Morteza Janghorbani

Inductively coupled plasma mass spectrometry for stable isotope tracer investigations

Inductively coupled plasma mass spectrometry (ICP-MS) has now been developed for application to stable isotope tracer investigations of several minerals/trace elements. Use of this method for such purposes requires an understanding of a number of fundamental issues: analytical chemistry performance of the method of isotopic analysis, relationship of the level of enriched isotope administered to the subject with background level of the isotope already present, the issues of cost, and finally the specific details of the biological issues to be explored.In this paper, a brief discussion of these issues is presented. As an example, the discussion is presented in relation to selected aspects of metabolism of selenium, employing the three stable isotopes74Se,77Se, and82Se in the rat as the biological model.Analytical performance of hydride generation/ICP-MS is discussed for the required analyses of selenium isotopes. It is shown that for solutions containing 10 ng/ml Se of natural isotopic composition, optimized signal/background ratios greater than 40/1 can be obtained, resulting in worst-case detection limits (ng Se) of 2 (74Se), and 0.6 (77,82Se). The precision and accuracy of isotope ratio measurements for the method used routinely in biological studies is ∼ 1%. The accuracy of the method for quantitative isotopic analysis is compared with hydride generation/atomic absorption spectrophotometry (HG/AAS). The following results are given (μg Se/g or ml; mean + 1 SD,n = 3–5; first HG/ICP-MS, second HG/AAS): SRM 1577a [bovine liver] 0.697 ± 0.002 versus 0.69 ± 0.01; human blood plasma 0.098 ± 0.001 versus 0.135 ± 0.008; human red cells 0.211 ± 0.002 versus 0.216 ± 0.012; and human urine 0.0473 ± 0.0003 versus 0.0489 ± 0.0003.An experiment is described with the rat to show the feasibility of the method for studies of selenium metabolism. Rats were placed on Se-free diet for eight weeks, given their Se requirements in the drinking water in the form of76SeO32− and a single-day (day 3) replacement of their water with that containing highly enriched74SeO32−. Isotopic analysis of carcass and selected organs revealed a high degree of isotopic enrichment with respect to74Se during the entire eight weeks of the experiment, indicating the feasibility of this approach for detailed investigations of selenium metabolism in the rat.

Development of the stable isotope tracer approach for studies of copper turnover in the rat and mouse.

The stable isotope tracer approach was explored for long-term investigations of copper turnover in the adult rat and mouse, with inductively coupled plasma mass spectrometry for isotope measurements. The isotopic measurement method permitted precision and accuracy of <1.0%, with an overall sample blank of <0.05 microg copper. Rats were fed a copper-deficient diet and deionized water with (+Cu) or without (-Cu) copper (20 microg/ml). Both groups underwent a single-day replacement of drinking water with 20 microg/ml of (65)Cu. Compared with the baseline isotope ratio ((65)Cu/(63)Cu) of 0.462 +/- 0.002, blood plasma ratios for the +Cu group on days 2, 7, and 14 postdosing were 0.702 +/- 0.021, 0.557 +/- 0.004, and 0.474 +/- 0.001, respectively. The corresponding data for liver were 1.652 +/- 0.018, 0.560 +/- 0.005, and 0.482 +/- 0.001, respectively. For the -Cu group, respective plasma ratios were 1.580 +/- 0.04. 0.917 +/- 0.02, and 0.664 +/- 0.01 for days 2, 7, and 14 postdosing, and the ratios for liver were 0.987 +/- 0.02, 0.876 +/- 0.04, and 0.739 +/- 0.03. Mice previously made copper deficient to varying degrees were given a single-day replacement with the label. When the 24-hour postdosing isotope ratios in the livers of these mice were correlated with the activity of plasma ceruloplasmin, a negative correlation (r = -0.85) was observed. Isotope enrichment in both rats and mice was greater in the copper-deficient animals compared with the controls.

