Monensin improves the effectiveness of meso-dimercaptosuccinate when used to treat lead intoxication in rats.Among divalent divalent /di·va·lent/ (di-va´lent) bivalent; carrying a valence of two. di·va·lent adj. Bivalent. di·va cations, the ionophore ionophore /ion·o·phore/ (i´on-ah-for?) any molecule, as of a drug, that increases the permeability of cell membranes to a specific ion. i·on·o·phore n. monensin monensin used as a growth promotant in ruminants, produced by cultures of Streptomyces cinnamonensis. Not to be used in horses because of its toxicity in this species. Large doses in cattle and normal doses in horses cause sudden death due to heart failure. shows high activity and selectivity selectivity /se·lec·tiv·i·ty/ (se-lek-tiv´i-te) in pharmacology, the degree to which a dose of a drug produces the desired effect in relation to adverse effects. selectivity 1. for the transport of lead ions ([Pb.sup.2+]) across phuspholipid membranes. When coadministered to rats that were receiving meso-dimercaptosuccinate for treatment of Pb intoxication intoxication, condition of body tissue affected by a poisonous substance. Poisonous materials, or toxins, are to be found in heavy metals such as lead and mercury, in drugs, in chemicals such as alcohol and carbon tetrachloride, in gases such as carbon monoxide, and , monensin significantly increased the amount of Pb removed from femur femur (fē`mər): see leg. , brain, and heart. It showed a tendency to increase Pb removal from liver and kidney but had no effect of this type in skeletal muscle. Tissue levels of several physiologic (calcium, cobalt, copper, iron, magnesium, manganese manganese (măng`gənēs, măn`–) [Lat.,=magnet], metallic chemical element; symbol Mn; at. no. 25; at. wt. 54.938; m.p. about 1,244°C;; b.p. about 1,962°C;; sp. gr. 7.2 to 7. , molybdenum molybdenum (məlĭb`dənəm) [Gr.,=leadlike], metallic chemical element; symbol Mo; at. no. 42; at. wt. 95.94; m.p. about 2,617°C;; b.p. about 4,612°C;; sp. gr. 10.22 at 20°C;; valence +2, +3, +4, +5, or +6. , zinc) and nonphysiologic (arsenic arsenic (är`sənĭk), a semimetallic chemical element; symbol As; at. no. 33; at. wt. 74.9216; m.p. 817°C; (at 28 atmospheres pressure); sublimation point 613°C;; sp. gr. (stable form) 5.73; valence −3, 0, +3, or +5. , cadmium cadmium (kăd`mēəm) [from cadmia, Lat. for calamine, with which cadmium is found associated], metallic chemical element; symbol Cd; at. no. 48; at. wt. 112.41; m.p. 321°C;; b.p. 765°C;; sp. gr. 8. , chromium chromium (krō`mēəm) [Gr.,=color], metallic chemical element; symbol Cr; at. no. 24; at. wt. 51.996; m.p. about 1,857°C;; b.p. 2,672°C;; sp. gr. about 7.2 at 20°C;; valence +2, +3, +6. , nickel, strontium strontium (strŏn`shēəm) [from Strontian, a Scottish town], a metallic chemical element; symbol Sr; at. no. 38; at. wt. 87.62; m.p. 769°C;; b.p. 1,384°C;; sp. gr. 2.6 at 20°C;; valence +2. ) elements were also determined after the application of these compounds. Among the physiologic elements, a number of significant changes were seen, including both rising and falling values. The size of these changes was typically around 20% compared with control values, with the largest examples seen in femur. These changes often tended to reverse those of similar size that had occurred during Pb administration. Among the nonphysiologic elements, which were present in trace amounts, the changes were smaller in number but larger in size. None of these changes appears likely to be significant in terms of toxicity, and there were no signs of overt toxicity under any of the conditions employed. Monensin may act by cotransporting [Pb.sup.2+] and OH- ions out of cells, in exchange for external sodium ions. The net effect would be to shuttle intracellular [Pb.sup.2+] to extracellular extracellular /ex·tra·cel·lu·lar/ (-sel´u-lar) outside a cell or cells. ex·tra·cel·lu·lar adj. Located or occurring outside a cell or cells. dimercaptosuccmic acid thereby enhancing its effectiveness. Thus, monensin may be useful for the treatment of Pb intoxication when applied in combination with hydrophilic hydrophilic /hy·dro·phil·ic/ (-fil´ik) readily absorbing moisture; hygroscopic; having strongly polar groups that readily interact with water. hy·dro·phil·ic adj. [Pb.sup.2+] chelators. Key words: chelation therapy Chelation Therapy Definition Chelation therapy is an intravenous treatment designed to bind heavy metals in the body in order to treat heavy metal toxicity. , DMSA DMSA dimercaptosuccinic acid. , heavy metal intoxication, ICP (1) (Internet Cache Protocol) A protocol used by one proxy server to query another for a cached Web page without having to go to the Internet to retrieve it. See CARP and proxy server. mass spectroscopy mass spectroscope n. Any of various devices that use magnetic fields, electric fields, or both to determine the masses of isotopes in a sample by producing a mass spectrum. , ionophores, monensin, Pb, [Pb.sup.2+] transport, trace metal cations. doi:10.1289/ehp.8279 available via http://dx.doi.org/ [Online 29 September 2005] ********** Several polyether pol·y·e·ther n. A polymer in which the repeating unit contains two carbon atoms linked by an oxygen atom. ionophores, including A23187, ionomycin, monensin, and nigericin, have been shown to transport lead ions ([Pb.sup.2+]) across phospholipid phospholipid (fŏs'fōlĭp`ĭd), lipid that in its simplest form is composed of glycerol bonded to two fatty acids and a phosphate group. bilayers and to form stable complexes with [Pb.sup.2+] in homogeneous solution (Erdahl et al. 2000; Hamidinia et al. 2002, 2004). Among this group, the order of transport activity is ionomycin > nigericin > monensin > A23187, whereas the order of selectivity, compared with other divalent cations, is nigericin > monensin > ionomycin > A23187. Ionomycin can be used to load cultured cells and to deplete de·plete v. 1. To use up something, such as a nutrient. 2. To empty something out, as the body of electrolytes. them of [Pb.sup.2+] (Erdahl et al. 2000), and effects of monensin on Pb dynamics in rats have also been investigated (Hamidinia et al. 2002). In the latter area it was found that simultaneous administration of monensin in feed and [Pb.sup.2+] in drinking water drinking water supply of water available to animals for drinking supplied via nipples, in troughs, dams, ponds and larger natural water sources; an insufficient supply leads to dehydration; it can be the source of infection, e.g. leptospirosis, salmonellosis, or of poisoning, e.g. lowers the prevailing concentration of Pb in blood and decreases the accumulation of Pb in several soft tissues and in bone. Feeding monensin after a period of [Pb.sup.2+] administration was furthermore effective at accelerating the clearance of Pb from brain, liver, kidney and bone, with the monensin-related increment To add a number to another number. Incrementing a counter means adding 1 to its current value. being found in feces feces or excrement or stools Solid bodily waste discharged from the colon through the anus during defecation. Normal feces are 75% water. The rest is about 30% dead bacteria, 30% indigestible food matter, 10–20% cholesterol and other fats, , as opposed to the Pb excreted spontaneously, which included a component found in urine (Hamidinia et al. 2002). The actions of monensin on Pb dynamics in rats suggest the possibility of using ionophores in the treatment of human Pb intoxication. At present, the ongoing and widespread problem of Pb intoxication is treated first by removing the individual from the Pb-contaminated environment and thereafter by administering a [Pb.sup.2+] chelating agent chelating agent a substance which combines with a metallic ion to produce an inert chelate, e.g. ethylenediamine tetra-acetic acid, penicillamine. . meso-Dimercaptosuccinic acid (DMSA) is the most commonly used agent at present, in part because it can be administered orally and is well tolerated (Cory-Slechta 1988; Graziano et al. 1985). DMSA is a water-soluble compound that forms a strong complex with [Pb.sup.2+] in blood, which is thereafter secreted via the kidney. EDTA EDTA: see chelating agents. and other chelating agents chelating agents (kē`lātĭng). Certain organic compounds are capable of forming coordinate bonds (see chemical bond) with metals through two or more atoms of the organic compound; such organic compounds are called chelating agents. are used in a similar way to treat Pb intoxication (Goyer et al. 1995; Llobet et al. 1990). In all cases, several cycles of chelator chelator A chemical–eg, EDTA that binds metal ions from solutions. See Chelation therapy. administration given over a period of months are required to produce an adequate and durable reduction of Pb in blood. This is because the blood pool is equilibrated with Pb in other internal compartments, such that a blood pool is reestablished as Pb is mobilized from the other compartments after a cycle of chelator administration (Graziano 1986, 1993; Graziano et al. 1985, 1988). The repetitive treatments and extended time frames are problematic, particularly when treating children, because important aspects of Pb toxicity arise to a greater degree if Pb is present before development is completed. The propensity of Pb to lower IQ (intelligence quotient intelligence quotient n. Abbr. IQ An index of measured intelligence expressed as the ratio of tested mental age to chronological age, multiplied by 100. ) and otherwise interfere with functions of the central nervous system is perhaps the most important of these aspects (Goyer 1993). An uneven effectiveness of water-soluble chelators at removing Pb from particular organs is another problem with existing protocols for the treatment of Pb intoxication, with bone (Castellino and Aloj 1964; Cory-Slechta 1988; Gerhardsson et al. 1999; Smith et al. 2000) and brain (Cremin et al. 1999; Seaton et al. 1999; Smith et al. 1998) being particularly difficult to free of the accumulated cation cation (kăt'ī`ən), atom or group of atoms carrying a positive charge. The charge results because there are more protons than electrons in the cation. . In addition, chelators can provoke an undesirable redistribution of Pb among soft tissues and between bone and soft tissues (Cory-Slechta et al. 1987). Within this context of less than ideal treatments for Pb intoxication and the recent discovery that several carboxylic acid carboxylic acid: see carboxyl group. carboxylic acid Any organic compound with the general chemical formula −COOH in which a carbon (C) atom is bonded to an oxygen (O) atom by a double bond to make a carbonyl group (−C=O; see ionophores transport [Pb.sup.2+] with high specificity, we are seeking to determine if some of these compounds might be used together with the traditional chelators to improve the effectiveness of existing treatment protocols. The present report describes the effectiveness of coadministering monensin and DMSA in this regard, using rats as an experimental model. Materials and Methods Treatment of experimental animals. We used male Sprague-Dawley rats throughout the study. They were treated humanely and with regard to the alleviation of suffering. The rats were housed at the College of Medicine, Ohio State University Ohio State University, main campus at Columbus; land-grant and state supported; coeducational; chartered 