Enhanced Tumour Uptake of Doxorubicin Loaded Poly(butyl cyanoacrylate) Nanoparticles in Mice Bearing Dalton's Lymphoma Tumour

The objective of this study is to enhance the delivery of Doxorubicin hydrochloride to Dalton's lymphoma solid tumour through poly(butyl cyanoacrylate) (PBC) nanoparticles. Doxorubicin loaded PBC (DPBC) nanoparticles were prepared by emulsion polymerization and characterized by particle size analysis, zeta potential and scanning electron microscopy. Doxorubicin HCl (Dox) and DPBC nanoparticles were radiolabeled with ^99mTc by reduction method using stannous chloride and optimized the labeling parameters to obtain high labeling efficiency. The in vitro stability of ^99mTc-labeled complexes was determined by DTPA and cysteine challenge test. The labeled complexes showed very low transchelation and high in vitro and serum stability. ^99mTc labeled complexes of Dox and DPBC nanoparticles were administered subcutaneously below the Dalton's lymphoma tumour and biodistribution was studied. The distribution of DPBC nanoparticles to the blood, heart and organs of RES such as liver, lung and spleen was biphasic with a rapid initial distribution, followed by a significant decrease later at 6 h post-injection. The distribution of Dox to tissues was very low initially and increased significantly at 6 h post-injection indicating its accumulation at the injection site for a longer time. The concentration of DPBC nanoparticles was also found high in tissues at 6 h post-injection indicating their accumulation at the subcutaneous site and consequent disposition to tissues with time. A significantly high tumour uptake of DPBC nanoparticles (～13 fold higher at 48 h post-injection) (P <0.001) was found compared to free Dox. The tumour concentrations of both Dox and DPBC nanoparticles increased with time indicating their slow penetration from the injection site into tumour. The concentration of DPBC nanoparticles in the femur bone in the tumour region was also significantly higher (P <0.001) than free Dox and increased with time. The study signifies the advantage of delivering Dox to Dalton's lymphoma through PBC nanoparticles by facilitating enhanced tumour uptake and prolonged tumour retention, which are expected to lead to greater therapeutic effect in the form of tumour regression.     

多柔比星纳米递药系统在三阴性乳腺癌靶向治疗中的应用

三阴性乳腺癌为高度恶性肿瘤。多柔比星是三阴性乳腺癌的常规化疗药物,该药药理作用是通过嵌入DNA碱基对之间,干扰基因转录,抑制mRNA和DNA合成。常规给药方式对正常组织损伤严重。多柔比星纳米递药系统借助肿瘤酸性微环境实现缓控释效应,多柔比星与肿瘤细胞的组织相容性增加,对正常组织影响较小。该系统有效抑制和杀灭肿瘤细胞,明显减轻正常细胞的细胞毒性。本文综述了近年来多柔比星靶向纳米递药系统的应用,以期开拓三阴性乳腺癌的的靶向治疗新视野。     

siRNAs targeting multidrug transporter genes sensitise breast tumour to doxorubicin in a syngeneic mouse model

Abstract

Chemotherapy, the commonly favoured approach to treat cancer is frequently associated with treatment failure and recurrence of disease as a result of development of multidrug resistance (MDR) with concomitant over-expression of drug efflux proteins on cancer cells. One of the most widely used drugs, doxorubicin (Dox) is a substrate of three different ATP-binding cassette (ABC) transporters, namely, ABCB1, ABCG2 and ABCC1, predominantly contributing to MDR phenotype in cancer. To silence these transporter-coding genes and thus enhance the therapeutic efficacy of Dox, pH-sensitive carbonate apatite (CA) nanoparticles (NPs) were employed as a carrier system to co-deliver siRNAs against these genes and Dox in breast cancer cells and in a syngeneic breast cancer mouse model. siRNAs and Dox were complexed with NPs by incubation at 37?°C and used to treat cancer cell lines to check cell viability and caspase-mediated signal. 4T1 cells-induced breast cancer mouse model was used for treatment with the complex to confirm their action in tumour regression. Smaller (～200?nm) and less polydisperse NPs that were taken up more effectively by tumour tissue could enhance Dox chemosensitivity, significantly reducing the tumour size in a very low dose of Dox (0.34?mg/kg), in contrast to the limited effect observed in breast cancer cell lines. The study thus proposes that simultaneous delivery of siRNAs against transporter genes and Dox with the help of CA NPs could be a potential therapeutic intervention in effectively treating MDR breast cancer.     