Intra-individual variability of CO2 breath isotope enrichment compared to blood glucose in the oral glucose tolerance test

BACKGROUND Glucose tolerance can be assessed noninvasively using (13)C-labeled glucose added to a standard oral glucose load, by measuring isotope-enriched CO(2) in exhaled air. In addition to the clear advantage of the noninvasive measurements, this approach may be of value in overcoming the high variability in blood glucose determination. METHODS We compared within-individual variability of breath CO(2) isotope enrichment with that for blood glucose in a 75-g oral glucose tolerance test (OGTT) by adding 150 mg of d-[(13)C]glucose ((13)C 99%) to a standard 75-g glucose load. Measurements of whole blood glucose (by glucose oxidase) and breath isotope enrichment (by isotope ratio mass spectrometry) were made every 30  min for 3 h. Subjects underwent three repeat tests over a 3-week period. Values for variability of breath isotope enrichment at 3 h (∂‰180) and of area under the curve for enrichment to 180  min (AUC180) were compared with variability of the 2-h OGTT blood glucose. RESULTS Breath test-derived measures exhibited lower within-subject variability than the 2-h OGTT glucose. The coefficient of variation for ∂‰180 was 7.4 ± 3.9% (mean ± SD), for AUC180 was 9.4 ± 6.3%, and for 2-h OGTT blood glucose was 13 ± 7.1% (P = 0.005 comparing ∂‰180 versus 2-h blood glucose; P = 0.061 comparing AUC180 versus 2-h blood glucose; P = 0.03 comparing ∂‰180 versus AUC180). CONCLUSIONS Breath test-derived measurements of glucose handling had lower within-subject variability versus the standard 2-h blood glucose reading used in clinical practice. These findings support further development of this noninvasive method for evaluating glucose tolerance.

Feasibility of measuring organ magnesium turnover in vivo by continuous feeding of a stable isotope

Abstract The feasibility of measuring organ endogenous magnesium (Mg en ) turnover in vivo by continuous feeding of a single stable isotope of Mg was demonstrated in this investigation. Adult CD-1 mice were fed a Mg deficient diet and deionized water with (+Mg) or without (−Mg) added 24 Mg (290 μg/mL) for 16 days. The change in organ 25 Mg content over time was then accurately determined by in vitro isotope dilution with 26 Mg as spike. Organ endogenous Mg content was then calculated as 25 Mg en / 0.1028 and exogenous Mg (Mg ex ) content from the expression Mg ex = Mg total - Mg en . All soft tissues examined in the +Mg group showed significant turnover of Mg en and accumulation of Mg ex . The rate at which this occurred was organ specific. Apparent half-lives for Mg en turnover were 3.83, 4.13, 5.87, and 8.77 days for liver, heart, brain, and skeletal muscle, respectively. Mg restriction resulted in a dramatic decrease in the rate of Mg en turnover with apparent half-lives ranging from 60.3 to 146 days. Brain showed the smallest decrease in Mg en turnover with Mg restriction, and was the only tissue observed to lose a significant amount of total Mg.

Effect of Mg nutriture on the dynamics of administered 25Mg exchange in vivo in the rat.

The effect of Mg nutriture on Mg exchange and interorgan distribution was studied in adult rats ten days after a single I.P. dose of (25)Mg ( approximately 5 mg). First the effects of level of Mg intake (0.25, 0.05, or 0.01% Mg) on standard measures of Mg nutriture were studied for 62d to fully document the Mg status of the adult rats. The Mg-deficient diet led to a reduction in plasma, erythrocyte and urine Mg concentration but the only tissues affected were kidney and bone; no outward signs of deficiency were observed. At this point, the 4 remaining rats from each diet group received a single dose of (25)Mg and were killed 10d later. Unlike measures of total Mg content, Mg restriction was observed to significantly alter the distribution of isotope within the soft tissue compartment. The proportion of retained isotope accumulated by soft tissues other than skeletal muscle increased. Because this was not true for skeletal muscle, exogenous (25)Mg label was diverted to more metabolically active tissues during Mg restriction. The apparent Mg exchangeable pool (MgEP) size, determined by in vivo stable isotope dilution, reflected this difference in skeletal muscle (25)Mg accumulation; MgEP size was 39% lower in Mg restricted (0.01% Mg) compared to control (0.05% Mg) rats. The pool of exchangeable Mg in bone was also reduced by Mg restriction but, unlike the soft tissue compartment, the reduction in bone exchangeable Mg was quantitatively similar to the reduction in total Mg content.

