Advanced search
Publication Cover
CRC Critical Reviews in Clinical Laboratory Sciences Volume 7, 1977 - Issue 4
Journal homepage
11
Views
6
CrossRef citations to date
0
Altmetric
Research Article

X-Ray Fluorescence Applications to Clinical Studies

Donald E. Leyden Department of Chemistry, University of Denver, Denver, Colorado
&
William K. Nonidez Department of Chemistry, West Georgia College, Carrollton, Georgia
Pages 393-422 | Published online: 27 Sep 2008

References

  • Jenkins R. An Introduction to X-ray Spectrometry. Heyden and Son, London 1974
  • Woldseth R. X-ray Energy Spectrometry. Kevex, Burlingame, Calif. 1973
  • Bertin E. P. Principles and Practices of X-ray Spectrometric Analysis, 2nd ed. Plenum Press, New York 1975
  • X-ray and electron probe analysis in biomedical research. Progress in Analytical Chemistry, K. M. Earle, A. J. Tousimis. Plenum Press, New York 1969; Vol. 3
  • Kaufman L., Nelson J., Price D., Shames D., Wilson C. J. Some applications of Si(Li) detectors to clinical problems. IEEE Trans, Nucl. Sci 1973; 20: 402
  • Valkovie V. X-ray emission spectroscopy. II. Contempt. Phys. 1973; 14: 439
  • Woldseth R. X-ray energy spectrometry; new applications in industry and medicine. Am. Lab. 1975; 7(11)82
  • Natelson S. Anal. Chem 1959; 31: 17A
  • Birks L. S., Brooks E. J., Seal R. T. Determination of Hemoglobin Content of Blood by X-ray Fluorescence. Naval Research Laboratory Report 3867, Naval Research Laboratory, Washington, D.C. 1951
  • Lund P. K., Mathies J. C. X-ray spectroscopy in biology and medicine. I. Total iron (hemoglobin) content in human whole blood. Norelco Rep. 1960; 7: 127
  • Cesareo R., Del D. Analysis of iron in blood using radioisotopic excited X-ray fluorescence. Med. Phys. 1974; 1: 163, Principe
  • Lund P. K., Mathies J. C. II. Calcium content of human blood serum. Norelco Rep. 1960; 7: 130
  • Natelson S., Rickelson M. R., Sheid B., Bender S. L. X-ray spectroscopy in the clinical laboratory. I. Calcium and potassium. Clin. Chem. (N.Y.) 1959; 5: 519
  • Mertl F. Determination of microamounts of calcium by means of X-ray fluorescence analysis. Chem. Listy. 1972; 66: 1099
  • Chem. Abstr. 1973; 78: 66598
  • Lund P. K., Mathies J. C. III. Bromide (total bromine) in human blood, serum, urine, and tissue. Norelco Rep. 1960; 7: 134
  • Beyermann K. Die Röntigenfluorimetrische und Abtivierungsanalytische Brombestimmung in Biologischem Material. Z. Anal. Chem. 1961; 183: 199
  • Natelson S., Sheid B., Leighton B. R. X-ray spectrometry in the clinical laboratory. VII. Bromide Normally Present in Human Serum. Clin. Chem. (N.Y.) 1962; 8: 630
  • Boiteau H. L., Gelot S., Robin M. Analysis of the bromine in blood and urine by X-ray fluorescence spectrometry: application to the diagnosis of bromism. Ann. Biol. Clin. (Paris) 1971; 29: 163
  • Chem. Abstr. 1971; 53: 11410
  • Natelson S., Sheid B. X-ray spectroscopy in the clinical laboratory. II. Chlorine and sulfur: automatic analysis of ultramicro samples. Clin. Chem. (N.Y.) 1960; 6: 299
  • Natelson S., Bender S. L. X-ray fluorescence (spectroscopy) as a tool for the analysis of submicrogram quantities of the elements in biological systems. Microchem J. 1959; 3: 19
  • Natelson S. Microanalysis in the modern analytical laboratory of clinical chemistry. Anal. Chem. 1959; 31: 17A
  • Natelson S., Sheid B. X-ray spectrometric determination of strontium in human serum and bone. Anal. Chem. 1961; 33: 396
  • Natelson S., Sheid B. X-ray spectroscopy in the clinical laboratory. IV. Phosphorus: total blood iron as a measure of hemoglobin content. Clin. Chem. (N.Y.) 1961; 7: 115
  • Natelson S., Leighton D. R., Calas C. Assay for the elements chromium, manganese, iron, cobalt, copper, and zinc simultaneously in human serum and sea water by X-ray spectrometry. Microchem J. 1962; 6: 539
