Bioequivalence decision for nanoparticular iron complex drugs for parenteral administration based on their disposition.

Although parenteral iron products have been established to medicinal use decades before, their structure and pharmacokinetic properties are not fully characterized yet. With its' second reflection paper on intravenous iron-based nano-colloidal products (EMA/CHMP/SWP/620008/2012) the European Medicine Agency provided an extensive catalogue of methods for quality, non-clinical and pharmacokinetic studies for the comparison of nano-sized iron products to an originator (EMA, 2015). For iron distribution studies, the reflection paper assumed the use of rodents. In our tests, we used a turkey fetus model to investigate time dependent tissue concentrations in pharmacological and toxicological relevant tissues liver, heart and kidney. We found turkey embryos to be a suitable alternative to rodents with high discriminatory sensitivity. Clear differences were found between equimolar doses of iron products with hydroxyethyl amylopectin, sucrose, dextrane and carboxymaltose shell. A linear dose dependency for the tissue accumulation was also demonstrated.

Comparative study of the oral absorption of microencapsulated ferric saccharate and ferrous sulfate in humans.

PURPOSE: Our objective was to compare the absorption of microencapsulated ferric saccharate (MFS) and ferrous sulfate (FS) in a fortified milk product, using a crossover design. METHODS: Seventeen non-iron-deficient healthy adults from both sexes participated in the study. On each intervention day (days 1 and 8), after an overnight fast, the volunteers consumed one type of product (test or control) and blood sampling was carried out at different times. The interventions days were separated by 7-day washout periods. This study was double blinded, crossover and randomized for nature of the test meals. The primary outcomes of the study were total serum iron and transferrin saturation. RESULTS: No significant differences could be observed in serum iron concentration during the 6-h postprandial study due to the type of milk product consumed, and there was neither an effect of time nor an interaction between the type of milk product and time. Transferrin saturation significantly increased after the intake of both products (P < 0.005), reaching a peak value between hours 2 and 4. No significant differences were detected between MFS and FS, indicating that iron absorption from MFS is equivalent to absorption from FS. CONCLUSIONS: MFS is a new ingredient that allows the fortification of a wide range of food products, including heat-processed and non-acidic products with similar absorption to FS, designed to produce neither organoleptic changes nor off-color development during storage of fortified food.

Nanoparticle iron medicinal products - Requirements for approval of intended copies of non-biological complex drugs (NBCD) and the importance of clinical comparative studies.

Currently, most countries apply the standard generic approach for the approval of intended copies of originator nanoparticle iron medicinal products, requiring only demonstration of bioequivalence to a reference medicinal product by bioavailability studies. However, growing evidence suggests that this regulatory approach is not appropriate. Clinical and non-clinical studies have shown that intended copy preparations of nanoparticle iron medicinal products can differ substantially from the originator product in their efficacy and potentially in their safety profile. An adapted regulatory pathway (separate from the standard generic approach) with defined data requirements is needed for approval of intended copies of iron medicinal products. Here, we discuss the difficulties involved in assessing therapeutic equivalence of nanoparticle iron medicinal products and suggest key concepts of a regulatory approach. Standardized non-clinical comparative studies are necessary but, as demonstrated in the reported clinical data, they may not be sufficient to demonstrate a comparable efficacy and safety profile. Validated, prospective, comparative clinical studies might be needed, in addition to non-clinical studies, in order to enable appropriate assessment of therapeutic equivalence. Furthermore, including brand names in addition to the International Non-proprietary Names (INNs) in safety reports could enable effective safety monitoring of intended copies and originator products.

Imaging of isoproterenol-induced myocardial injury with 18F labeled fluoroglucaric acid in a rat model.