Effect of acute selenium restriction on whole body endogenous selenium and the selenite-exchangeable metabolic pool in the adult rat

The time course of changes in whole body endogenous selenium (Se(end)) was investigated during a short-term (7-day) selenium restriction study in the adult rat. The method of continuous feeding with a stable isotope of selenium was used to permit normal intake of selenium while distinguishing between the dietary and endogenous components of body selenium. Additionally, the effect of short-term selenium restriction on the time course of the selenite-exchangeable metabolic pool (Se-EMP) was investigated. Two groups of adult male rats were intubated with the in vivo stable isotope (74)SeO(3)(2-), then fed a Torula yeast diet (selenium <0.02 microg/g) and either deionized water (-Se group) or deionized water containing selenium as (76)SeO(3)(2-) (0.1 microg selenium/ml) (+Se group). Three animals from each group were killed at 24-hour intervals. Whole body Se(end) and the estimated size of Se-EMP (W(Se-EMP)) were determined using hydride generation-inductively coupled plasma mass spectrometry for isotopic measurements. Whole body Se(end) decreased linearly in the +Se group (Se degrees (end): 54.4 microg; Se(end) at 3 days: 49.3 +/- 2.1; Se(end) at 7 days: 45.2 +/- 2.2). The decrease was exponential for the -Se group (Se degrees (end): 54.4 microg; Se(end) at 3 days: 42.9 +/- 0.3; Se(end) at 7 days: 42.2 +/- 0.7). The value of W(Se-EMP,pl) (microg) was 19.8 +/- 0.6 at 1 day and 19.7 +/- 1.0 at 7 days for the +Se group. The corresponding values for the -Se group were 15.7 +/- 1.5 and 18.8 +/- 0.4. All respective values of W(Se-EMP,pl) for the -Se group were significantly smaller than for the +Se group (P < 0.05), with the exception of values at days 6 and 7. The value of W(Se-EMP,urine) (microg) was 2.1 +/- 0.2 at 1 day, increasing rapidly to 23.5 +/- 1.5 at 7 days for the +Se group. The corresponding values for the -Se group were 3.0 and 23.1.

Failure of hyperglycemia and hyperinsulinemia to compensate for impaired metabolic response to an oral glucose load

OBJECTIVE To evaluate whether the augmented insulin and glucose response to a glucose challenge is sufficient to compensate for defects in glucose utilization in obesity and type 2 diabetes, using a breath test measurement of integrated glucose metabolism. METHODS Non-obese, obese normoglycemic and obese type 2 diabetic subjects were studied on 2 consecutive days. A 75g oral glucose load spiked with ¹³C-glucose was administered, measuring exhaled breath ¹³CO₂ as an integrated measure of glucose metabolism and oxidation. A hyperinsulinemic euglycemic clamp was performed, measuring whole body glucose disposal rate. Body composition was measured by DEXA. Multivariable analyses were performed to evaluate the determinants of the breath ¹³CO₂. RESULTS Breath ¹³CO₂ was reduced in obese and type 2 diabetic subjects despite hyperglycemia and hyperinsulinemia. The primary determinants of breath response were lean mass, fat mass, fasting FFA concentrations, and OGTT glucose excursion. Multiple approaches to analysis showed that hyperglycemia and hyperinsulinemia were not sufficient to compensate for the defect in glucose metabolism in obesity and diabetes. CONCLUSIONS Augmented insulin and glucose responses during an OGTT are not sufficient to overcome the underlying defects in glucose metabolism in obesity and diabetes.