  • Natelson S., De P. K. Application of X-ray emission spectrometry to the estimation of heavy elements (at. n. 79–83). Microchem. J. 1963; 7: 448
  • Lauer G. R. X-ray fluorescent analyzer of biological samples. Chem. Abstr. 1975; 82: 28203k
  • Natelson S., Vassilevsky A. N., De P. K., Whitford W. R. Microestimation of sodium, magnesium and barium with the X-ray spectrometer. Microchem J. 1964; 8: 295
  • Susbielle H., Forestier R., Gaudin-Harding F. Utilisation de la fluorescence X pour le dosage du soufre total: application au materiel d'origine anamale. Bull. Soc. Chim Biol. 1969; 51: 187
  • Moss A. A., Kaufman L., Nelson J. A. Fluorescent excitation analysis: a simplified method of iodine determination in vitro. Invest. Radiol. 1972; 7: 335
  • Simmons E. L. The internal standard addition method in X-ray fluorescence analysis of biological materials. Anal. Chim Acta 1972; 62: 446
  • Walsh P., Hamrick P., Underwood N. Application of X-ray emission spectrometry to the determination of mercury in biological samples. Rev. Sci. Instrum 1973; 44: 1019
  • Strausz K. I., Purdham J. T., Strausz O. P. X-ray fluorescence spectrometric determination of selenium in biological materials. Anal. Chem. 1975; 47: 2032
  • Purdham J. T., Strausz O. P., Strausz K. I. X-ray fluorescence spectrometric determination of gold, bromine, and iodine in biological fluids. Anal. Chem 1975; 47: 2030
  • Landis D. A., Goulding F. S., Jarrett B. V. Some aspects of X-ray fluorescence spectrometers for trace analysis. Nucl. Instrum Methods 1972; 101: 127
  • Vaasjoki R., Rantanen J. Determination of toxic metals in blood by X-ray fluorescence spectrometry. Scand. J. Work Environ. Health 1975; 1: 184
  • Ong P. S., Lund P. K., Litton C. E., Mitchel B. A. An energy dispersive system for the analysis of trace elements in human blood serum. Advances in X-ray Analysis, L. S. Birks, C. S. Barrett, J. B. Newkirk, C. O. Ruud. Plenum Press, New York 1973; Vol. 16: 124
  • Cesarao R., Tallarada G., Baldoni F. Determination of hemodynamic parameters in the rabbit by X-ray fluorescence excitation. Int. J. Appl. Radiat. Isot. 1975; 26: 285
  • De Young L. G. Trace Analysis of Heavy Elements by X-ray Energy Spectroscopy. Masters thesis, Air Force Institute of Technology, Ohio School of Engineering 1974
  • Beyermann K., Rose H. J., Christian R. P. The determination of nanogram amounts of chromium in urine by X-ray fluorescence spectroscopy. Anal. Chim Acta 1969; 45: 51
  • Moss A. A., Amberg J. R., Jones R. S. The relationship of bile salts and bile flow to the bilary excretion of iopanoic acid. Invest. Radiol. 1972; 7: 11
  • Nelson J. A., Pepper H. W., Goldberg H. I., Moss A. A., Amberg J. R. Effect of phenobarbitol on iodipamid and iopanoate bile excretion. Invest. Radiol. 1973; 3: 127
  • Argarwal M., Bennett R. B., Stump I. G., D'Auria J. M. Analysis of urine for trace elements by energy dispersive X-ray fluorescence spectrometry with a pre-concentrating chelating resin. Anal. Chem. 1975; 47: 925
  • Höglund G. Determination of strontium in bone by X-ray, fluorescence spectroscopy. Exp. Cell Res. 1959; 14: 565
  • Roberts W. M. B. Estimation of strontium in animal bone using X-ray fluorescence analysis. Nature (London) 1959; 18: 887
  • Goldman M., Anderson R. P. X-ray fluorescence determination of strontium in biological materials by direct matrix-transmittance correction. Anal. Chem 1965; 36: 718
  • Bogatov V. N., Denisov-Nikol'skii Y. U. I. Use of X-ray spectral microanalysis to study mineralized tissues. Vopr. Med Khim. 1975; 21: 107
  • Chem Abstr. 1975; 82: 66932
  • Lund P. K., Mathies J. C. X-ray spectroscopy in biology and medicine. VII. Ultra-micro determination of potassium in human tissue and blood serum. Am. J. Clin Pathol 1965; 44: 398
  • Alexander G. V. Determination of zinc, copper, and iron in biological tissues – an X-ray fluorescence method. Anal Chem 1962; 34: 951