Activity of Doxorubicin Covalently Bound to a Novel Human Serum Albumin Microcapsule

Doxorubicin is widely used in the treatment of human malignancies, however is associated with significant cardiac, bone marrow and gastro-intestinal toxicity. Delivery systems may ameliorate this toxicity and increase treatment specificity by increasing the proportion of drug delivered to sites of disease. We have developed a novel preparation of doxorubicin (Dox) covalently linked to a heat stabilised human serum albumin microparticle (HSAM) carrier (median particle diameter of 4 m) and assessed its activity in 4 malignant cell lines.Materials and methods. Doxorubicin microcapsules were compared with free doxorubicin in the rat carcinoma cell line, WRC256, and the human lines, OVCAR3, MCF7 and the Dox resistant MCF7/Dox, using a cell counting technique. IC50 were calculated from regression analysis of the resulting survival curves. Endocytosis of the microcapsules by cells in culture was observed. The rate of microcapsule uptake was assessed using dual wavelength filtered fluorescence microscopy and flow cytometry.Results. The mean IC50 following incubation with the Dox microcapsules was around 5 times greater than Dox for WRC256 (p < 0.001), MCF7 (p < 0.01) and for OVCAR3 (p < 0.01). MCF7/Dox was significantly more sensitive to Dox microcapsules than free Dox (p = 0.034). A negative correlation between the rate of microcapsule uptake and the IC50 values for each cell line in culture exists (r = –0.96, p = 0.04).Conclusions. We conclude that: 1) Doxorubicin microcapsules retain activity in vitro and appear to overcome p-glycoprotein mediated Dox resistance. 2) The observed activity of Dox microcapsules correlates with the rate of particle uptake. Further studies in animal tumour models are in progress.     

Somatostatin receptor-binding peptides suitable for tumor radiotherapy with Re-188 or Re-186. Chemistry and initial biological studies

Somatostatin derivative peptides previously designed for radiodiagnostic purposes (99mTc P829 or 99mTc depreotide) were reoptimized for radiotherapy of tumors with rhenium radioisotopes. An optimized pharmacophore peptide P1839 was derived by in vitro binding affinity assay to AR42J rat pancreatic tumor cell membranes. Peptides with chelating domains and their oxorhenium(V) complexes were tested in vitro for binding to NCI H69 human SCLC tumor membranes. Further optimization entailed radiolabeling with 99mTc and biodistribution in an AR42J xenograft mouse model. Kidney uptake was decreased substantially by removing positively charged residues. Neutral N3S diamide amine thiol chelators with no adjacent positive charges had the best overall properties. Substituting an aromatic amino acid into the chelator approximately doubled the tumor uptake. The final optimized peptide P2045 (39) radiolabeled with 99mTc exhibited increased tumor uptake ( approximately 25 %ID/g at 1.5 h), lower kidney uptake ( approximately 4.8 %ID/g at 1.5 h), and extensive urinary excretion (59 %ID at 1.5 h). Finally, comparison biodistribution studies between 99mTc and 188Re (39) showed a good correlation between the two metal complexes and demonstrated prolonged tumor retention (> or =24 h).     

Etoposide-incorporated tripalmitin nanoparticles with different surface charge: Formulation, characterization, radiolabeling, and biodistribution studies

Etoposide-incorporated tripalmitin nanoparticles with negative (ETN) and positive charge (ETP) were prepared by melt emulsification and high-pressure homogenization techniques. Spray drying of nanoparticles led to free flowing powder with excellent redispersibility. The nanoparticles were characterized by size analysis, zeta potential measurements, and scanning electron microscopy. The mean diameter of ETN and ETP nanoparticles was 391 nm and 362 nm, respectively, and the entrapment efficiency was more than 96%. Radiolabeling of etoposide and nanoparticles was performed with Technetium-99m (99mTc) with high labeling efficiency and in vitro stability. The determination of binding affinity of 99mTc-labeled complexes by diethylene triamine penta acetic acid (DTPA) and cysteine challenge test confirmed low transchelation of 99mTc-labeled complexes and high in vitro stability. Pharmacokinetic data of radiolabeled etoposide, ETN, and ETP nanoparticles in rats reveal that positively charged nanoparticles had high blood concentrations and prolonged blood residence time. Biodistribution studies of 99mTc-labeled complexes were performed after intravenous administration in mice. Both ETN and ETP nanoparticles showed significantly lower uptake by organs of the reticuloendothelial system such as liver and spleen (P < .001) compared with etoposide. The ETP nanoparticles showed a relatively high distribution to bone and brain (14-fold higher than etoposide and ETN at 4 hours postinjection) than ETN nanoparticles. The ETP nanoparticles with long circulating property could be a beneficial delivery system for targeting to tumors by Enhanced Permeability and Retention effect and to brain.     