Positron emission tomography (PET) of myocardial infarction (MI) by infarct avid imaging has the potential to reduce the time to diagnosis and improve diagnostic accuracy. The objective of this work was to synthesize 18F-labeled glucaric acid (FGA) for PET imaging of isoproterenol-induced cardiomyopathy in a rat model. METHODS: We synthesized 18F-FGA by controlled oxidation of 18F-fluorodeoxy glucose (FDG), mediated by 4-acetamido-2,2,6,6-tetramethylpiperidine 1-oxyl (TEMPO) in presence of NaBr and NaOCl in highly-buffered reaction conditions. After ascertaining preferential uptake of 18F-FGA in necrotic as compared to normal H9c2 myoblasts, the biodistribution and circulation kinetics of 18F-FGA was assessed in mice. Moreover, the potential of 18F-FGA to image myocardial damage was investigated in a rat model of isoproterenol-induced cardiomyopathy. Isoproterenol-induced myocardial injury was verified at necropsy by tissue staining and plasma cardiac troponin levels. RESULTS: Synthesis of radiochemically pure 18F-FGA was accomplished by a 5 min, one step oxidation of 18F-FDG. Reaction yield was quantitative and no side-products were detected. Biodistribution studies showed rapid elimination from the body (ke = 0.83 h-1); the major organ of 18F-FGA accumulation was kidney. In the rat model, isoproterenol-treatment resulted in significant increase in cardiac troponin. PET images showed that the hearts of isoproterenol-treated rats accumulated significant amounts of 18F-FGA, whereas healthy hearts showed negligible uptake of 18F-FGA. Target-to-nontarget contrast for 18F-FGA accumulation became significantly more pronounced in 4 h images as compared to images acquired 1 h post-injection. CONCLUSION: 18F-FGA can be easily and quantitatively synthesized from ubiquitously available 18F-FDG as a precursor. The resultant 18F-FGA has a potential to serve as an infarct-avid agent for PET imaging of MI. ADVANCES IN KNOWLEDGE AND IMPLICATIONS FOR PATIENT CARE: 18F-FGA/PET will complement existing perfusion imaging protocols in therapeutic decision making, determination of revascularization candidacy and success, differentiation of ischemia from necrosis in MI, discrimination of myocarditis from infarction, and surveillance of heart transplant rejection.

Complexity of intravenous iron nanoparticle formulations: implications for bioequivalence evaluation.

Intravenous iron formulations are a class of complex drugs that are commonly used to treat a wide variety of disease states associated with iron deficiency and anemia. Venofer® (iron-sucrose) is one of the most frequently used formulations, with more than 90% of dialysis patients in the United States receiving this formulation. Emerging data from global markets outside the United States, where many iron-sucrose similars or copies are available, have shown that these formulations may have safety and efficacy profiles that differ from the reference listed drug. This may be attributable to uncharacterized differences in physicochemical characteristics and/or differences in labile iron release. As bioequivalence evaluation guidance evolves, clinicians should be educated on these potential clinical issues before a switch to the generic formulation is made in the clinical setting.

Iron sucrose: assessing the similarity between the originator drug and its intended copies.

Iron sucrose (IS) is a complex nanocolloidal intravenous suspension used in the treatment of iron-deficiency anemia. Follow-on IS products (iron sucrose similars (ISSs)) have obtained marketing authorization by the generic pathway, implying that identical copies of IS may be manufactured. However, recent prospective and retrospective clinical studies showed discrepancies in clinical outcomes, which might be related to differences in physicochemical properties. The aim of this work is to measure and compare the physicochemical properties of IS and three ISSs available in the market using innovative analytical procedures. The comprehensive elucidation of size, size distribution, morphology, and stability of these complex drugs revealed very significant differences between the products. This study serves to provide the basis to define critical quality attributes that may be linked to differences in clinical outcome and thus may contribute to an adequate regulatory approach for IS and its follow-on products.

MRP-1 protein expression and glutathione content of in vitro tumor cell lines derived from human glioma carcinoma U-87-MG do not interact with 99mTc-glucarate uptake.

The main cause of the multidrug resistance (MDR) of glioma cells is the overexpression of MRP-1, often associated with high levels of glutathione (GSH). We investigated whether MRP-1-related GSH content can influence (99m)Tc-glucarate entry by comparing its uptake with that of (99m)Tc-sestamibi (MIBI), an MRP- 1 probe, in an in vitro model of a sensitive cell line (U-87-MG) and a resistant derived cell line expressing MRP-1 (U-87-MG-R). Drug resistance was assessed by immunoblotting, GSH measurement, and Alamar Blue assay. To correlate MDR phenotype with tracer accumulation, uptakes were performed with and without modulators and after GSH depletion. Similar accumulation of (99m)Tc-glucarate was observed in the two cell lines, and the use of MDR reversals did not enhance its uptake. Our results clearly demonstrate that (99m)Tc-glucarate uptake is not related to MRP-1 expression or GSH levels. In contrast, (99m)Tc- MIBI accumulation is inversely proportional to the cell MDR phenotype. The combination of (99m)Tc-glucarate and (99m)Tc-MIBI may be a useful tool for the noninvasive detection of malignant sites and their chemoresistance status.