1870, opened 1873 as Ohio Agricultural and Mechanical College, renamed 1878. There are also campuses at Lima, Mansfield, Marion, and Newark. , in animal facilities approved by the Association for Accreditation of Laboratory Animal Care. A 12-hr light/dark cycle, dual housing in plastic cages, and conditions of constant temperature and humidity were employed. We allowed 1 week for acclimation acclimation /ac·cli·ma·tion/ (ak?li-ma´shun) the process of becoming accustomed to a new environment. ac·cli·ma·tion n. 1. before the experimental protocol began. During this period rats were fed a standard laboratory chow, whereas the AIN-93M diet containing 0.5% calcium (normal chow; Harlan Teklad, Madison, WI) was employed thereafter. During the administration of [Pb.sup.2+] and/or monensin and DMSA, water and feed were provided ad libitum ad libitum without restraint. ad libitum feeding food available at all times with the quantity and frequency of consumption being the free choice of the animal. , and records of consumption were maintained together with periodic measurements of body weight. Initially the rats weighed 245-255 g. They were divided into five groups of eight, and the administration of [Pb.sup.2+] was begun. It was provided at 100 ppm in the drinking water (0.48 mM) and was in the form of Pb(acetate acetate (ăs`ĭtāt'), one of the most important forms of artificial cellulose-based fibers; the ester of acetic acid. The first patents for the production of fibers from cellulose acetate appeared at the beginning of the 20th cent. )2. The water was rendered slightly acidic acidic /acid·ic/ (ah-sid´ik) of or pertaining to an acid; acid-forming. acidic, adj having the properties of an acid; acid-forming properties. with acetic acid acetic acid (əsē`tĭk), CH3CO2H, colorless liquid that has a characteristic pungent odor, boils at 118°C;, and is miscible with water in all proportions; it is a weak organic carboxylic acid (see carboxyl group). to prevent the precipitation of PbC[O.sub.3] (lead carbonate lead carbonate n. A poisonous white amorphous powder, PbCO3, used as a paint pigment. Noun 1. lead carbonate - a poisonous white pigment that contains lead ceruse, white lead ) (Bogden et al. 1995). As a point of reference, after several days this regimen produces a circulating Pb level of 1.1 [micro]M in rats (22 [micro]g/dL) (Hamidinia et al. 2002), which is higher by about a factor of 2 than the value of 0.5 [micro]M (10 [micro]g/dL), which is often taken to be the toxic threshold for Pb in children. After 3 weeks, one group of rats was sacrificed to determine the Pb content of organs at that time (the Pb-loaded group), whereas the remaining groups thereafter received water that did not contain [Pb.sup.2+]. One of these groups received the normal chow (no-treatment group), another received this chow containing 100 ppm monensin (monensin group), a third group received normal chow and DMSA administered by oral garage (DMSA group), and a final group received the chow containing monensin and DMSA delivered by oral gavage gavage /ga·vage/ (gah-vahzh´) [Fr.] 1. forced feeding, especially through a tube passed into the stomach. 2. superalimentation. ga·vage n. 1. (monensin plus DMSA group). When administered, the 50 mg/kg dose of DMSA was given every other day. The solution volume administered varied between approximately 0.25 and 0.45 mL as body weight increased so as to maintain the prescribed dose. The DMSA solution was freshly prepared by dissolving the compound in 5% NaHC[O.sub.3] (sodium bicarbonate sodium bicarbonate or sodium hydrogen carbonate, chemical compound, NaHCO3, a white crystalline or granular powder, commonly known as bicarbonate of soda or baking soda. It is soluble in water and very slightly soluble in alcohol. ). All treatments were continued for 3 weeks beyond the time when the administration of [Pb.sup.2+] had been discontinued. The rats were then sacrificed by the injection of excess Nembutal (Abbott Laboratories Abbott Laboratories (NYSE: ABT) is a diversified pharmaceuticals and health care company. It has over 65,000 employees and operates in 130 countries. The corporate headquarters are in Abbott Park, Illinois, a neighborhood of North Chicago, Illinois. , North Chicago North Chicago, industrial city (1990 pop. 34,978), Lake co., NE Ill.; inc. 1909. Its economy is closely intertwined with the neighboring city of Waukegan, which has a harbor on Lake Michigan. , IL) and were subsequently perfused briefly with HEPES-buffered 0.9% NaCl, via the left ventricle left ventricle n. The chamber on the left side of the heart that receives the arterial blood from the left atrium and contracts to force it into the aorta. , to remove blood from the organs. After this, organs and tissues of interest were removed and stored at -20[degrees]C. Determination of Pb and other elements by inductively coupled plasma An inductively coupled plasma (ICP) is a type of plasma source in which the energy is supplied by electrical currents which are produced by electromagnetic induction, that is, by time-varying magnetic fields. mass spectroscopy. All aspects of the analytical procedures Analytical Procedures is one of financial audit skill which help an auditor understand the client's business and changes in the business, to identify potential risk areas and to plan other audit procedures. were conducted in laminar flow laminar flow Fluid flow in which the fluid travels smoothly or in regular paths. The velocity, pressure, and other flow properties at each point in the fluid remain constant. hoods within the Microscopic and Chemical Analysis Research Center at Ohio State University. The frozen organs were first thawed thaw v. thawed, thaw·ing, thaws v.intr. 1. To change from a frozen solid to a liquid by gradual warming. 2. and weighed and were then digested in 5.00 mL of trace-metal--grade concentrated nitric acid nitric acid, chemical compound, HNO3, colorless, highly corrosive, poisonous liquid that gives off choking red or yellow fumes in moist air. It is miscible with water in all proportions. . One intact kidney, the entire brain, the entire heart, and the left femur from each animal were analyzed. For liver, a portion of the right lateral lobe lobe (lob) 1. a more or less well-defined portion of an organ or gland. 2. one of the main divisions of a tooth crown. weighing approximately 2 g was analyzed, whereas for muscle it was a similar-sized portion of the left biceps femoris biceps fem·or·is n. A muscle whose long head has origin from the tuberosity of the ischium and whose short head has origin from the lower half of the lateral lip of the linea aspera, with insertion into the head of the fibula, with nerve supply from . Digestion was conducted in acid-cleaned quartz vials that were contained in a Teflon liner that was itself contained in a closed high-pressure vessel (Milestone Inc). The Teflon liners contained 10 mL of a 6% [H.sub.2][O.sub.2] solution, in which the quartz vial vial a small bottle. was partially immersed im·merse tr.v. im·mersed, im·mers·ing, im·mers·es 1. To cover completely in a liquid; submerge. 2. To baptize by submerging in water. 3. , so as to minimize the rise in internal pressure that occurs as digestion proceeds. Samples were heated to 180[degrees]C in a microwave apparatus (Ethos Plus; Milestone Inc., Shelton, CT). Temperature programming provided for a linear rise to that value over a 10-min period, a holding period of 10 min, and a 15-min cool-down period. Sample blanks containing no tissue were generated in the same way, as were occasional tissue samples that were spiked with gallium gallium (găl`ēəm), metallic chemical element; symbol Ga; at. no. 31; at. wt. 69.72; m.p. 29.78°C;; b.p. 2,403°C;; sp. gr. 5.904 at 29.6°C; (solid), 6.095 at 29.8°C; (liquid); valence +2 or +3. (used to estimate overall recovery from the procedure). After digestion, the samples were transferred quantitatively to Nalgene LDPE LDPE abbr. low-density polyethylene Boston round bottles (Fisher Scientific Fisher Scientific, formally Fisher Scientific International, Inc. and colloquially Fisher was a biotechnology company that provided products and services to the global scientific research and United States clinical laboratory markets. , Pittsburgh, PA), diluted to 50.0 mL with NANOpure water (Barnstead/Thermolyne, Dubuque, IA), and then stored at room temperature. Subsequent steps were carried out within 1 month. A cocktail of three internal standards (bismuth bismuth (bĭz`məth) [Ger. Weisse Masse=white mass], metallic chemical element; symbol Bi; at. no. 83; at. wt. 208.9804; m.p. 271.3°C;; b.p. about 1,560°C;; sp. gr. 9.75 at 20°C;; valence +3 or +5. , scandium scandium (skăn`dēəm), metallic chemical element; symbol Sc; at. no. 21; at. wt. 44.9559; m.p. 1,541°C;; b.p. 2,831°C;; sp. gr. 2.99 at 20°C;; valence +3. Scandium is a soft silver-white metal. , and rhodium rhodium (rō`dēəm), metallic chemical element; symbol Rh; at. no. 45; at. wt. 102.9055; m.p. about 1,966°C;; b.p. 3,727±100°C;; sp. gr. 12.41 at 20°C;; valence +2, +3, +4, +5, or +6. ) made from CPI International  This article or section is written like an .Please help [ rewrite this article] from a neutral point of view. Mark blatant advertising for , using . (Santa Rosa Santa Rosa, city, Argentina Santa Rosa, city (1991 pop. 80,629), capital of La Pampa prov., central Argentina. It is a modern city and road junction surrounded by a rich agricultural and cattle-raising area. , CA) peak performance standards was added to each sample (100 [micro]L in 10.0 mL) so as to give a 10 ppb ppb abbr. parts per billion concentration of each standard. The signals arising from these standards were used to correct data for variations in instrument performance that occur while a set of samples is being analyzed. A set of calibration standards, similar in composition to the unknown samples, was prepared for each of the six tissues and used to convert data output from the instrument into units of concentration. These were prepared using SPEX SPEX Special Licensing Examination Medtalk An examination administered to ±1500 physicians/yr who seek relicensure and/or want to practice in a different state yrs after initial licensure Certi Prep (Metuchen, NJ) multielement standards with appropriate adjustments made using single-element standards obtained from CPI International. The samples were analyzed using a Thermo Finnigan magnetic sector inductively coupled plasma (ICP) mass spectrometer spectrometer Device for detecting and analyzing wavelengths of electromagnetic radiation, commonly used for molecular spectroscopy; more broadly, any of various instruments in which an emission (as of electromagnetic radiation or particles) is spread out according to some (Thermo Electron Thermo Electron Corporation (TMO (NYSE)) (incorporated 1956) is a major provider of analytical instruments and services for a variety of domains. Thermo has revenues of over $2 billion, and employs 11,000 people in 30 countries. Corporation, Waltham, MA), which is capable of resolutions > 0.005 atomic mass units atomic mass unit or amu, in chemistry and physics, unit defined as exactly 1-12 the mass of an atom of carbon-12, the isotope of carbon with six protons and six neutrons in its nucleus. One amu is equal to approximately 1. . The data