New conformationally restricted 99mTc N2S2 complexes as myocardial perfusion imaging agents.

In developing 99mTc complexes as potential myocardial imaging agents, a new series of ligands based on a conformationally restricted N2S2 system were investigated. Using piperazine or homopiperazine as the starting material, two N2S2 ligands (4a and 4b) with additional conformation restriction between the two nitrogen donor atoms were synthesized. The 99mTc complexes were prepared by a direct labeling method with tin(II) tartrate as the reducing agent for [99mTc]pertechnetate. The resulting 99mTc complexes were purified through a sulfonpropyl Sephadex column and further purified by HPLC with a reverse-phase column eluting with a solvent system of acetonitrile/buffer. Biodistribution studies in rats showed initial uptake in the heart (0.21%, 0.42% dose/order for [99mTc]4a and 4b at 2 min postinjection). Carrier-added preparation of [99mTc]4b was successful. NMR, IR, UV, crystallographic, and elemental analysis of the [99Tc]4b complex suggest that it contains a TcVO3+ center core and is 1+ charged. The results suggest that this series of 1+ charged 99mTc complexes may have potential as myocardial imaging agents, and further study of the complexes is warranted.     

基于钙离子驱动的药物负载构建光响应性介孔硅纳米粒的研究

目的 提高介孔硅纳米粒(mesoporous silicon nanoparticles,MSNs)中药物负载量,并使其具备光响应性等功能。方法 本研究采用模板法制备氨基化的介孔硅纳米粒(MSN-NH₂),并通过钙离子负载的MSNs(MSN-Ca)诱导化疗药物阿霉素(Doxorubicin,Dox)及光热治疗药物Cypate、二氢卟吩e6(Ce6)的高效负载,制得光响应性载单药或多药的MSNs,并对其理化性质及释药特性进行研究。结果 钙离子可有效负载于MSNs内,并可以诱导Dox、Cypate、Ce6在MSNs孔道内的高效负载,其载药量可分别达到(28.5±1.4)%,(36.8±1.5)%,(36.6±1.7)%;MSN-Ca还可以实现Dox、Cypate、Ce6中的2种或3种药物共同负载。负载Cypate的MSNs具有良好的光热升温效果。载Dox的MSNs具有酸性pH响应性释放Dox的特点。785 nm激光照射可明显增强MSN-Ca-Dox/Cypate的Dox释放,具有光响应性释药的特点。结论 钙离子驱动的药物负载策略在多功能MSNs的构建及其抗肿瘤协同治疗研究中具有重要作用。     

Improved cytotoxicity and preserved level of cell death induced in colon cancer cells by doxorubicin after its conjugation with iron-oxide magnetic nanoparticles

A promising strategy for overcoming the problem of limited efficacy in antitumor drug delivery and in drug release is the use of a nanoparticle-conjugated drug. Doxorubicin (Dox) anticancer chemotherapeutics has been widely studied in this respect, because of severe cardiotoxic side effects. Here, we investigated the cytotoxic effects, the uptake process, the changes in cell cycle progression and the cell death processes in the presence of iron-oxide magnetic nanoparticles (Nps) and doxorubicin conjugates (Dox-Nps) in human colon HT29 cells. The amount of Dox participated in biological action of Dox-Nps was determined by cyclic voltammetry and thermogravimetric measurements. The cytotoxicity of Dox-Nps was shown to be two/three times higher than free Dox, whereas Nps alone did not inhibit cell proliferation. Dox-Nps penetrated cancer cells with higher efficacy than free Dox, what could be a consequence of Dox-Nps aggregation with proteins in culture medium and/or with cell surface. The treatment of HT29 cells with Dox-Nps and Dox at IC₅₀ concentration resulted in G2/M arrest followed by late apoptosis and necrosis. Summing up, the application of iron-oxide magnetic nanoparticles improved Dox-Nps cell penetration compared to free Dox and achieved the cellular response to Dox-Nps conjugates similar to that of Dox alone.     