Investigations of (99m)Tc-labeled glucarate as a SPECT radiotracer for non-small cell lung cancer (NSCLC) and potential tumor uptake mechanism.

This study attempted to evaluate the feasibility of (99m)Tc-labeled glucarate ((99m)Tc-GLA) imaging in non-small cell lung cancer (NSCLC) and the potential tumor uptake mechanism. Cell lysates from two NSCLC cell lines, H292 and H1975, were immunoblotted with anti-glucose transporter 5 (GLUT5) antibody for Western blotting. Thereafter, the two cell lines were used to examine cellular uptake of (99m)Tc-GLA with or without fructose. SPECT/CT imaging studies were performed on small animals bearing H292 and H1975 tumors. Biodistribution studies were also conducted to achieve accurate tissue uptake of this tracer in two tumor models. Hematoxylin & eosin (H&E) staining and GLUT5, Ki67 and cytokeratin-7 (CK-7) immunohistochemistry (IHC) analysis were further investigated on tumor tissues. In Western blotting, H292 cells showed higher levels of GLUT5 compared to the H1975 cells. Meanwhile, the in vitro cell assays indicated GLUT5-dependent uptake of (99m)Tc-GLA in H292 and H1975 cells. The fructose competition assays showed a significant decrease in (99m)Tc-GLA uptake by H292 and H1975 cells when fructose was added. The (99m)Tc-GLA accumulation was as much as two-fold higher in H292 implanted tumors than in H1975 implanted tumors. (99m)Tc-GLA exhibited rapid clearance pharmacokinetics and reasonable uptake in human NSCLC H292 (1.69±0.37 ID%/g) and H1975 (0.89±0.06 ID%/g) implanted tumors at 30min post injection. Finally, the expression of GLUT5, Ki67 and CK-7 on tumor tissues also exhibited positive correlation with the in vitro cell test results and in vivo SPECT/CT imaging results in xenograft tumors. Both in vitro and ex vivo studies demonstrated that the uptake of (99m)Tc-GLA in NSCLC is highly related to GLUT5 expression. Imaging and further IHC results support that (99m)Tc-GLA could be a promising SPECT imaging agent for NSCLC diagnosis and prognosis evaluation.

Distribution of deoxyglucose and technetium-99m-glucarate in the acutely ischemic myocardium.

The regional myocardial distribution of 99mTc-glucarate was compared to 3H-deoxyglucose in 22 rabbits with left circumflex marginal artery occlusion. In 12 rabbits, tissue radioactivity measurements were compared to the results of triphenyl tetrazolium chloride staining and light microscopy. In 10 additional rabbits, the myocardial sodium space (24NaCl), an indicator of tissue edema induced by injury, was compared to the distribution of deoxyglucose and glucarate. Technetium-99m-glucarate accumulated in injured myocardium within 6 hr after coronary ligation and myocardial concentration was greatest in the most severely injured zones (TTC unstained). Hydrogen-3-deoxyglucose behaved as a marker of ischemia but concentrated in tissue with injury ranging from mild ischemia (TTC stained) to transmural infarction (TTC unstained). Both 99mTc-glucarate and 3H-deoxyglucose concentrated in acute, severely injured myocardial tissue. These studies suggest that 99mTc-glucarate is a useful tracer for evaluating myocardial injury. In addition, it appears that 99mTc-glucarate and 3H-deoxyglucose demarcate different points in the spectrum of myocardial injury.

Effect of hypoxia on the accumulation of technetium-99m-glucarate and technetium-99m-gluconate by Chinese hamster ovary cells in vitro.