were expressed first in units of parts per billion and were subsequently converted to units of nanomoles per gram wet weight of tissue. Replicate analysis of single samples showed that deviation arising from analysis per se was on the order of [+ or -] 2%, whereas overall recovery of unknowns was approximately 98-101%. Values obtained from sample blanks and standard solution samples that had been carried through the entire procedure showed that potential errors arising from contamination in reagents, leaching/ absorption of materials from labware, and so on, could be ignored for most elements. Nevertheless, duplicate blanks were run with each set of samples, and the values obtained were subtracted from the standard and experimental values during data analysis. Pb levels in the various tissues were expressed as means [+ or -] SE and thereafter by the percentage change in mean values. Comparisons between groups were made using Student's t-test A t test is any statistical hypothesis test in which the test statistic has a Student's t distribution if the null hypothesis is true. History The t with differences reported as significant for p-values < 0.05. For elements other than Pb, we asked if mean values differed between treatment groups, and the two-tailed test two-tailed test a test in which both 'large' and 'small' values of the test statistic indicate that the null hypothesis is not correct. was employed accordingly. In the case of Pb, previous work indicated that all treatments would enhance depletion and would not be expected to elevate the levels observed. According, when analyzing the Pb data, we asked if treatment in question lowered Pb, relative to the appropriate control, and the one-tailed test was employed (Christenson and Stoop 1986). Results Levels of Pb and other elements after Pb administration. Monensin is highly selective for the transport of [Pb.sup.2+], compared with other divalent cations (Hamidinia et al. 2002), and this is one of its characteristics that led us to test this ionophore for possible use in conjunction with DMSA for the treatment of Pb intoxication. That is to say, it seemed possible that monensin might aid in the delivery of intracellular [Pb.sup.2+] to the circulating chelator without greatly perturbing the intracellular level of other cations. On the other hand, the available selectivity data were obtained using a model transport system based on phospholipid vesicles and did not include all cations of possible interest. Thus, it was not clear initially to what extent the selectivity for [Pb.sup.2+] would manifest in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. , or if cations having a physiologic role, but not yet considered in terms of selectivity, might also be perturbed per·turb tr.v. per·turbed, per·turb·ing, per·turbs 1. To disturb greatly; make uneasy or anxious. 2. To throw into great confusion. 3. . Accordingly, we examined the tissue levels of several physiologic elements (Ca, cobalt, copper, iron, manganese, magnesium, molybdenum, zinc) using ICP mass spectrometry mass spectrometry or mass spectroscopy Analytic technique by which chemical substances are identified by sorting gaseous ions by mass using electric and magnetic fields. as the detection modality modality /mo·dal·i·ty/ (mo-dal´i-te) 1. a method of application of, or the employment of, any therapeutic agent, especially a physical agent. 2. . We also examined levels of several elements having no physiologic role (arsenic, cadmium, chromium, nickel, strontium) to determine if the ionophores actions are specific for Pb among a known group of potential toxins. In Table 1 we compare the endogenous endogenous /en·dog·e·nous/ (en-doj´e-nus) produced within or caused by factors within the organism. en·dog·e·nous adj. 1. Originating or produced within an organism, tissue, or cell. levels of these cations as reported by Naveh et al. (1987) with those we found at the end of the 3-week Pb loading period. As expected, Pb rose markedly in all organs examined, but there were large differences in the absolute levels attained. Specifically, the order of Pb levels observed was femur > kidney > liver > brain > heart > skeletal muscle, with the highest value exceeding the lowest one by approximately 2.5 x [10.sup.3]. These findings are similar to those reported by others (Bogden et al. 1992; Han et al. 1996; Naveh et al. 1987). Among the other elements considered, comparisons were possible for Ca, Cu, Fe, Mg, Mn, and Zn, but not for Co, Mo, As, Cd, Cr, Ni, and Sr, because the reference study did not include data for the latter group. Among the former group, three large variations were seen: the level of Ca in kidney and the levels of Cu and Mn in femur. In all three cases, the values reported here are about 10% of the reference values ref·er·ence values pl.n. A set of laboratory test values obtained from an individual or from a group in a defined state of health. , and the differences are statistically significant. Although there are several possible reasons for variations of this magnitude, as further considered in the "Discussion," we doubt that they reflect authentic effects of Pb administration and have used our present values when interpreting other aspects of the data. Among the other organs and elements considered, variations were much smaller. Reference values for Fe in kidney and Mn in skeletal muscle are higher than what we found after Pb loading, by about a factor of 2, and these differences were also statistically significant. Regarding the other variations, many were not significantly different, whereas others were, even when the extent of variation was quite small (Table 1). Depletion of previously accumulated Pb. To express the relative effectiveness of the four treatments that were applied after the period of Pb administration, we calculated the fraction of the Pb loaded value that remained when the treatment period was complete (3 weeks) and compared these values with each other and with the endogenous values. Results are shown graphically and numerically in Figure 1. Two subsets are apparent among the six tissues examined: kidney, liver, and skeletal muscle compared with heart, brain, and femur. For those in the first subset, the mean Pb level fell dramatically simply in response to halting its administration, and these were fully significant declines compared with the levels that existed at the end of the loading period (Figure 1). For this subset, monensin alone did not alter the values significantly, compared with withdrawal alone, whereas the further decrease produced by DMSA was significant in kidney and liver. The former result might not be expected, whereas the latter was expected, based on previous reports (Cory-Slechta 1988; Hamidinia et al. 2002; Jones et al. 1997; Pappas et al. 1995). Regarding monensin used together with DMSA, the mean values in kidney and liver were lower than those produced by DMSA alone, but the p-values (0.08 in kidney, 0.14 in liver) fell short of the usual threshold of significance (0.05). For the other subset of tissues (heart, brain, and femur), halting administration alone did not significantly lower the level of Pb during the 3-week test period. Compared with the values obtained by withdrawal, the effects of monensin alone were again not significant, except in the case of heart, where the ionophore did produce a lower value. Regarding DMSA alone, this treatment lowered Pb in heart and brain but did not decrease Pb in bone, again, as might be expected (Cory-Slechta 1988; Gerhardsson et al. 1999; Jones et al. 1997; Smith et al. 2000). Of greater interest, in all three tissues, monensin plus DMSA lowered mean Pb values more noticeably than was seen in the other tissues, compared with the effect of DMSA alone, and these differences were statistically significant (Figure 1). Furthermore, the decrease produced by monensin plus DMSA in bone was significant compared with withdrawal alone, and this was also true in the five other tissues (Figure 1). Effects of monensin alone on the levels of other elements. Regarding the other elements, data are presented in Figures 2-14, which are in the same format used for Figure 1. Given that we are primarily interested in determining if monensin might be useful in the treatment of Pb intoxication, we focus first on whether or not the ionophore given alone perturbs physiologic elements. This point is of interest because such perturbations might lead to secondary forms of toxicity. Regarding Ca, monensin alone increased the level in heart by approximately 24%, compared with rats that received no treatment for accumulated Pb, but had no significant effect in the other tissues (Figure 2). By the same comparison, Co was decreased in kidney, heart, and brain, but in the no-treatment group Co fell during the 3-week period after Pb administration had ended (Figure 3). Thus, the 25-30% increases in Co produced by monensin were tending to reverse that initial decline and might therefore be viewed as advantageous. Cu was increased in kidney and brain, decreased slightly in liver and skeletal muscle, and was not changed significantly in heart and femur (Figure 4). Fe rose modestly in heart and brain but was not perturbed significantly elsewhere (Figure 5). Mg was altered only in heart (Figure 6), and Mn in liver, heart, and brain (Figure 7); these were all modest variations of around 15% or less. Changes in Mo and Zn were similarly small (Figures 8 and 9), except for the Mo level in femur, which decreased by 70% (Figure 8). Among the nonphysiologic elements (Figures 10-14), the only statistically significant effect produced by monensin alone was in heart, where the trace level of As rose by approximately 24% (Figure 10). Perturbations produced by monensin in DMSA-treated rats. Because Figure 1 indicates that monensin plus DMSA is more effective at depleting Pb than either agent used alone, it is also of interest to determine if the two agents used together perturb other elements more so than does DMSA alone and to examine perturbations produced by the combination of compounds compared with no treatment. Considering the former comparison first, and for the physiologic elements, monensin altered the levels of Ca, Co, Cu, Fe, and Zn in one or more tissues, more so than did DMSA alone, whereas the levels Mg, Mn, and Mo were not affected statistically (Figures 2-9). Among the changes of this type, all were small (on the order of < 15%), except for the level of Co in femur, which increased by 53% (Figure 3). Furthermore, the directions of these changes were such that they tended to reverse changes that arose from DMSA alone and thus might be viewed as beneficial. This is with the exception of Zn in skeletal muscle and heart (Figure 9), which was perturbed to a greater extent by monensin plus DMSA than it was by DMSA alone, although the effects were small (+16% and -10%, respectively). Considering the nonphysiologic elements, monensin plus DMSA increased Ni substantially in liver, skeletal muscle, and heart, compared with DMSA alone (Figure 13), and likewise decreased Sr in kidney and heart (Figure 14). The changes in Sr were in the direction that corrected a perturbation perturbation (pŭr'tərbā`shən), in astronomy and physics, small force or other influence that modifies the otherwise simple motion of some object. The term is also used for the effect produced by the perturbation, e.g. produced by DMSA alone, but this was not true with Ni. Perturbations produced by monensin plus DMSA compared with no treatment. Within this last area of interest, and among the physiologic elements, monensin plus DMSA produced a change in one or more tissues in all cases except Ca. Co rose in kidney, heart, and femur, but these changes were again tending to reverse declines that otherwise occurred in rats that were not treated (Figure 3). Cu fell modestly in liver, heart, and brain; Fe rose in liver and femur, whereas Zn was altered in liver, skeletal muscle, and femur (Figures 7-9). All of these changes were again small, with the exception of Mo in femur, where the increase was 62%. Considering the nonphysiologic elements (Figures 10-14), significant changes were confined to Cr and Ni, which were both increased in liver (Figures 12 and 13). Effects of treatment on other parameters. Regarding macroscopic macroscopic /mac·ro·scop·ic/ (mak?ro-skop´ik) gross (2). mac·ro·scop·ic or mac·ro·scop·i·cal adj. 1. Large enough to be perceived or examined by the unaided eye. 2. effects of the treatment strategies investigated, there was no indication that the rats were differently stressed, as indicated by their behavior, activity level, general appearance, and the macroscopic appearance of internal structures seen during dissection dissection /dis·sec·tion/ (di-sek´shun) 1. the act of dissecting. 