Glutathione-mediated metabolism of technetium-99m SNS/S mixed ligand complexes: a proposed mechanism of brain retention

Two series of [99mTc](SNS/S) mixed ligand complexes each carrying the N-diethylaminoethyl or the N-ethyl-substituted bis(2-mercaptoethyl)amine ligand (SNS) are produced at tracer level using tin chloride as reductant and glucoheptonate as transfer ligand. The identity of [99mTc](SNS/S) complexes is established by high-performance liquid chromatographic (HPLC) comparison with authentic rhenium samples. The para substituent R on the phenylthiolate coligand (S) ranges from electron-donating (-NH2) to electron-withdrawing (-NO2) groups, to study complex stability against nucleophiles as a result of N- and R-substitution. The relative resistance of [99mTc](SNS/S) complexes against nucleophilic attack of glutathione (GSH), a native nucleophilic thiol of 2 mM intracerebral concentration, is investigated in vitro by HPLC. The reaction of [99mTc](SNS/S) complexes with GSH is reversible and advances via substitution of the monothiolate ligand by GS- and concomitant formation of the hydrophilic [99mTc](SNS/GS) daughter compound. The N-diethylaminoethyl complexes are found to be more reactive against GSH as compared to the N-ethyl ones. Complex reactivity as a result of R-substitution follows the sequence -NO2 > -H > -NH2. These in vitro findings correlate well with in vivo distribution data in mice. Thus, brain retention parallels complex susceptibility to GSH attack. Furthermore, isolation of the hydrophilic [99mTc](SNS/GS) metabolite from biological fluids and brain homogenates provides additional evidence that the brain retention mechanism of [99mTc](SNS/S) complexes is GSH-mediated.     

99mTc]oxotechnetium(V) complexes amine-amide-dithiol chelates with dialkylaminoalkyl substituents as potential diagnostic probes for malignant melanoma.

[99mTc]oxotechnetium(V) complexes of amine-amide-dithiol (AADT) chelates containing tertiary amine substituents were synthesized and shown to have affinity for melanoma. For complexation the AADT-CH2[CH2]nNR2 (n = 1, 2; R = Et, n-Bu) ligand was mixed with a [99mTc]oxotechnetium(V)-glucoheptonate precursor to make the AADT-[99mTc]oxotechnetium(V) complexes in nearly quantitative yield. Structurally analogous nonradioactive oxorhenium(V) complexes were also synthesized and characterized. In vitro sigma-receptor affinity measurements indicate these complexes to possess sigma-affinity in the low micromolar range with K(i) values in the 7.8-26.1 and 0.18-2.3 microM range for the sigma1- and sigma2-receptors, respectively. In vitro cell uptake of the 99mTc complexes in intact B16 murine melanoma cells at 37 degrees C after a 60-min incubation ranged from 12% for complex 2 (n = 1, R = n-Bu) to 68% for complex 4 (n = 2, R = n-Bu). In vivo evaluation of complexes 1-Tc-4-Tc in the C57Bl/B16 mouse melanoma model demonstrated significant tumor localization. Complex 1-Tc (n = 1, R = Et) displayed an in vivo tumor uptake of 7.6% ID/g at 1 h after administration with initial melanoma/blood (M/B), melanoma/spleen (M/S), and melanoma/lung (M/L) ratios >4; these ratios increased to 10.8, 10.1, and 7.3, respectively, at 6 h. While complex 3-Tc (n = 3, R = Et) had an initial tumor uptake of 3.7% ID/g 1 h after administration with M/B, M/S, and M/L ratios >2, a greater tumor retention and slightly faster clearance from nontumor-containing organs resulted in M/B, M/S, and M/L ratios of 19.1, 19.1, and 12.7, respectively, at 6 h. The high tumor uptake and significant tumor/nontumor ratios indicate that such small technetium-99m-based molecular probes can be developed as in vivo diagnostic agents for melanoma and its metastases.     