The accumulation of 99mTc-glucarate, an agent recently reported to localize in acutely infarcted myocardium, zones of acute cerebral injury and tumors, has been compared with 99mTc-gluconate in an in vitro system of cultured Chinese hamster ovary fibroblasts. The effects on accumulation of hypoxia and competition with fructose have been studied. Both labeled glucose analogs showed a two- to threefold enhanced accumulation in hypoxic cells relative to aerobic cells. No such enhanced accumulation under hypoxia was observed for the nonsugar tracers pertechnetate and 99mTc-DTPA. The presence of 20 mM fructose reduced the accumulation of 99mTc-glucarate by 30% (p = 0.067) and 99mTc-gluconate by 40% (p < 0.05) in hypoxic cells, but had no significant effect in aerobic cells. These results suggest that both compounds at least partially share a common mechanism of uptake and/or accumulation with fructose.

Early scintigraphic detection of experimental myocardial infarction in dogs with technetium-99m-glucaric acid.

Recent data have generated some interest in technetium-99m-(99mTc) glucaric acid as an in vivo viability marker. We studied 99mTc-glucaric acid retention in canine models of myocardial ischemia (20-min occlusion of the LAD/40-min reperfusion), acute myocardial infarction (MI) (90-min LAD occlusion/3-hr reperfusion), and chronic MI (90-min occlusion and either 48-hr or 10-day reperfusion). Regional myocardial blood flow was measured by radiolabeled microspheres. No preferential uptake of glucaric acid was observed in ischemic but viable myocardium. The compound showed high affinity for necrotic myocardial tissue for several days following injury. The preferential uptake in infarcted tissue disappeared by 10 days following injury. This study shows that 99mTc-glucaric acid acts exclusively as a marker of necrosis in canine models of MI. Technetium-99m-glucaric acid may have clinical utility in early cardiac imaging of myocardial infarction and in differentiating recent from old injuries.

Early detection of infarct in reperfused canine myocardium using 99mTc-glucarate.

UNLABELLED: 99mTc-Glucarate is an infarct-avid imaging agent with the potential for very early detection of myocardial infarction. The purposes of this study using a canine model were to determine (a) the time course of (99m)Tc-glucarate uptake and clearance from necrotic and normal myocardium; (b) the (99m)Tc-glucarate necrotic-to-normal activity ratio over time; (c) the time course of detectable scan positivity after intravenous administration of the tracer; and (d) the relationship of infarct size determined by triphenyltetrazolium chloride (TTC) staining versus (99m)Tc-glucarate imaging ex vivo. METHODS: A 90-min left circumflex coronary artery (LCx) occlusion was followed by 270 min of reperfusion at 100% baseline flow in 6 open-chest, anesthetized dogs. (99m)Tc-Glucarate (555 MBq [15 mCi]) was injected 30 min after reperfusion and was followed by 240 min of gamma-camera serial imaging. Microspheres were injected during baseline, occlusion, tracer injection, and before the dogs were euthanized. Creatine kinase assays were performed to assess developing injury. Ex vivo gamma-camera imaging was performed. Blood flow and tracer activity were determined by well counting. TTC stain was used to mark infarct areas, which were sized using computerized digital planimetry. RESULTS: Hemodynamics demonstrated no significant change from baseline at any time for any parameter except LCx flow, which was significantly depressed during occlusion. The mean infarct size +/- SEM was 10.7% +/- 2% of total left ventricle. Blood (99m)Tc-glucarate clearance was triexponential and rapid. Qualitative image analysis revealed a well defined hot spot after 30 min, which remained well defined through 240 min after injection (150 and 360 min after occlusion, respectively). Images were quantitatively abnormal with hot spot-to-normal zone activity ratios of >/=2:1 within 10 min of tracer administration (130 min after occlusion), reaching 8:1 at 240 min after tracer administration (360 min after occlusion). There was a linear correlation between infarct size determined by (99m)Tc-glucarate and TTC staining (r = 0.96; slope = 0.87). CONCLUSION: (99m)Tc-Glucarate marks acute myocardial infarct very early after occlusion and appears to accurately assess infarct size when compared with TTC staining.

Localization of technetium-99m-glucarate in zones of acute cerebral injury.