  • Kissel P., Schmitt J., Duprez A. Detection of tissue copper content by X-ray spectrography: advantage for the systematic detection of the Wilson Defect. J. Genet. Hum. 1969; 17: 413
  • Chem. Abstr. 1970; 52: 61626
  • Alexander G. V. An X-ray fluorescence method for the determination of calcium, potassium, chlorine, sulfur, and phosphorus in biological tissues. Anal Chem 1965; 37: 1671
  • Zeitz L., Lee R. Zinc analysis in biological specimens by X-ray fluorescence. Anal Biochem. 1966; 14: 191
  • Boiteau H. L., Bliaux M. F. Quelques applications de la fluorescence X en toxicologie. J. Eur. Toxicol 1969; 2: 300
  • Evans C. C. X-ray fluorescence analysis for light elements and plant in faecal materials. Analyst 1970; 95: 919
  • Lubozynski M. F., Baglan R. J., Dyer G. R., Brill A. B. Sensitivity of X-ray fluorescence for trace element determinations in biological tissues. Int. J. Appl. Radiat. Isot. 1972; 23: 497
  • Zeimer R., Weinrib A., Loewinger E., Kalman Z. H., Belkin M. Detection and analysis of metals in the eye by X-ray spectrometry. Med. Phys. 1974; 1: 251
  • Alfery A. C., Nunnelley L. L., Rudolph H., Smythe W. R. Medical applications of a small sample X-ray fluorescence system. Advances in X-ray Analysis, R. W. Gould, C. S. Barrett, J. B. Newkirk, C. O. Ruud. Plenum Press, New York 1975; Vol. 19: 497
  • Quinton P. M. Energy dispersive X-ray analysis of picoliter samples of physiological fluids. Proc. Annu Meet. Electron Microsc. Soc. Am 1975; 33: 248
  • Nicholson A. P., Hall T. A. X-ray fluorescence microanalysis of thin biological specimens. J. Phys. E 1973; 6: 781
  • Natelson S., Sheid B. X-ray spectroscopy in the clinical laboratory. VI. Acid-labile probine-bound iodine. Clin Chem. (N.Y.) 1962; 8: 17
  • Zeitz L., Lee R. Bromine analysis in labeled DNA by X-ray fluorescence. Anal Biochem. 1968; 23: 442
  • Zeitz L., Lee R. Bromine analysis in 5-bromouracil-labeled DNA by X-ray fluorescence. Science 1963; 142: 1670
  • Leyden D. E., Carr P. W., Nonidez W. K. Direct determination of total serum phospholipid by X-ray fluorescence. Clin Chem. (N.Y.) 1974; 20: 127
  • Fish C, SubbaRow Y. The colorimetric determination of phosphorus. J. Biol Chem. 1925; 66: 375
  • Johansson T. B., Akselsson R., Johansson S. A. E. X-ray analysis: elemental trace analysis at the 10-1 2 g level. Nucl Instrum Methods 1970; 84: 141
  • Cooper J. A. Comparison of particle and photon excited X-ray fluorescence applied to trace element measurements of environmental samples. Nucl. Instrum. Methods 1973; 106: 525
  • Campbell J. L., Herman A. W., McNelles L. A., Orr B. N., Willoughby R. A. Some biomedical applications of charged-particle-induced X-ray fluorescence analysis. Advances in X-ray Analysis, C. L. Grant, C. S. Barrett, J. B. Newkirk, C. O. Ruud. Plenum Press, New York 1973; Vol. 17: 457
  • Young F. C., Roush M. L., Berman P. G. Trace element analysis by proton-induced X-ray excitation. J. Appl Radiat. Isot. 1973; 24: 153
  • Valkovic V., Liebert R. B., Zabel T., Larson H. T., Miljanic D., Wheeler R. M., Phillips G. C. Trace element analysis using proto-induced X-ray emission spectroscopy. Nucl Instrum Methods 1974; 114: 573
  • Herman A. W., McNelles L. A., Campbell J. L. Target backings for charged particle induced X-ray fluorescence analysis. Nucl. Instrum Methods 1973; 109: 429
  • Siddall G. Proc. European Reg. Conf. Electron Microscopy. DelftHolland 1960; Vol. 1: 584
  • Barnes B. K., Coleman R. M., Kegel G. H. R., Quinn P. W., Rencricca N. J. Charged particle induced X-ray analysis of malaria infected blood. Advances in X-ray Analysis, W. L. Pickles, C. S. Barrett, J. B. Newkirk, C. O. Ruud. Plenum Press, New York 1975; Vol 18: 343