五价锝标记化合物在缺血性心肌中的摄取与其离解性

目的：研究在机体内具有一定的稳定性而又能离解出可达靶组织的活性形式ＴｃＯ４＾３－的多核锝标记化合物。方法：模仿锝标记化合物进入血循环后的状况，采用稀释的方法，用硅胶板薄层层析法来测量其离解能力的大小。结果：５００倍稀释液的离解物峰的相对放射性百分数为：＾９９ｍＴｃ＾５＋－ｓｕｃｃｉｍｅｒ为０，＾９９ｍＴｃ＾５＋ＧＨ为２８．１％±１．３％，＾９９ｍＴｃ％５＋－ＰＰｉ为４６．０％±２．９％，而缺血３ｈ     

Accumulation of radiolabelled low molecular peptides and proteins in experimental inflammation

This study focuses on evaluating accumulation of the low molecular peptides and proteins labelled with 99mTc in rat inflammatory/infection foci. Peptides (human leukocyte dialysate, HLD; thymosin fraction 5, TF5; aprotinin, APT), and proteins (human IgG, HIG) were labelled with 99mTc using redox polymer. The labelling efficiency was evaluated using paper, TLC and/or column chromatography. Biodistribution of labelled substances was evaluated in rats with Staphylococcus aureus infection or with sterile kaolin suspension inflammation 24 h after abscess induction. Accumulation of 99mTc activity was determinated both by external gamma camera imaging and by counting dissected tissues 4 h after administration. The evaluated peptides and proteins show high labelling efficiency (99mTc-HLD>98%, 99mTc-TF5>95%, 99mTc-APT>98%, 99mTc-HIG>95%). Usage of redox polymer for labelling increases the stability of 99mTc-labelled substances. The labelling efficiency stays nearly the same (95-98%) after 8 h at least. In experimentally induced inflammation the amount of 99mTc-peptides and 99mTc-HIG activity accumulated is 2.5-6.5 and 5.3-10.6 times higher than in a control tissue. When comparing two types of model inflammations (kaolin- and Staphylococcus-induced ones), the values measured with 99mTc-peptides are more than double than those of kaolin suspension inflammation. The studied low molecular peptides labelled with 99mTc allow rapid localisation of infection foci. 99mTc labelled HIG proved useful for detection of infections and inflammatory lesions.     

Distribution of radioactivity and metabolite profiling in tumour and plasma following intravenous administration of a colchicine derivative (14C-ZD6126) to tumour-bearing mice

The main aim of the study was to investigate the distribution of radioactivity in the tissues and tumours using quantitative whole-body autoradiography (QWBA), together with a more detailed investigation of plasma and tumour samples, following administration of a single intravenous dose at 200 mg kg(-1) of 14C-ZD6126 to mice bearing subcutaneous Hras5 tumour xenografts. The study also included an assessment of tumour necrosis following administration of a single intravenous dose of non-labelled ZD6126 at 200 mgkg(-1). QWBA analysis showed that drug-related material was widely distributed to the tissues and tumour. In the majority of tissues, concentrations of radioactivity were highest at 15 min and declined rapidly thereafter. The tumour-to-plasma ratio was 0.6:1 at 0.25 h and increased to 6:1 at 48 h, indicating that drug-related material persisted in the tumour longer than in plasma. ZD6126, a phosphate ester, is rapidly hydrolysed to ZD6126 phenol, the active metabolite. The major metabolite in plasma (36% of the sample radioactivity) and all tumour samples (58-83% of the sample radioactivity) was confirmed as ZD6126 phenol. Extensive tumour necrosis was noted by 24h, which was still evident at 48 h, although there was some evidence of tumour regrowth.     

Synthesis of [99mTc]ethylenedicysteine-colchicine for evaluation of antiangiogenic effect.