2. a part or whole of an organism prepared by dissecting. . Records of weight gain throughout the experimental period are shown in Figure 15. During the period of Pb administration, when all rats were maintained in the same way, the per animal average weight of the five groups diverged such that there was a 25 g range in this parameter at the time that Pb was withdrawn. Comparing the no-treatment and the monensin-alone groups showed no significant difference in the subsequent rate of weight gain (Figure 15). For the rats receiving DMSA or DMSA plus monensin, weight gain lagged initially but then returned to a rate that was similar to that seen in the no-treatment or the monensin-alone groups. An unpleasant odor of the dimercaptide and gavage-related irritation of the gastrointestinal tract gastrointestinal tract n. The part of the digestive system consisting of the stomach, small intestine, and large intestine. Gastrointestinal tract may have contributed to these lags in weight gain by discouraging eating. [FIGURE 15 OMITTED] Discussion The results of the present study demonstrate that monensin plus DMSA is more effective than DMSA alone in terms of depleting rats of previously accumulated Pb, and that the combination of agents is effective in all organs/ tissues examined. Comparing the agents used in combination with DMSA alone, monensin significantly improved the outcome in heart, brain, and femur and showed a tendency to do this in kidney and liver. The improved clearance seen in heart, brain, and femur is notable because withdrawal of Pb alone is not very effective at reducing Pb in these tissues, because DMSA used alone is less effective in these tissues than in some others, and because the actions of Pb in heart, brain, and bone account for significant aspects of Pb pathophysiology pathophysiology /patho·phys·i·ol·o·gy/ (-fiz?e-ol´ah-je) the physiology of disordered function. path·o·phys·i·ol·o·gy n. 1. . Thus, in heart, Pb accumulation generates a set of effects that are analogous to those produced by various forms of human cardiac disease (Williams et al. 1983). In brain, Pb effects manifest at low overall levels and include cognitive impairment and reduced IQ (Goyer 1993; Goyer et al. 1995; Rice 1996). Bone Pb is problematic because this pool is large and is the main source of Pb that reestablishes an elevated blood concentration after treatment by existing methods (Cory-Slechta 1988; Leggett 1993; O'Flaherty 1991, 1995; O'Flaherty et al. 1998). Bone Pb can furthermore be mobilized together with Ca during aging and pregnancy to produce toxic effects even when there is no ongoing exposure to Pb from the environment. Thus, it seems worthwhile to further explore the possibility of using ionophores together with the traditional agents in the clinical treatment of Pb intoxication. Potential toxicity of the ionophore itself must be considered when contemplating a clinical application. There are no data available on the toxic actions of monensin in humans; however, the compound has long been administered to a variety of animal species that are used to produce food in agriculture. This practice arose because monensin is an anticoccidial agent, because it promotes growth, and became it is easily administered in feed as was done during this study (Ruff 1982; Shumard and Callender 1968; Walker et al. 1980). The level of 100 ppm used here is typical of that used in agriculture and is well below the level of 200 ppm where toxic actions are first seen in rats (Ruff 1982; Todd et al. 1984). To these points we can now add that monensin plus DMSA also produces no overt toxicity in rats and has little effect on growth beyond that seen with DMSA alone (Figure 15). To further examine the potential for toxicity, we determined how tissue levels of other elements changed during a period of Pb administration and during our attempts to remove it. Among the elements having a physiologic role, no situation was found in which the level of an element was markedly decreased compared to that which existed when Pb administration had been completed and treatment was about to begin. The closest we saw to this type of situation was with Co, where levels tended to decline after removal of Pb from the drinking water. The various treatments used to remove Pb either had little further effect or tended to restore Co to its pretreatment pretreatment, n the protocols required before beginning therapy, usually of a diagnostic nature; before treatment. pretreatment estimate, n See predetermination. value (Figure 3). Likewise, we did not encounter examples in which the levels of a physiologic element rose markedly, compared with a pretreatment value, as a result of any approach taken to remove Pb. Cu, Fe, Mo, and Zn rose variously in some tissues by as much as 50%, and there were a number of smaller changes (increases and decreases) where statistical significance could be demonstrated (Figures 2-9). It is difficult to say if any of these are of consequence because data describing the range of values found in normal rats as a function of strain, diet, age, and so on, are sparse. It also is not clear to what extent a "normal value" may be decreased or increased before giving rise to symptoms of deficiency or overload toxicity, respectively. Some further insight into these types of questions is obtained by examining Table 1, which shows tissue levels of physiologic elements in rats that had received Pb and levels in rats that had not been exposed. We selected data from unexposed rats reported by Naveh et al. (1987) for comparison because the rats they used were of a similar age and dietary history dietary history, n See analysis, dietary. . As seen globally in Table 1, the size of variations that were identified are similar to those that arose during attempts to remove Pb after it had accumulated. This supports our view that the changes in physiologic element levels that were seen during treatment for Pb intoxication are of little consequence. This is with the exception of Ca levels in kidney and the levels of Cu and Mn in femur. There, the same argument cannot be employed because the normal values normal values pl.n. A set of laboratory test values used to characterize apparently healthy individuals, now replaced by reference values. reported by Bogden and colleagues (Naveh et al. 1987) fare about 10-fold higher than what we found after Pb administration. These large variations may reflect methodologic problems arising during calibration or data analysis. We rechecked our own methods upon seeing these differences and note that our values are close to those reported by others (Oishi et al. 2000; Seaborn and Nielsen 2002a, 2002b). Another type of potential toxicity to consider in contemplating the use of monensin to treat Pb intoxication is the possibility that other toxic elements present in the individual might be perturbed in such way as to enhance their toxicity, even though the toxicity from Pb has been abated Abated, an ancient technical term applied in masonry and metal work to those portions which are sunk beneath the surface, as in inscriptions where the ground is sunk round the letters so as to leave the letters or ornament in relief. From 1911 Encyclopædia Britannica . Among the five toxic elements examined, we found scattered examples where one or more of the treatment strategies increased the level of a toxin in one or more of the tissues (Figures 10-14). When observed, these perturbations were sometimes much larger than what was seen with physiologic elements (e.g., the 2- to 4-fold rise of Cr and Ni in liver during treatment with monensin plus DMSA), supporting the prospects for increased toxicity. On the other hand, none of the nonphysiologic elements was being administered beyond the trace quantifies presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. present in diet, water, and the general environment provided to the rats. Accordingly, the levels of these were very low (Table 1) even when they had increased during attempts to removed Pb. Thus, it is again difficult to judge if these changes are meaningful in terms of toxicity without conducting additional studies in which the element of interest is purposely pur·pose·ly adv. With specific purpose. purposely Adverb on purpose USAGE: See at purposeful. Adv. 1. administered. The same can be said for the scattered examples where certain treatments for Pb intoxication decreased the level of another toxin (e.g., Cr and Ni in brain and As in liver). Interest is growing in the combined use of multiple chelating agents for the treatment of metal intoxication (Andersen and Aaseth 2002; Kalia and Flora 2005; Link et al. 2001; Wu et al. 2003), although the success of this approach with Pb intoxication has been limited (Jones et al. 1997; Kachru et al. 2005; Kostial et al. 1999). The question then arises: How does monensin improve the effectiveness of DMSA at removing Pb from various tissues to the extent that is seen here? The multiple chelator approach seems to work best when one of the agents is fully water soluble and the other has some hydrophobic hydrophobic /hy·dro·pho·bic/ (-fo´bik) 1. pertaining to hydrophobia (rabies). 2. not readily absorbing water, or being adversely affected by water. 