  • Lear R. D., Van Rinsvelt H. A., Adams W. R. An investigation of the correlation between human diseases and trace elements levels by proton-induced X-ray emission analysis. Advances in X-ray Analysis, R. W. Gould, C. S. Barrett, J. B. Newkirk, C. O. Ruud. Plenum Press, New York 1976; Vol. 19: 521
  • Chen J. R. Testimony on the Possible Causative Factors of Legionnaires' Disease. Report to the Sub-Committee on Consumer Protection and Finance of the Committee on Interstate and Foreign Commerce. November 24. U.S. House of Representatives, 1976
  • Chen J. R., Francisco R. B., Miller T. E. Nickel Levels in Lung and Kidney Tissues from Victims of “Legionnaires' Disease” Using Proton-Induced X-ray Emission. Interim Report to the Center for Disease Control, Atlanta 1976, November 22
  • Mangelson N. F., Allison G. E., Christensen J. J., Eatough D. J., Hill M. W., Izatt R. M., Nielson K. K. Rapid Multi-Element Analysis of Biological Samples Using an Energy Dispersive X-ray Fluorescence Method. Int Sym on Trace Element Metabolism in Animals, W. G. Hoekstra. University Park Press, Baltimore 1974; 431
  • Valkovic V., Miljanice D., Wheeler R. M., Liebert R. B., Abel T. Z., Phillips G. C. Variation in trace metal concentrations along single hairs as measured by proton-induced X-ray emission photometry. Nature (London) 1973; 243: 543
  • Johansson T. B., Van Grieken R. E., Nelson J. W., Winchester J. W. Elemental Trace Analysis of Small Samples by Proton-Induced X-ray Emission. Anal Chem 1975; 47: 855
  • Kubo H. Reproducibility of proton induced elemental analysis in biological tissue sections. Nucl Instrum Methods 1974; 121: 541
  • Bearse R. C., Close D. A., Malanify J. J., Umbarger C. J. Elemental analysis of whole blood using proton-induced X-ray emission. Anal Chem 1974; 46: 499
  • Ter-Pogossian M. M., Phelps M. E., Lassen M. In vivo measure of regional cerebral blood flow and volume by means of X-ray fluorescence. Semi-Conductor Detectors in the Future of Nuclear Medicine, P. B. Hoffer, R. N. Beck, A. Bottschalk. Society for Nuclear Medicine, New York 1971; 240
  • Ter-Pogossian M. M., Phelps M. E., Brubb R. I., Jr., Gado M. Measure of regional cerebral blood volume in vivo by means of stimulated X-ray fluorescent X-radiation, and factors affecting this parameter. Eur. Neurol 1971–1972; 6: 218
  • Grubb R. L., Jr., Phelps M. E., Ter-Pogossian M. M. Regional cerebral blood volume in humans. Arch. Neurol. (Chicago) 1973; 28: 38
  • Grubb R. L., Phelps M. E., Raichle M. E., Ter-Pogossian M. M. The effects of arterial blood pressure on the regional cerebral blood volume by X-ray fluorescence. Stroke 1973; 4: 390
  • Phelps M. E., Grubb R. L., Jr., Ter-Pogossian M. M. In vivo regional cerebral blood volume by X-ray fluorescence: validation of method. J. Appl Physiol 1973; 35: 471
  • Phelps M. E., Grubb R. L., Ter-Pogossian M. M. Correlation between PCO2 and regional cerebral blood volume by X-ray fluorescence. J. Appl. Physiol. 1973; 35: 274
  • Kaufman L, Shames D. M., Greenspan R. H., Powell M. R., Perez-Mendez V. Cardiac output determination by X-ray fluorescence determination in the dog. Invest. Radiol 1972; 7: 365
  • Kaufman L., Shames D., Powell M. An absorption correction technique for in vivo iodine quantitation by fluorescent excitation. Invest. Radiol. 1973; 8: 167
  • Hoffer P. B., Gottschalk A. Fluorescent thyroid scanning: scanning without radio isotopes. Radiology 1971; 99: 117
  • Bloch P. X-ray spectrophotometric methods using a silicon lithium drifted detector for determining in vivo the antimony deposits in a lung. Radiology 1970; 94: 200
  • Preuss L. E., Bolin F. P. In vivo analysis of lipid-protein ratios in human muscle by differential X-ray absorption using Cd photons. Advances in X-ray Analysis, L. S. Birks, C. S. Barrett, J. B. Newkirk, C. O. Ruud. Plenum Press, New York 1973; Vol. 16: 3

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.