Angiogenesis is in part responsible for tumor growth and the development of metastasis. Radiolabeled angiongenesis inhibitors would be useful to assess tumor microvasculature density. Colchicine (COL), a potent antiangiogenic agent, is known to inhibit microtubule polymerization and cell arrest at metaphase. This study aimed to develop 99mTc-labeled COL (EC-COL) using ethylenedicysteine (EC) as a chelator to assess tumor microvascular density. EC was conjugated to trimethylcolchicinic acid using N-hydroxysuccinimide and 1-ethyl-3-dimethylaminopropyl carbodiimide as coupling agents with a yield of 50-60%. In vivo stability was analyzed in rabbit serum at 0.5-4 h. Tissue distribution and planar imaging studies of [99mTc]EC-COL were evaluated in breast tumor-bearing rats at 0.5, 2 and 4 h. The data was compared to that using [99mTc]EC (control). The radiochemical yield of [99mTc]EC-COL was greater than 95%. [99mTc]EC-COL was stable in rabbit serum. In vivo biodistribution of [99mTc]EC-COL in breast tumor-bearing rats showed increased tumor-to-blood (0.52+/-0.12 to 0.72+/-0.07) and tumor-to-muscle (3.47+/-0.40 to 7.97+/-0.93) ratios as a function of time. Conversely, tumor-to-blood values showed a time-dependent decrease with [99mTc]EC over the same time period. Planar images confirmed that the tumors could be visualized clearly with [99mTc]EC-COL from 0.5 to 4 h. [99mTc]EC-COL may be useful to assess antiangiogenic and therapeutic effects during chemotherapy.     

Enhanced retention of celecoxib-loaded solid lipid nanoparticles after intra-articular administration

OBJECTIVE: The objective of this study was to determine whether the retention of celecoxib in inflamed articular joints of arthritic rats could be enhanced by incorporation of the drug into solid lipid nanoparticles. METHODS: Celecoxib-loaded solid lipid nanoparticles (SLN) were prepared by emulsification and high-pressure homogenisation, then characterised by particle size analysis and scanning electron microscopy. In vitro drug-release studies indicated that the nanoparticles exhibited sustained release of celecoxib and the release pattern followed quasi-Fickian diffusion. The biocompatibility of solid lipid nanoparticles was evaluated by histopathology of the rat joints after intra-articular injection in normal rats. Celecoxib and celecoxib-loaded SLN were labelled with (99m)Tc and the labelling parameters were optimised to obtain maximum labelling efficiency. The labelled complexes were administered intra-articularly and the pharmacokinetics and biodistribution were determined. RESULTS: The nanoparticles showed no inflammatory infiltrates 3 and 7 days post-intra-articular injection, proving their biocompatibility and suitability for intra-articular use. Free celecoxib underwent rapid clearance from the inflamed articular joints into the systemic circulation, while the celecoxib-loaded SLN were associated with significantly lower blood levels compared with free celecoxib. Free celecoxib was found to have been extensively distributed to organs of the reticuloendothelial system such as the liver, lungs and spleen. In contrast, celecoxib-loaded nanoparticles demonstrated significantly lower distribution to the reticuloendothelial organs. The articular concentrations of celecoxib-loaded nanoparticles in the inflamed joints were 16-fold higher at 4 hours post-injection and 15-fold higher at 24 hours post-injection than free celecoxib concentrations, indicating greater and prolonged retention in the inflamed articular joints. CONCLUSION: Celecoxib-loaded SLN with its greater intra-articular retention and sustained-release properties would be a beneficial delivery system for the effective treatment of arthritis and is expected to result in prolonged anti-arthritic activity of celecoxib.     

Biphasic accumulation kinetics of [99mTc]-hexakis-2-methoxyisobutyl isonitrile in tumour cells and its modulation by lipophilic P-glycoprotein ligands.

AIM: To study the accumulation and washout kinetics of [99mTc]-hexakis-2-methoxyisobutyl isonitrile (99mTc-MIBI) in MDR positive and MDR negative tumour cells and how this is modified by lipophilic P-glycoprotein ligands. METHODS: The tumour cells were incubated in the presence and absence of the ligands and the uptakes of 99mTc-MIBI, rhodamine 123 and 2-[18F]fluoro-2-deoxy-D-glucose (18FDG) were measured. RESULTS: The accumulation of 99mTc-MIBI in the tumour cells followed biphasic kinetics. Verapamil and cyclosporin A increased the membrane fluidity and significantly enhanced the 99mTc-MIBI uptake of the MDR negative cells, while the rhodamine 123 uptake was not affected. Verapamil significantly increased the uptake of rhodamine 123 and 18FDG but did not modify that of 99mTc-MIBI in the MDR positive cells. Cyclosporin A significantly increased the 18FDG uptake of the MDR positive and negative tumour cells; these effects were ouabain-sensitive. Depolarization of the cytoplasmic membrane, acidification of the extracellular medium and the administration of CCCP decreased the accumulation of 99mTc-MIBI and rhodamine 123 uptake in the tumour cells. CONCLUSIONS: Lipophilic P-glycoprotein ligands modified the biphasic accumulation kinetics of the 99mTc-MIBI uptakes of MDR negative and positive tumour cells in different and complex ways and could therefore mask the P-glycoprotein pump-dependent changes in tracer accumulation.     

