-acridine orange dye (Xem = 525 nm) plasticized in a PVC membrane for the fluorescent detection of ammonium ions. Signal interference due to superfluous ions and poor detection limits of KT5 M restricted the use of the probe. 

Malcik N, Ferrance JP, Caglar P, Landers JP. Development of a microchip sensor for calcium detection in biological fluids. In preparation. 

Breen JF, Schwartz RS, et al. Quantity of coronary artery calcium detected by electron beam computed tomography in asymptomatic subjects and angio-... 

Paraffin sections were hematoxylin and eosin (HE)-stained and selected sections were stained according to Von Kossa reaction for calcium detection and were evaluated under light microscopy. For electron microscopy, semi-thin sections were toluidine blue-stained and ultra-thin sections were uranyl acetate and lead citrate-contrasted for ultrastmctural examination (Jeol 1200 EX electron microscope at 80KV). 

Place 45 g. (43 ml.) of benzal chloride (Section IV,22), 250 ml. of water and 75 g. of precipitated calcium carbonate (1) in a 500 ml. round-bottomed flask fltted with a reflux condenser, and heat the mixture for 4 hours in an oil bath maintained at 130°. It is advantageous to pass a current of carbon dioxide through the apparatus. Filter off the calcium salts, and distil the filtrate in steam (Fig. II, 40, 1) until no more oil passes over (2). Separate the benzaldehyde from the steam distillate by two extractions with small volumes of ether, distil off most of the ether on a water bath, and transfer the residual benzaldehyde to a wide-mouthed bottle or flask. Add excess of a concentrated solution of sodium bisulphite in portions with stirring or shaking stopper the vessel and shake vigorously until the odour of benzaldehyde can no longer be detected. Filter the paste of the benzaldehyde bisulphite compound at the pump... 

Direct Metal Analyses. Calcium ion can be detected to a lower limit of 10 M hy Aequorea bioluminescence. Strontium interferes to a minor extent (270,271). 

A significant advantage of the PLM is in the differentiation and recognition of various forms of the same chemical substance polymorphic forms, eg, brookite, mtile, and anatase, three forms of titanium dioxide calcite, aragonite and vaterite, all forms of calcium carbonate Eorms I, II, III, and IV of HMX (a high explosive), etc. This is an important appHcation because most elements and compounds possess different crystal forms with very different physical properties. PLM is the only instmment mandated by the U.S. Environmental Protection Agency (EPA) for the detection and identification of the six forms of asbestos (qv) and other fibers in bulk samples. 

Magnesium, calcium, barium, and strontium can also be deterrnined by ion chromatography with y -phenylenediamine in perchloric acid as the eluent. Ion chromatography by conductimetric detection has been described, and appHcations to environmental waters have been discussed (1,22—23). 

Analytical applications of pyrazolones have been reviewed by Busev et al. (65RCR237). Organic bases are easily characterized by formation of highly crystalline salts with picrolonic acid (l-(4-nitrophenyl-3-methyl-4-nitro-5-hydroxypyrazole). The last-named compound is used as a reagent for alkaloids, tryptophan, phenylalanine and for the detection and estimation of calcium (B-76MI40404). 

Calcium carbonate makes up the largest amount of deposit in many cooling water systems (Fig. 4.16) and can be easily detected by effervescence when exposed to acid. Deposits are usually heavily stratified, reflecting changes in water chemistry, heat transfer, and flow. Corrosion may be slight beneath heavy accumulations of fairly pure calcium carbonate, as such layers can inhibit some forms of corrosion. When nearly pure, calcium carbonate is white. However, calcium carbonates are often intermixed with silt, metal oxides, and precipitates, leading to severe underdeposit attack. 

Calcium hexacyanoferrate (II) (IIH2O) [ 13821 -08-4] M 490.3. Recrystd three times from conductivity H2O and air dried to constant weight over partially dehydrated salt. [Trans Faraday Soc 45 855 1949.] Alternatively the Ca salt can be purified by pptn with absolute EtOH in the cold (to avoid oxidation) from an air-free saturated aqueous soln. The pure lemon yellow crystals are centrifuged, dried in a vacuum desiccator first over dry charcoal for 24h, then over partly dehydrated salt and stored in a dark glass stoppered bottle. No deterioration occurred after 18 months. No trace of Na, K or NH4 ions could be detected in the salt from the residue after decomposition of the salt with cone H2SO4. Analyses indicate 1 Imols of H2O per mol of salt. The solubility in H2O is 36.45g (24.9 ) and 64.7g (44.7 ) per lOOg of solution. [J Chem Soc 50 1926.]... 

H. Fujimoto, I. Nishino, K. Ueno and T. Umeda, Determination of the enantiomers of a new 1,4-dihydropyridine calcium antagonist in dog plasma achiral / chiral coupled high performance liquid cliromatography with electrochemical detection , 7. Pharm. Sci. 82 319-322(1993). 

Some other procedures for CaCl and NaCl content determination are used by mud service companies. Although probably more accurate, all of them are based on calcium filtration for CaCl detection and on chlorides filtration for NaCl detection. 

In the many reports on photoelectron spectroscopy, studies on the interface formation between PPVs and metals, focus mainly on the two most commonly used top electrode metals in polymer light emitting device structures, namely aluminum [55-62] and calcium [62-67]. Other metals studied include chromium [55, 68], gold [69], nickel [69], sodium [70, 71], and rubidium [72], For the cases of nickel, gold, and chromium deposited on top of the polymer surfaces, interactions with the polymers are reported [55, 68]. In the case of the interface between PPV on top of metallic chromium, however, no interaction with the polymer was detected [55]. The results concerning the interaction between chromium and PPV indicates two different effects, namely the polymer-on-metal versus the metal-on-polymer interface formation. Next, the PPV interface formation with aluminum and calcium will be discussed in more detail. 

Coelenterazine and the corresponding luciferase can be easily tested in the field. A small piece of tissue sample is put in a test tube with methanol (for coelenterazine) or water (for luciferase), and crushed with a spatula. To measure coelenterazine, a buffer solution containing a coelenterazine luciferase is injected into a small amount of the fluid part of the crushed sample mixture. Similarly, luciferase can be measured with a buffer solution containing coelenterazine. The presence of Cypridina luciferin can be tested in the same fashion, with the methanol extract of samples and crude Cypridina luciferase. However, the detection of a very weak Cypridina luciferase activity in the field is not recommended (see Section C5.6). To test the presence of a Ca2+-sensitive photoprotein, crush a sample in a neutral buffer solution containing 20-50 mM EDTA, and then add lOmM calcium acetate to a small portion of the fluid part of the crushed sample to detect any light emission. 

Shimomura, O., and Johnson, F. H. (1979a). Chemistry of the calcium-sensitive photoprotein aequorin. In Ashley, C. C., and Campbell, A. K. (eds.), Detection and Measurement of Free Calcium Ions in Cells, pp. 73-83. Elsevier/North-Holland, Amsterdam. 

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