The potential structural similarity of technetium-99m-labeled glucaric acid (99mTc-glucarate) to that of fructose suggests that this agent may enter cells by a sugar transport system. Studies with LLC-PK1 cells demonstrated inhibition of 99mTc-glucarate uptake by fructose, confirming this potential relationship. Since anaerobic metabolism can use either glucose or fructose, we hypothesized that 99mTc-glucarate may concentrate in areas of acute ischemic injury. To test this hypothesis, 63 adult rats with middle cerebral artery (MCA) occlusion followed by reperfusion were injected with 99mTc-glucarate and in vivo and ex vivo images were acquired. Seven animals were also studied with 18FDG and high resolution PET imaging. The radionuclide images were compared to the results of triphenyl tetrazolium chloride (TTC) staining and conventional histopathology. Thirty-five rats had significant accumulation of 99mTc-glucarate and no TTC staining (indicating infarction) in the involved hemisphere. Of the remaining 28 rats with TTC staining (suggesting viability) of the involved hemisphere, 16 (57%) had 99mTc-glucarate accumulation. In the seven rats that were studied with both 99mTc-glucarate and 18FDG, 99mTc-glucarate accumulated at the center of the occluded MCA territory while 18FDG activity was decreased in this region. These results suggest that 99mTc-glucarate is a sensitive marker of acute severe cerebral injury, but its mechanism of localization is probably different from that of 18FDG.

Pharmacokinetics relevant to the anti-carcinogenic and anti-tumor activities of glucarate and the synergistic combination of glucarate:retinoid in the rat.

Alone and in synergistic combination with retinoids, dietary glucarate inhibits both the chemical induction and growth of rat mammary tumors. To investigate the pharmacokinetics of glucarate, [14C]glucarate was synthesized, converted to the calcium salt, and administered to rats bearing primary mammary tumors. When given by gavage, [14C]glucarate, as the calcium salt, showed a biphasic response in the blood. After peaking within 1 hr of administration at a level of 0.4 mumol/mL (normal endogenous level is approximately 0.04 mumol/mL), its plasma concentration dropped to 0.1 mumol/mL at 3 hr. In the second phase, there was a semilog increase to 0.6 mumol/mL at 15 hr, followed by a slow rise to 0.75 mumol/mL at 24 hr. Of the 38% of the administered glucarate that was recovered, 38% was excreted in the urine, and 30% remained in the gastrointestinal tract at 24 hr. Glucarate was concentrated 3- to 4-fold in the liver and intestinal mucosa, compared to the level in serum. With minor exception, the pharmacokinetics of [14C]13-cis-retinoic acid administered by gavage to rats was similar or not the semipurified diets were supplemented with 64 mmol/kg of calcium glucarate. During the interval between 5 and 10 hr post-administration of [14C]13-cis-retinoid, there was a transient 35-50% rise in the plasma level in rats on the glucarate-supplemented diet. This rise had no observable effect on the level of retinoid in major organs or in the tumor. A glucarate-binding protein was detected in the tumor cytosol. This potential receptor had a Ka of 1.49 x 10(7) M-1.

Inhibition of liver metastases and tumor cell invasion in spontaneous liver metastasis model (LMFS) by sodium D-glucaro-delta-lactam (ND2001).

We examined the inhibitory effect of sodium D-glucaro-delta-lactam (sodium 5-amino-5-deoxy-D-glucosaccharic acid-delta-lactam: ND2001) upon liver metastases of the LMFS tumor. A permanent cell line, LMFS, was established from a spontaneously occurring murine retroperitoneal tumor of BALB/c mouse origin, and after a subcutaneous injection, the LMFS cells proliferated at the inoculation site (100% take) with liver metastases. ND2001 had little effect on the cell growth, cell cycle and phagokinesis of the LMFS cells in vitro. However, when the invasive activity was measured by the Boydem chamber method, the number of LMFS cells was reduced, with inhibition rates of 98.0%. After the LMFS cells treated with ND2001 in vitro, the numbers of hepatic metastases of subcutaneous inoculation of treated cells were reduced dose-dependently, and those of intravenous inoculation were not found by microscopical study. When the LMFS tumor-bearing mice were treated with ND2001 (0, 30, 100 mg/kg/d) from day 1, ND2001 (30 mg/kg) inhibited the liver metastases with a rate of 56.4%, and when given from day 15, ND2001 (100 mg/kg) inhibited with a rate of 47.5%. But ND2001 showed neither cytocidal nor anti-tumor activity. Combination therapy of primary tumor resection and ND2001 administration revealed that preoperative use of ND2001 was more effective in preventing liver metastases. These results suggested that ND2001 might have a potential use as an anti-metastatic agent for operative patients without metastasis.