3. character (Andersen and Aaseth 2002; Giardina and Grady 2001). This has been explained by the so-called relay hypothesis, or shuttle hypothesis, which maintains that the more hydrophobic agent is able to bind toxic cations that are located in compartments not accessible to the hydrophilic compound and can thereafter facilitate their movement and transfer to the hydrophilic compound. Once this has occurred, the hydrophilic compound is excreted via the kidney, together with the chelated che·late adj. Zoology Having chelae or resembling a chela. n. Chemistry A chemical compound in the form of a heterocyclic ring, containing a metal ion attached by coordinate bonds to at least two nonmetal ions. cation. Monensin is highly hydrophobic and is in fact a highly selective and efficient ionophore for [Pb.sup.2+] (Hamidinia et al. 2002). It may then be particularly effective at shuttling [Pb.sup.2+] to DMSA located in blood or in the interstitial fluid interstitial fluid n. The fluid in spaces between the tissue cells. Interstitial fluid The fluid between cells in tissues. Referred to as the liquid subtance of the body. Mentioned in: Lymphedema compartment. Additional factors to consider are illustrated in Figure 16 and relate to the fact that monensin is an effective ionophore for sodium ions ([Na.sup.+]) compared with potassium ions ([K.sup.+]) (Henderson et al. 1969; Kinnally et al. 1991; Pressman 1968). In addition, near a membrane surface, the acid dissociation constant An acid dissociation constant, denoted by Ka, is an equilibrium constant for the dissociation of a weak acid. According to the Brønsted-Lowry theory of acids and bases an acid is only recognised by its reaction with a base. ([pK.sub.a]) for monensin is 6.85, and the [Na.sup.+] dissociation constant Noun 1. dissociation constant - the equilibrium constant for a reversible dissociation equilibrium constant - (chemistry) the ratio of concentrations when equilibrium is reached in a reversible reaction (when the rate of the forward reaction equals the rate of the ([pK.sub.Na]) is 5.00 (Hamidinia et al. 2002), whereas the in vivo concentrations of hydrogen ions hydrogen ion n. The positively charged ion of hydrogen, H+, formed by removal of the electron from atomic hydrogen and found in all aqueous solutions of acids. Noun 1. ([H.sup.+]) and [Na.sup.+] in extracellular volumes are about [10.sup.-7] M and [10.sup.-3] M, respectively. The pK values were obtained in solutions of 80% methanol methanol, methyl alcohol, or wood alcohol, CH3OH, a colorless, flammable liquid that is miscible with water in all proportions. Methanol is a monohydric alcohol. It melts at −97. in water, an environment that mimics a membrane-water interface in terms of polarity (1) The direction of charged particles, which may determine the binary status of a bit. (2) In micrographics, the change in the light to dark relationship of an image when copies are made. (Pfeiffer et al. 1983; Taylor et al. 1985, 1993). Furthermore, at physiologic pH, it appears that the predominant species by which monensin transports [Pb.sup.2+] is the mixed complex monensin.Pb.OH (Hamidinia et al. 2002). Thus, when acting to deliver intracellular [Pb.sup.2+] to extracellular DMSA, it is probable that the compound enters cells as the species monensin*Na, leaves as the mixed complex, and so in effect catalyzes an exchange of extracellular [Na.sup.+] for intracellular PbO[H.sup.+] (equivalent to exchanging an extracellular [Na.sup.+] and an [H.sup.*] for an intracellular [Pb.sup.2+]) (Figure 16). Given that the external/internal [Na.sup.+] concentration gradient concentration gradient n. The graduated difference in concentration of a solute per unit distance through a solution. Noun 1. is maintained by Na, K-ATPase, the presence of monensin partially couples the release of intracellular [Pb.sup.2+] to ATP hydrolysis ATP hydrolysis is the reaction by which chemical energy that has been stored and transported in the high-energy phosphoanhydridic bonds in ATP (Adenosine triphosphate) is released, for example in the muscles, to produce work. , giving a direction and a driving force to the process. This may also help explain why the presence of monensin enhances the effectiveness of DMSA at removing Pb. However, it should also be pointed out that monensin may act in a more indirect way to enhance the action of DMSA. One possibility relates to the depletion of Pb from bone, where monensin might increase the rate of bone turnover. Were that to occur, access of Pb to DMSA would possibly be increased without a requirement for direct [Pb.sup.2+] transport mediated by the ionophore. [FIGURE 16 OMITTED] A final point arises upon comparing an aspect of the present data with those from a previous study in which monensin alone was administered to Pb-intoxicated rats (Hamidinia et al. 2002). The earlier study showed that monensin alone accelerated the removal of Pb from several tissues, compared with no treatment, whereas in the present study this was seen only in heart tissue (Figure 1). In the present study, Pb was released more efficiently under the no-treatment condition than was reported earlier (Hamidinia et al. 2002), even though the design of both studies was very similar. These differences related to how the rats were housed: during the earlier study (Hamidinia et al. 2002), they were housed individually and in metabolic cages (i.e., standing on metal gratings See diffraction grating and fiber Bragg grating. ), which are both considered to be stressful circumstances; in the present study rats were housed in pairs, in plastic cages containing normal bedding. When viewed collectively, these considerations suggest that the mechanism(s) that remove Pb under no-treatment conditions are less efficient in stressed rats and that monensin used alone is more efficient when organ Pb levels are higher. The later point is of interest here because it implies that monensin alone may be even more effective at higher levels of Pb intoxication and that other Pb ionophores having a higher affinity for Pb may also be more effective. These possibilities can be tested experimentally and are under investigation. Received 3 May 2005; accepted 29 September 2005. REFERENCES Andersen O, Aaseth J. 2002. Molecular mechanisms of in vivo metal chelation Chelation The process by which a molecule encircles and binds to a metal and removes it from tissue. Mentioned in: Heavy Metal Poisoning chelation : implications for clinical treatment of metal intoxications. Environ Health Perspect 110:887-890. Bogden JD, Gertner SB, Christakos S, Kemp FW, Yang Z, Katz SR, et al. 1992. Dietary calcium modifies concentrations of lead and other metals and renal calbindin in rats. J Nutr 122:1351-1360. Bogden JD, Kemp FW, Han S, Murphy M, Fraiman M, Czerniach D, et al. 1995. Dietary calcium and lead interact to modify maternal blood pressure, erythropeiesis, and fetal and neonatal growth in rats during pregnancy and lactation lactation Production of milk by female mammals after giving birth. The milk is discharged by the mammary glands in the breasts. Hormones triggered by delivery of the placenta and by nursing stimulate milk production. . J Nutr 125:990-1002. Castellino N, Aloj S. 1964. Action of calcium disodium edathamil on the kinetics kinetics: see dynamics. Kinetics (classical mechanics) That part of classical mechanics which deals with the relation between the motions of material bodies and the forces acting upon them. of the distribution and excretion excretion, process of eliminating from an organism waste products of metabolism and other materials that are of no use. It is an essential process in all forms of life. In one-celled organisms wastes are discharged through the surface of the cell. of lead ([sup.210]pb) acetate in the rat [in Italian]. Folia fo·li·a n. Plural of folium. Med 47:381-403. Christenson LB, Stoop CM. 1986. Hypothesis testing hypothesis testing In statistics, a method for testing how accurately a mathematical model based on one set of data predicts the nature of other data sets generated by the same process. . In: Introduction to Statistics. Belmont, CA:Brook/Cole, 250-275. Cory-Slechta DA. 1988. Mobilization of lead over the course of DMSA chelation therapy and long-term efficacy. J Pharmacol Exp Ther 246:84-91. Cory-Slechta DA, Weiss B, Cox C. 1987. Mobilization and redistribution of lead over the course of calcium disedium ethylenediamine ethylenediamine /eth·y·lene·di·a·mine/ (eth?i-len-di´ah-men) a clear liquid with an ammonialike odor and a strong alkaline reaction; complexed with theophylline it forms aminophylline. tetraacetate chelation therapy. J Pharmacol Exp Ther 243:804-813. Cremin JD, Luck ML, Laughlin NK, Smith DR. 1999. Efficacy of succimer chelation for reducing brain lead in a primate model of lead exposure. Toxicol Appl Pharmacol 161:283-293. Erdahl WL, Chapman C J, Taylor RW, Pfeiffer DR. 2000. Ionomycin, a carboxylic acid ionophore, transports [Pb.sup.2+] with high selectivity. J Biol Chem 275:7071-7079. Gerhardsson L, Borjesson J, Mattsson S, Schutz A, Skerfving S. 1999. Chelated lead in relation to lead in bone and ALAD ALAD d-aminolevulinic acid dehydratase. genotype genotype (jēn`ətīp'): see genetics. genotype Genetic makeup of an organism. The genotype determines the hereditary potentials and limitations of an individual. . Environ Res 80:389-398. Giardina PJ, Grady RW. 2001. Chelation therapy in [beta]-thalassemia: an optimistic op·ti·mist n. 1. One who usually expects a favorable outcome. 2. A believer in philosophical optimism. op update. Semin Hematol 38:360-366. Goyer RA. 1993. Lead toxicity: current concerns. Environ Health Perspect 100:177-187. Goyer RA, Cherian MG, Jones MM, Reigart JR. 1995. Role of chelating agents for prevention, intervention, and treatment of exposure to toxic metals toxic metal Environment Any metal known to be toxic to humans–eg, antimony, arsenic, beryllium, bismuth, cadmium, lead, mercury, nickel. Cf Nontoxic metal. . Environ Health Perspect 103:1048-1052. Graziano JH. 1986. Role of 2,3-dimercaptosuccinic acid in the treatment of heavy metal poisoning Heavy Metal Poisoning Definition Heavy metal poisoning is the toxic accumulation of heavy metals in the soft tissues of the body. Description . Med Texicol 1:155-162. Graziano JH. 1993. Conceptual and practical advance in the measurement and clinical management of lead toxicity. Neurotoxicology 14:219-223. Graziano JH, Lolacono N J, Meyer P. 1988. Dose-response study of oral 2,3-dimercaptesuccinic acid in children with elevated blood lead concentrations. J Pediatr 113:751-757. Graziano JH, Siris ES, Lolacono N, Silverberg S J, Turgeon L 1985. 