Distribution of radioactivity and metabolite profiling in tumour and plasma following intravenous administration of a colchicine derivative (14C-ZD6126) to tumour-bearing mice

The main aim of the study was to investigate the distribution of radioactivity in the tissues and tumours using quantitative whole-body autoradiography (QWBA), together with a more detailed investigation of plasma and tumour samples, following administration of a single intravenous dose at 200?mg?kg^?1 of ¹⁴C-ZD6126 to mice bearing subcutaneous Hras5 tumour xenografts. The study also included an assessment of tumour necrosis following administration of a single intravenous dose of non-labelled ZD6126 at 200?mg?kg^?1. QWBA analysis showed that drug-related material was widely distributed to the tissues and tumour. In the majority of tissues, concentrations of radioactivity were highest at 15?min and declined rapidly thereafter. The tumour-to-plasma ratio was 0.6:1 at 0.25?h and increased to 6:1 at 48?h, indicating that drug-related material persisted in the tumour longer than in plasma. ZD6126, a phosphate ester, is rapidly hydrolysed to ZD6126 phenol, the active metabolite. The major metabolite in plasma (36% of the sample radioactivity) and all tumour samples (58–83% of the sample radioactivity) was confirmed as ZD6126 phenol. Extensive tumour necrosis was noted by 24?h, which was still evident at 48?h, although there was some evidence of tumour regrowth.     

Dermal delivery of doxorubicin-loaded solid lipid nanoparticles for the treatment of skin cancer

Objective: Dermal delivery of Doxorubicin (Dox) would be an ideal way in maximising drug efficiency against skin cancer accompanying with minimising side effects. We investigated the potential of Dox-loaded Solid lipid nanoparticles (SLNs) for topical delivery against skin cancer.

Methods: In vitro and in vivo cytotoxicity of optimised formulation were evaluated on murine melanoma (B16F10) cells by MTT assay and melanoma induced Balb/C mice, respectively. Animal study followed by histological analysis.

Results: Optimised formulation showed mean particle size and encapsulation efficiency (EE) of 92?nm and 86% w/w (0.86% w/w value of encapsulated Dox in the lipid matrix), respectively. FTIR experiment confirmed drug–lipid interaction interpreting the observed high EE value for Dox. In vitro and in vivo results indicated the superiority of cytotoxic performance of Dox-loaded SLN compared to Dox solution.

Conclusion: Our findings may open the possibilities for the topical delivery of Dox to the skin cancerous tissues.     

New brain perfusion imaging agents based on 99mTc-bis(aminoethanethiol) complexes: stereoisomers and biodistribution

In developing new brain perfusion imaging agents, we prepared 99mTc complexes of racemic mixtures of bis(aminoethanethiol) (BAT) derivatives containing an N'-benzylpiperazinyl (BPA) side chain. Due to the presence of a chiral center, a mixture of diastereomers (syn and anti) following chelation with the 99mTc (no-carrier-added) was obtained. The neutral and lipid-soluble 99mTc-BPA-BAT (99mTc, T1/2 = 6 h) isomers were separated. The syn and anti isomers of carrier-added 99Tc-BPA-BAT (99Tc, T1/2 = 2 x 10(5) years) were also synthesized, separated, and crystallized. The X-ray crystallography of 99Tc-BPA-BAT showed the syn and anti conformations (in relationship with the central TC(=O)N2S2 core). Despite a similarity in the partition coefficients for the two isomers, the syn isomer showed a higher in vivo brain uptake and longer brain retention in rats (2.77 and 1.08% dose/organ at 2 and 15 min) than that of the corresponding anti isomer (0.57 and 0.27% dose/organ at 2 and 15 min). This information is important and should be taken into consideration when new 99mTc-labeled brain perfusion imaging agents are being designed.