99mTc-glucarate for detection of isoproterenol-induced myocardial infarction in rats.

Infarct-avid radiopharmaceuticals are necessary for rapid and timely diagnosis of acute myocardial infarction. The animal model used to produce infarction implies artery ligation but chemical induction can be easily obtained with isoproterenol. A new infarct-avid radiopharmaceutical based on glucaric acid was prepared in the hospital radiopharmacy of the INCMNSZ. 99mTc-glucarate was easy to prepare, stable for 96 h and was used to study its biodistribution in rats with isoproterenol-induced acute myocardial infarction. Histological studies demonstrated that the rats developed an infarct 18 h after isoproterenol administration. The rat biodistribution studies showed a rapid blood clearance via the kidneys. Thirty minutes after 99mTc-glucarate administration the standardised heart uptake value S(h)UV was 4.7 in infarcted rat heart which is six times more than in normal rats. ROIs drawn over the gamma camera images showed a ratio of 4.4. The high image quality suggests that high contrast images can be obtained in humans and the 96 h stability makes it an ideal agent to detect, in patients, early cardiac infarction.

Targeting human breast tumour in xeno-grafted SCID mice with 99Tcm-glucarate.

99Tcm-glucarate accumulation in human mammary BT-20 tumours hosted in severe combined immune deficiency (SCID) mice was compared to 111In-monoclonal antibody 103D2-F(ab')2, 99Tcm-methoxyisobutyl isonitrile (99Tcm-MIBI) and 99Tcm-diethylenetriamine pentaacetate (99Tcm-DTPA). The intracellular tumour distribution of 99Tcm-glucarate was also determined. SCID mice injected with a mixture of 99Tcm-glucarate and 111In-103D2-F(ab')2 were imaged serially up until 24 h. Computer planimetered tumour-to-blood activity (in the heart) ratios (T/BH) to 8 h were significantly greater for 99Tcm-glucarate than 111In-103D2. The mean (+/-S.D.) tumour-to-blood ratio (T/B) from biodistribution was 1.21 +/- 0.31 and 0.35 +/- 0.06 (P < 0.0001) at 5 h, and 1.526 +/- 0.29 and 0.75 +/- 0.2 (P < 0.0001) at 8 h, for 99Tcm-glucarate and 111In-103D2 respectively. At 24 h, T/B for 111In-103D2 (1.76 +/- 0.22) exceeded that of 99Tcm-glucarate (1.44 +/- 0.2, P = 0.01). 99Tcm-glucarate uptake in the tumours at 5 h (1.133 +/- 0.25 %ID g-1) and 8 h (1.213 +/- 0.23 %ID g-1) was significantly greater than that of 99Tcm-MIBI (0.340 +/- 0.09, P = 0.0002; 0.220 +/- 0.04, P = 0.0001) and 99Tcm-DTPA (0.091 +/- 0.03, P < 0.0002; 0.016 +/- 0.01, P < 0.0001) respectively. Intracellular tumour distribution of 99Tcm-glucarate was 50.91 +/- 6.55% in the nuclear fraction, 34.34 +/- 2.88% in the cytoplasmic fraction and 14.75 +/- 7.66% in the mitochondrial fraction. Thus glucarate may provide a 99Tcm-based mammary tumour imaging modality for visualization of tumours very quickly after tracer administration with maximal targeting in the nuclei of the tumour cells.

Accumulation of technetium-99m glucarate: in vitro cell cultures and in vivo tumour models.