2,3-Dimercaptosuccinic acid as an antidote for lead intoxication. Clin Pharmacol Thor 37:431-438. Hamidinia SA, Shimelis 01, Tan B, Erdahl WL, Chapman CJ, Renkes GD, et al. 2002. Monensin mediates a rapid and highly selective transport of [Pb.sup.2+]: possible application of monensin for the treatment of [Pb.sup.2+] intoxication. J Biol Chem 277:38111-38120. Hamidinia SA, Tan B, Erdahl WL, Chapman CJ, Taylor RW, Pfeiffer DR. 2004. The ionophore nigericin transports [Pb.sup.2+] with high activity and selectivity: a comparison to monensin and ienomycin. Biochemistry 43:15956-15965. Han S, Qiao X, Simpson S Simp·son , Sir James Young 1811-1870. British obstetrician and a founder of gynecology. He is also known for introducing the use of chloroform as an anesthetic. , Ameri P, Kemp FW, Bogden JD. 1996. Weight loss alters organ concentrations and contents of lead and some essential divalent metals in rats previously exposed to lead. J Nutr 126:317-323. Henderson PJF PJF Policía Judicial Federal (Spanish: Federal Judicial Police, Mexico) PJF Pre-Joycean Fellowship (used by writer, Steve Brust) PJF Professor John Frink (Simpsons cartoon) , McGivan JD, Chappell JB. 1969. The action of certain antibiotics on mitochondrial mitochondrial pertaining to mitochondria. mitochondrial RNAs a unique set of tRNAs, mRNAs, rRNAs, transcribed from mitochondrial DNA by a mitochondrial-specific RNA polymerase, that account for about 4% of the total cell RNA that , erythrocyte erythrocyte (ĭrĭth`rəsīt'): see blood. erythrocyte or red blood cell or red blood corpuscle Blood cell that carries oxygen from the lungs to the body tissues. and artificial phospholipid membranes. Biochem J 111:521-535. Jones MM, Singh PK, Kostial K, Blanusa M, Piasek M, Restek-Samarozija N. 1997. Comparative in lead mobilization of meso- and rac-2,3-dimercaptosuccinic acids in albino albino (ălbī`nō) [Port.,=white], animal or plant lacking normal pigmentation. The absence of pigment is observed in the body covering (skin, hair, and feathers) and in the iris of the eye. Wistar rats. Pharmacol Toxicol 80:182-186. Kachru DN, Singh S, Tandon SK. 2005. Chelation in metal intoxication. XXXIV. Mixed ligand ligand (lĭg`ənd), charged or uncharged molecule with one or more unshared pairs of electrons that can attach to a central metallic atom or ion to form an aggregate known as a complex ion (see chemical bond). chelation in lead poisoning lead poisoning or plumbism (plŭm`bĭz'əm), intoxication of the system by organic compounds containing lead. . Toxicol Lett 57:251-256. Kalia K, Flora SJS SJS Stevens Johnson Syndrome (medical) SJS San Jose Sharks SJS St Joseph's School (Ifugao, Philippines) SJS Schwartz-Jampel Syndrome SJS San Jose Scale SJS Secretary, Joint Staff . 2005. Strategies for safe and effective therapeutic measures for chronic arsenic and lead poisoning. J Occup Health 47:1-21. Kinnally KW, Zorev D, Antonenke Y, Perini S Perini Corporation (NYSE: PCR) is one of the largest general contractors in the United States. At the end of 2004 its revenue was almost $2 billion. Perini is headquartered in Framingham, Massachusetts and as a consequence bids on many heavy construction projects in . 1991. Calcium modulation of mitochondrial inner membrane The inner membrane is the cell membrane (phospholipid bilayer) of an organelle or Gram-negative bacteria that is within an outer membrane. In eukaryotic cells, this inner membrane is present within the nuclear envelope, mitochondria and plastids like the chloroplast. channel activity. Biochem Biophys Res Commun 176:1183-1188. Kestial K, Blanusa M, Piasek M, Restek-Samarozija N, Jones MM, et al. 1999. Combined chelation therapy in reducing tissue lead concentrations in suckling suckling In mammals, the drawing of milk into the mouth from the nipple of a mammary gland. In human beings, it is referred to as nursing or breast-feeding. The word also denotes an animal that has not yet been weaned—that is, whose access to milk has not yet been rats. J Appl Toxicol 19:143-147. Leggett RW. 1993. An age-specific kinetic model of lead metabolism in humans. Environ Health Perspect 101:598-616. Link G, Konijn AM, Breuer W, Cabantchik ZI, Hershko C. 2001. Exploring the "iron shuttle" hypothesis in chelation therapy: effects of combined deferoxamine and deferiprone treatment in hyper A Greek work meaning "above" or "more than." It is used as a prefix to technical concepts and products to convey a more advanced or more automatic capability. transfused rats with labeled iron stores and in iron-loaded rat heart cells in culture. J Lab Clin Meal 138:130-138. Llobet JM, Domingo JL, Paternain JL, Corbella J. 1990. Treatment of acute lead intoxication. A quantitative comparison of a number of chelating agents. Arch Environ Contain Toxicol 19:185-189. Naveh Y, Weis P, Chung HR, Bogden JD. 1987. Effect of cimetidine cimetidine /ci·met·i·dine/ (si-met´i-den) a histamine H2 receptor antagonist, which inhibits gastric acid secretion; used as the base or the monohydrochloride salt in the treatment and prophylaxis of gastric or duodenal ulcers, on tissue distribution of some trace elements Trace elements A group of elements that are present in the human body in very small amounts but are nonetheless important to good health. They include chromium, copper, cobalt, iodine, iron, selenium, and zinc. Trace elements are also called micronutrients. and minerals in the rat. J Nutr 117:1576-1587. O'Flaherty EJ. 1991. Physiologically based models for bone-seeking elements. II. Kinetics of lead disposition in rats. Toxicol Appl Pharmacol 111:313-331. O'Flaherty EJ. 1995. Physiologically based models for bone-seeking elements. V. Lead absorption and disposition in childhood. Toxicol Appl Pharmacol 131:297-308. O'Flaherty EJ, Inskip MJ, Franklin CA, Durbin PW, Manton WI, Baccanale CL. 1998. Evaluation and modification of a physiological based model of lead kinetics using data from a sequential isotope isotope (ī`sətōp), in chemistry and physics, one of two or more atoms having the same atomic number but differing in atomic weight and mass number. The concept of isotope was introduced by F. study in cynomolgus monkeys, Toxicol Appl Pharmacol 149:1-18. Oishi S, Nakagawa J, Ando M. 2000. Effects of cadmium administration on the endogenous metal balance in rats. Biol Trace Elem Res 76:257-278. Pappas JB, Ahlquist JT, Allen EM, Banner W Jr. 1995. Oral dimercaptosuccinic acid Dimercaptosuccinic acid, or DMSA, is the chemical compound with the formula HO2CCH(SH)CH(SH)CO2H. This colourless solid contains two carboxylic acid and two thiol groups, the latter being responsible for the mildly unpleasant odour of this dicarboxylic acid. and ongoing exposure to lead: effects on heme synthesis and lead distribution in a rat model. Toxicol Appl Pharmacol 133:121-129, Pfeiffer DR, Chapman C J, Taylor RW, Laing JL. 1983. Monovalent monovalent /mono·va·lent/ (-va´lent) 1. having a valency of one. 2. capable of combining with only one antigenic specificity or with only one antibody specificity. cation-A23187 equilibrium in Me0H-[H.sub.2]O solutions and on phospholipid vesicles. Inorg Chim Acta 79:214-215. Pressman BC. 1968. Ionophorous antibiotics as models for biological transport. Fed Proc 27:1283-1288. Rice DC. 1996. Behavioral effects of lead: commonalities between experimental and epidemiological data. Environ Health Perspect 104(suppl 2):337-351. Ruff MD. 1982. Veterinary applications. In: Polyether Antibiotics: Naturally Occurring Acid Ionophores, Vol 1 (Westley JW, ed). New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of : Marcel Dekker Marcel Dekker is a well-known encyclopedia publishing company with editorial boards found in New York, New York. They are part of the Taylor and Francis publishing group. Initially a textbook publisher, they went to encyclopedia publishing in the late 1990's. , 303-332. Seaborn CD, Nielsen FH. 2002, Dietary silicon and arginine arginine (är`jənĭn), organic compound, one of the 20 amino acids commonly found in animal proteins. Only the l-stereoisomer participates in the biosynthesis of proteins. affect mineral element composition of rat femur and vertabra. Biol Trace Elem Res 2002:239-250. Seaborn CD, Nielsen FH. 2002. Silicon deprivation decreases collagen formation in wounds and bone, and ornithine ornithine /or·ni·thine/ (or´ni-then) an amino acid obtained from arginine by splitting of urea; it is an intermediate in urea biosynthesis. or·ni·thine n. Abbr. transaminase transaminase /trans·am·i·nase/ (-am´i-nas) aminotransferase. trans·am·i·nase n. See aminotransferase. enzyme activity Enzyme activity A measure of the ability of an enzyme to catalyze a specific reaction. Mentioned in: Glucose-6-Phosphate Dehydrogenase Deficiency in liver. Biol Trace Elem Res 2002:251-281. Seaton CL, Lasman J, Smith DR. 1999. The effects of CaNa2EDTA on brain lead mobilization in rodents determined using a stable lead isotope tracer. Toxicol Appl Pharmacol 159:153-160. Shumard RF, Callender ME. 1968. Monensin, a new biologically active compound. VI. Anticoccidial activity. Antimicrob Agents Chemother 1967:369-377. Smith DR, Woolard D, Luck ML, Laughlin NK. 2000. Seccimer and the reduction of tissue lead in juvenile monkeys. Toxicol Appl Pharmacol 166:230-240. Smith M, Bayer L, Strupp BJ. 1998, Efficacy of succimer chelation for reducing brain Pb levels in a rodent rodent, member of the mammalian order Rodentia, characterized by front teeth adapted for gnawing and cheek teeth adapted for chewing. The Rodentia is by far the largest mammalian order; nearly half of all mammal species are rodents. model. Environ Res 78:168-176. Taylor RW, Chapman C J, Pfeiffer DR. 1985. Effect of membrane associations on the stability of complexes between ionophore A23187 and monovalent cations. Biochemistry 24:4852-4859. Taylor RW, Pfeiffer DR, Chapman CJ, Craig ME, Thomas TP. 1993. Cemplexation chemistry of ionophores A23187 and ionomycin. Pure Appl Chem 65:579-584. Todd GC, Novilla MN, Howard LC. 1984. Comparative toxicology toxicology, study of poisons, or toxins, from the standpoint of detection, isolation, identification, and determination of their effects on the human body. Toxicology may be considered the branch of pharmacology devoted to the study of the poisonous effects of drugs. of monensin sodium in laboratory animals. J Anim Sci 58:1512-1517. Walker PM, Weichenthal BA, Cmarik GF. 1980. Efficacy of monensin for beef cows. J Anita Sci 51:532-538. Williams B J, Hejtmancik MR, Abreu M. 1983. Cardiac effects of lead, Fed Proc 42:2989-2993. Wu KH, Chang JS, Tsai CH, Peng CT. 2003. Combined therapy with deferiprone and desferrioxamine successfully regresses severe heart failure in patients with [beta]-thalassemia major. Ann Hematol 83:471-473. Shawn A. Hamidinia, (1) Warren L. Erdahl, (1) Clifford J. Chapman, (1) Gregory E. Steinbaugh, (1) Richard W. Taylor, (2) and Douglas R. Pfeiffer (1) (1) Departments of Molecular and Cellular Biochemistry, Ohio State University, Columbus, Ohio Columbus is the capital and the largest city of the American state of Ohio. Named for explorer Christopher Columbus, the city was founded in 1812 at the confluence of the Scioto and Olentangy rivers, and assumed the functions of state capital in 1816. , USA; (2) Department of Chemistry and Biochemistry, University of Oklahoma University of Oklahoma, abbreviated OU, is a coeducational public research university located in the U.S. state of Oklahoma. Founded in 1890, it existed in Oklahoma Territory near Indian Territory 17 years before the two became the state of Oklahoma. , Norman, Oklahoma, USA Address correspondence to D.R. Pfeiffer, Department of Molecular and Cellular Biochemistry, Ohio State University, 1645 Nell Ave., 310A Hamilton Hall
Hamilton Hall was a hall of residence for the University of St Andrews, Scotland, between the years of 1949 and 2006. , Columbus, Ohio 43210-1218. Telephone: (614) 292-8774. Fax: (614) 292-4118. E-mail: pfeiffer.17@ osu.edu This research was supported by grant GM 66206 from the National Institutes of General Medical Sciences, National Institutes of Health; by grant 0255017B from the American Heart Association American Heart Association (AHA), n.pr a national voluntary health agency that has the goal of increasing public and medical awareness of cardiovascular diseases and stroke, and thereby reducing the number of associated deaths and disabilities. , Ohio Valley Affiliate; and by grant HR00-030 from the Oklahoma Center for the Advancement of Science and Technology. The authors declare they have no competing financial interests.
Table 1. Effects of Ph administration on the
concentrations (nmol/q) of selected elements
in rat tissues.
Tissue
Skeletal
Element Kidney Liver muscle
Pb 29.8 * 5.77 * 0.073 *
0.20 0.20 ND
Physiologic
Ca 897 * 574 1,318 *
12,775 669 1,193
Co 1.24 0.352 0.025
NR NR NR
Cu 62.1 * 51.1 13.6
96.9 59.2 14.0
Fe 524 * 1,534 * 133 *
1,112 1,003 191
Mg 6,627 8,203 * 10,028
7,365 6,665 9,998
Mn 13.1 * 32.0 * 1.02 *
19.8 37.3 2.4
Mo 2.21 4.10 0.083
NR NR NR
Zn 295 472 * 162 *
327 329 284
Nonphysiologic
As 0.035 0.444 0.121
NR NR NR
Cr 0.012 0.004 0.033
NR NR NR
Cd 0.082 0.062 0.003
NR NR NR
Ni 0.070 0.029 0.097
NR NR NR
Sr 0.088 0.061 0.313
NR NR NR
Tissue
Element Heart Brain Femur
Pb 0.163 * 1.19 * 203 *
0.005 0.05 ND
Physiologic
Ca 522 * 2,418 4,025,000 *
903 1,327 3,220,000
Co 0.523 0.093 0.130
NR NR NR
Cu 101 * 38.7 * 5.29 *
78.4 33.4 45.5
Fe 1,049 239 * 771
1,010 315 702
Mg 8,885 * 6,561 * 117,300
8,023 6,048 91,750
Mn 7.34 * 7.12 6.44 *
10.32 8.83 52.8
Mo 0.492 0.299 0.187
NR NR NR
Zn 315 * 247 * 1,844
246 180 1,743
Nonphysiologic
As 0.437 0.071 0.207
NR NR NR
Cr 0.886 0.066 ND
NR NR NR
Cd 0.005 0.005 0.006
NR NR NR
Ni 0.420 0.080 ND
NR NR NR
Sr 0.110 0.277 56.3
NR NR NR
Abbreviations: ND, not detected in this study,
NR, not reported. The upper value for each element
is from the present study and was determined after
the rats had been given 100 ppm [Pb.sup.2+] in their
drinking water for 3 weeks (see "Materials and Methods").
The lower value for each element is from the literature
and was determined using rats that had not been given
Pb: values for Pb are from Hamidinia et al. (2002), and
values for the other elements are from Naveh et al. (1987).
* Values obtained during this study that are statistically
different (p < 0.05) from the corresponding literature value.
Figure 1. (A) Fractional changes (+ SE) in tissue levels
of Pb produced by selected treatments. Rats were treated
as described in "Materials and Methods." Pb levels observed
for the Pb-loaded group are presented in Table 1; values
for the Pb-loaded group were set to 1.0 to aid in
normalizing values of other treatment groups. (8) Percent
changes in mean values calculated using the same data
shown in (A).
[B]
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded -77 * -86.3 * -68.0 *
Monensin vs. no treatment +34.0 +17.8 -34.7
DMSA vs. no treatment -61.4 * -74.2 * -34.0
Monensin + DMSA vs. DMSA -36.3 -36.5 -4.5
Monensin + DMSA vs. -75.4 * -83.6 * -34.0 *
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +6.4 -30.6 -22.8
Monensin vs. no treatment -36.7 * +2.1 +18.5
DMSA vs. no treatment -52.7 * -58.6 * -10.6
Monensin + DMSA vs. DMSA -38.5 * -45.9 * -43.8 *
Monensin + DMSA vs. -70.9 * -77.6 * -49.6 *
no treatment
* Statistically significant (p < 0.05).
Figure 2. (A) Fractional changes (+ SE) in tissue
levels of Ca occurring during treatment for Pb
intoxication. For details, see "Materials and
Methods" and Table 1; values for the Pb-loaded
group were set to 1.0 to aid in normalizing
values of other treatment groups. (8) Percent
changes in mean values calculated
using the same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +19.1 +15.5 +0.1
Monensin vs. no treatment +8.6 -10.3 +7.3
DMSA vs. no treatment +10.2 -17.1 +0.5
Monensin + DMSA vs. DMSA -8.1 +3.5 +7.3
Monensin + DMSA vs. +1.3 -14.2 +7.9
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded -4.7 -2.0 +4.5 *
Monensin vs. no treatment +23.9 * +18.6 -0.9
DMSA vs. no treatment +6.3 +34.6 +4.4
Monensin + DMSA vs. DMSA -3.3 -15.6 -4.8 *
Monensin + DMSA vs. +2.8 +13.7 -0.6
no treatment
* Statistically significant (p< 0.05).
Figure 3. (A) Fractional changes (+ SE) in tissue levels of
Co occurring during treatment for Pb intoxication. For details,
see "Materials and Methods" and Table 1; values for the
Pb-loaded group were set to 1.0 to aid in normalizing values
of other treatment groups. (e) Percent changes in mean values
calculated using the same data shown in (A).
[B]
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded -31.8 * -37.7 * +12.2
Monensin vs. no treatment +35.1 * +8.3 +13.2
DMSA vs. no treatment +15.1 -6.8 -22.3
Monensin + DMSA vs. DMSA +28.5 +25.4 +13.5
Monensin + DMSA vs. +48.0 * +16.9 -11.8
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded -22.8 * -17.7 * -57.3 *
Monensin vs. no treatment +26.6 * +23.3 * +14.5
DMSA vs. no treatment +10.4 +6.1 +14.4
Monensin + DMSA vs. DMSA +17.5 * +8.3 * +52.7 *
Monensin + DMSA vs. +29.6 * +14.9 * +74.7 *
no treatment
* Statistically significant (p < 0.05).
Figure 4. (A) Fractional changes (+ SE) in tissue levels
of Cu occurring during treatment for Pb intoxication. For
details, see "Materials and Methods" and Table 1; values
for the Pb-loaded group were set to 1.0 to aid in normalizing
values of other treatment groups. (e) Percent changes in mean
values calculated using the same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +28.2 * +13.2 * +0.2
Monensin vs. no treatment +19.3 * -7.0 * -9.3 *
DMSA vs. no treatment -2.0 -11.8 * -10.2 *
Monensin + DMSA vs. DMSA -6.9 +5.9 +2.9
Monensin + DMSA vs. -8.8 -6.6 * -7.6
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +10.1 -0.5 +54.4
Monensin vs. no treatment +1.0 +11.3 * -24.7
DMSA vs. no treatment -2.7 -6.6 -16.6
Monensin + DMSA vs. DMSA -13.1 * -1.2 -2.5
Monensin + DMSA vs. -15.5 * -7.7 * -18.7
no treatment
* Statistically significant (p < 0.05).
Figure 5. (A) Fractional changes (+ SE) in tissue levels
of Fe occurring during treatment for Pb intoxication.
For details, see "Materials and Methods" and Table 1;
values for the Pb-loaded group were set to 1.0 to aid
in normalizing values of other treatment groups.
(8) Percent changes in mean values calculated using the
same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +26.0 * +12.8 +3.2
Monensin vs. no treatment -3.0 -2.5 -4.4
DMSA vs. no treatment +3.8 +16.4 +0.3
Monensin+DMSAvs.DMSA -10.3 +5.4 +2.1
Monensin + DMSA vs. -6.9 +22.7 * +2.4
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +8.3 -5.8 +18.6 *
Monensin vs. no treatment +15.7 * +17.9 * +6.2
DMSA vs. no treatment +13.3 * +3.9 +19.1
Monensin+DMSAvs.DMSA -9.2 * -5.8 +11.0
Monensin + DMSA vs. +2.8 -2.1 +32.1 *
no treatment
* Statistically significant (p < 0.05).