99mTc-glucarate is an investigational radiopharmaceutical which has been shown to accumulate in acute cerebral and myocardial injuries and in some tumours. In the present work, a survey of possible factors affecting the cellular accumulation of 99mTc-glucarate was carried out in cell lines and strains in vitro and in murine tumours in vivo. Accumulation was enhanced under hypoxic conditions in 12 of the 16 human and murine cell lines and strains studied, and inhibited in the presence of nitroimidazoles. At temperatures lower than 37 degrees C, accumulation was reduced, but a hypoxic/aerobic differential was maintained. Aerobic accumulation of 99mTc-glucarate was enhanced by cyanide. In transplanted tumours in mice, 99mTc-glucarate showed high tumour/muscle and tumour/blood ratios at early times after injection. Pharmacological enhancement of the extent of hypoxia by the administration of hydralazine or nitro-L-arginine resulted in significantly increased accumulation of 99mTc-glucarate in the tumour. The in vitro and in vivo properties of 99mTc-glucarate suggest that it may be useful for tumour imaging in the clinic, although the exact mechanism(s) by which it localizes in tumours remains unknown.

99mTc glucarate high-resolution imaging of drug sensitive and drug resistant human breast cancer xenografts in SCID mice.

BACKGROUND AND AIM: Previous studies have showed that 99mTc labelled glucarate (GLA) might be an agent for non-invasive detection of breast tumours. In xenografted BT20 breast tumours, GLA was found to have higher uptake than 99mTc sestamibi (MIBI). It is unclear whether GLA can localize in all cell line breast cancer xenografts, as well as breast tumours with multidrug resistance (MDR). The present study aimed to investigate the properties of GLA in detecting drug sensitive and drug resistant MCF7 breast cancer xenografts in mice by using dynamic single photon emission computed tomography (SPECT) imaging. METHODS: MCF7/S cells are drug sensitive breast carcinoma cells. MCF7/D40 cells are 40-fold more resistant to doxorubicin compared to MCF7/S. Subcutaneous tumours were grown in SCID mice for 10-14 days after injection of 1 x 10(6) cells into the right thigh. Anaesthetized mice with MCF7/S (MIBI, n=9; GLA, n=8) and MCF7/D40 (MIBI, n=6; GLA, n=5) tumours were imaged using a high-resolution SPECT system called FASTSPECT. Dynamic images were acquired for 2 h after intravenous injection of GLA or MIBI. Expression of MDR P-glycoprotein (Pgp) in the tumours was demonstrated in the MCF7/D40 tumours by western blotting, not in the MCF7/S tumours. RESULTS: The xenografted tumours were visualized unequivocally within 10-30 min in GLA images and remained detectable for at least 2 h after injection. Drug resistant tumours, from which MIBI was rapidly expelled, retained GLA as readily as did drug sensitive tumours. The biodistribution data of GLA demonstrated significantly higher accumulation (%ID/g) compared to MIBI. CONCLUSION: MCF7 tumour xenografts can be detected by 99mTc glucarate imaging. More importantly, 99mTc glucarate can potentially localize drug resistant breast tumours.

Hydroxyurea could be a good clinically relevant iron chelator.

Our previous study showed a reduction in serum ferritin of ß-thalassemia patients on hydroxyurea therapy. Here we aimed to evaluate the efficacy of hydroxyurea alone and in combination with most widely used iron chelators like deferiprone and deferasirox for reducing iron from experimentally iron overloaded mice. 70 BALB/c mice received intraperitonial injections of iron-sucrose. The mice were then divided into 8 groups and were orally given hydroxyurea, deferiprone or deferasirox alone and their combinations for 4 months. CBC, serum-ferritin, TBARS, sTfr and hepcidin were evaluated before and after iron overload and subsequently after 4 months of drug therapy. All animals were then killed. Iron staining of the heart and liver tissue was done using Perl's Prussian Blue stain. Dry weight of iron in the heart and liver was determined by atomic absorption spectrometry. Increased serum-ferritin, TBARS, hepcidin and dry weight of iron in the liver and heart showed a significant reduction in groups treated with iron chelators with maximum reduction in the group treated with a combination of deferiprone, deferasirox and hydroxyurea. Thus hydroxyurea proves its role in reducing iron from iron overloaded mice. The iron chelating effect of these drugs can also be increased if given in combination.