Figure 6. (A) Fractional changes (+ SE) in tissue levels
of Mg occurring during treatment for Pb intoxication. For
details, see "Materials and Methods" and Table 1; values
for the Pb-loaded group were set to 1.0 to aid in normalizing
values of other treatment groups. (e) Percent changes in
mean values calculated using the same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded -6.9 +3.5 +12.4 *
Monensin vs. no treatment +7.5 -6.2 +1.9
DMSA vs. no treatment +8.1 -9.7 * -0.5
Monensin + DMSA vs. DMSA +3.1 +4.2 -1.8
Monensin + DMSA vs. +11.4 -5.9 -2.2
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded -1.6 -5.9 * +0.0
Monensin vs. no treatment +9.5 * +4.1 +5.5
DMSA vs. no treatment +1.9 -10.3 * +3.1
Monensin + DMSA vs. DMSA -2.1 -6.2 +3.7
Monensin + DMSA vs. -0.3 -15.8 * +6.9 *
no treatment
* Statistically significant (p < 0.05).
Figure 7. (A) Fractional changes (+ SE) in tissue levels
of Mn occurring during treatment for Pb intoxication.
For details, see "Materials and Methods" and Table 1;
values for the Pb-loaded group were set to 1.0 to aid
in normalizing values of other treatment groups.
(8) Percent changes in mean values calculated using
the same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded -4.6 +5.8 -7.6
Monensin vs. no treatment +4.9 -10.8 * -5.0
DMSA vs. no treatment +4.2 -6.3 -4.0
Monensin + DMSA vs. DMSA +1.6 +5.5 +0.3
Monensin + DMSA vs. +5.8 -1.2 -3.7
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +0.2 -2.4 -5.1
Monensin vs. no treatment +7.5 * +6.7 * -2.0
DMSA vs. no treatment +1.1 -2.1 -2.4
Monensin + DMSA vs. DMSA -2.8 -2.5 +3.6
Monensin + DMSA vs. -1.7 -4.6 * +1.2
no treatment
* Statistically significant (p < 0.05).
Figure 8. (A) Fractional changes (+ SE) in tissue
levels of Mo occurring during treatment for Pb
intoxication. For details, see "Materials and
Methods" and Table 1; values for the Pb-loaded group
were set to 1.0 to aid in normalizing values of other
treatment groups. (8) Percent changes in mean values
calculated using the same data shown in (A).
Comparison Kidney Liver Muscle
No treatment vs. loaded +12.5 * +25.9 * +11.2
Monensin vs. no treatment +1.9 -8.4 +6.4
DMSA vs. no treatment +8.1 * -11.1 +13.8
Monensin + DMSA vs. DMSA -2.1 +2.8 -1.2
Monensin + DMSA vs. +5.8 -8.6 -12.5
no treatment
Comparison Heart Brain Femur
No treatment vs. loaded -3.3 -1.3 -17.6
Monensin vs. no treatment +10.2 * +8.5 * +70.7 *
DMSA vs. no treatment +8.4 * -1.0 +56.3 *
Monensin + DMSA vs. DMSA -2.3 +2.2 +3.5
Monensin + DMSA vs. +5.8 * +1.2 +61.7 *
no treatment
* Statistically significant (p < 0.05).
Figure 9. (A) Fractional changes (+ SE) in tissue levels
of Zn occurring during treatment for Pb intoxication.
For details, see "Materials and Methods" and Table 1;
values for the Pb-loaded group were set to 1.0 to aid
in normalizing values of other treatment groups.
(a) Percent changes in mean values calculated using
the same data shown in (A).
Comparison Kidney Liver Muscle
No treatment vs. loaded +1.8 +5.8 * +4.5
Monensin vs. no treatment +8.7 -5.3 * +3.3
DMSA vs. no treatment +7.4 -4.7 -4.9
Monensin + DMSA vs. DMSA +0.3 -0.7 +15.9 *
Monensin + DMSA vs. +7.7 -5.3 * +10.1 *
no treatment
Comparison Heart Brain Femur
No treatment vs. loaded -5.3 -2.7 +6.8
Monensin vs. no treatment +14.8 * +10.0 * +1.6
DMSA vs. no treatment +5.5 -2.4 +10.1
Monensin + DMSA vs. DMSA -9.9 * -2.8 +5.7
Monensin + DMSA vs. -5.0 -4.4 +16.4 *
no treatment
* Statistically significant (p < 0.05).
Figure 10. (A) Fractional changes (+ SE) in tissue
levels of As occurring during treatment for Pb
intoxication. For details, see Materials and Methods
and Table 1; values for the Pb-loaded group were set
to 1.0 to aid in normalizing values of other treatment
groups. (e) Percent changes in mean values calculated
using the same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded -23.7 -47.0 -4.9
Monensin vs. no treatment +0.5 +23.6 +7.9
DMSA vs. no treatment +8.3 -18.6 +7.0
Monensin + DMSA vs.DMSA -7.2 +6.2 -3.0
Monensin + DMSA vs. +0.5 -13.5 +3.8
no treatment
Comparison Heart Brain Femur
No treatment vs. loaded -14.2 +11.6 +59.1
Monensin vs. no treatment +23.6 * -11.7 +20.3
DMSA vs. no treatment +9.4 -11.7 +27.8
Monensin + DMSA vs. DMSA -8.0 -2.4 -23.4
Monensin + DMSA vs. +0.6 -2.2 -2.1
no treatment
* Statistically significant (p < 0.05).
Figure 11. (A) Fractional changes (+ SE) in tissue
levels of Cd occurring during treatment for Pb
intoxication. For details, see "Materials and Methods"
and Table 1; values for the Pb-loaded group were set
to 1.0 to aid in normalizing values of other
treatment groups. (e) Percent changes in mean values
calculated using the same data shown in (A)
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +28.6 +17.5 +20.1
Monensin vs. no treatment +28.4 +22.7 -36.9
DMSA vs. no treatment +0.7 -10.2 +0.1
Monensin + DMSA vs. DMSA +59.5 +5.0 +57.9
Monensin + DMSA vs. +60.6 -5.7 +58.1
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +3.6 +9.3 +14.3
Monensin vs. no treatment +16.3 +15.4 -18.9
DMSA vs. no treatment -5.8 -1.7 +0.9
Monensin + DMSA vs. DMSA +2.0 +11.8 -13.3
Monensin + DMSA vs. -3.9 +9.9 -12.6
no treatment
Figure 12. (A) Fractional changes (+ SE) in tissue levels
of Cr occurring during treatment for Pb intoxication. For
details, see "Materials and Methods" and Table 1; values
for the Pb-loaded group were set to 1.0 to aid in
normalizing values of other treatment groups. Where data
are missing, levels of Cr were too low to be determined
relative to the levels in blanks that arose as contaminants.
(8) Percent changes in mean values calculated using the
same data shown in (A). NO, not detected.
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +14.8 -21.2 +13.3
Monensin vs. no treatment +40.7 -17.9 -8.2
DMSA vs. no treatment -81.4 +143.0 +41.0
Monensin + DMSA vs.DMSA ND +96.9 -3.4
Monensin + DMSA vs. ND +379 * +36.2
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded -42.5 * -63.1 ND
Monensin vs. no treatment -13.6 -33.5 ND
DMSA vs. no treatment -24.3 +370.9 ND
Monensin + DMSA vs. DMSA -4.1 -83.9 ND
Monensin + DMSA vs. -27.4 -24.4 ND
no treatment
* Statistically significant (p < 0.05).
Figure 13. (A) Fractional changes (+ SE) in tissue levels of Ni
occurring during treatment for Pb intoxication. For details, see
"Materials and Methods" and Table 1; values for the Pb-loaded
group were set to 1.0 to aid in normalizing values of other
treatment groups. Where data are missing, levels of Ni were too
low to be determined relative to the levels in blanks that arose
as contaminants. (8) Percent changes in mean values calculated
using the same data shown in (A). ND, not detected.
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +63.3 +38.1 -5.5
Monensin vs. no treatment +48.6 +168.9 -58.9
DMSA vs. no treatment +37.1 -40.5 -67.0 *
Monensin + DMSA vs. DMSA +3.8 +458 * +260 *
Monensin + DMSA vs. +42.3 +232 * +19.0
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +28.2 -51.1 ND
Monensin vs. no treatment -26.8 -22.2 -42.2
DMSA vs. no treatment -31.7 -35.4 -74.6
Monensin + DMSA vs. DMSA +61.9 * +2.9 +515.8
Monensin + DMSA vs. +10.6 -33.6 +56.6
no treatment
* Statistically significant (p < 0.05).
Figure 14. (A) Fractional changes (+ SE) in tissue levels of Sr
occurring during treatment for Pb intoxication. For details, see
"Materials and Methods" and Table 1; values for the Pb-loaded group
were set to 1.0 to aid in normalizing values of other treatment
groups. (e) Percent changes in mean values calculated using
the same data shown in (A).
Tissue (percent change)
Comparison Kidney Liver Muscle
No treatment vs. loaded +162 * +31.5 -37.1
Monensin vs. no treatment +10.4 +1.7 +9.7
DMSA vs. no treatment +29.2 -9.7 -10.3
Monensin + DMSA vs. DMSA -31.9 * +13.5 +10.8
Monensin + DMSA vs. -12.0 +2.5 -0.6
no treatment
Tissue (percent change)
Comparison Heart Brain Femur
No treatment vs. loaded +136 * -15.0 +12.7
Monensin vs. no treatment +21.6 +17.1 -0.3
DMSA vs. no treatment +39.3 +35.6 +0.3
Monensin + DMSA vs. DMSA -49.3 * -12.6 +2.0
Monensin + DMSA vs. -29.4 +18.5 +2.3
no treatment
* Statistically significant (p < 0.05).
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