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ABSTRACT: The development of noninvasive imaging techniques for the assessment of cancer treatment is rapidly becoming highly important. The aim of the present study is to show that magnetic cationic liposomes (MCLs), incorporating superparamagnetic iron oxide nanoparticles (SPIONs), are a versatile theranostic nanoplatform for enhanced drug delivery and monitoring of cancer treatment.
MCLs (with incorporated high SPION cargo) were administered to a severe combined immunodeficiency mouse with metastatic (B16-F10) melanoma grown in the right flank. Pre- and post-injection magnetic resonance (MR) images were used to assess response to magnetic targeting effects. Biodistribution studies were conducted by ¹¹¹In-labeled MCLs and the amount of radioactivity recovered was used to confirm the effect of targeting for intratumoral administrations.
We have shown that tumor signal intensities in T₂-weighted MR images decreased by an average of 20 ± 5% and T₂* relaxation times decreased by 14 ± 7 ms 24 h after intravenous administration of our MCL formulation. This compares to an average decrease in tumor signal intensity of 57 ± 12% and a T₂* relaxation time decrease of 27 ± 8 ms after the same time period with the aid of magnetic guidance.
MR and biodistribution analysis clearly show the efficacy of MCLs as MRI contrast agents, prove the use of magnetic guidance, and demonstrate the potential of MCLs as agents for imaging, guidance and therapeutic delivery.
Nanomedicine 10/2010; 5(8):1173-82. · 5.05 Impact Factor
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ABSTRACT: Cationic liposomes have been shown to preferentially target the tumor vasculature, but not uniformly. Bevacizumab antibody selectively accumulates in tumors expressing VEGF. We thus developed bevacizumab-modified, pegylated cationic liposomes (PCLs) to improve the distribution of liposomes along tumor vessels, and to enhance tumor targeting.
We evaluated the delivery vehicle both in the absence and presence of VEGF, using human pancreatic cancer (Capan-1, HPAF-II and PANC-1) and endothelial (MS1-VEGF and HMEC-1) cell lines.
All cell lines except for HMEC-1 secreted VEGF. Modification of PCLs with bevacizumab did not alter zeta-potential, but increased overall liposome size. The toxicity profile for bevacizumab-modified PCLs was cell line dependent and, in general, bevacizumab improved cellular uptake and tumor targeting of PCLs.
Bevacizumab-modified PCLs represent a potential improvement over the unmodified variety, supporting their future development for the treatment of cancer.
Nanomedicine 02/2010; 5(2):181-92. · 5.05 Impact Factor
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ABSTRACT: The goal of this research was to evaluate the effectiveness of cationic liposomes for intranasal administration of proteins to the brain. Cationic liposomes were loaded with a model protein, ovalbumin (OVAL), and a 50 microg dose was administered intranasally to rats. In qualitative studies, liposomes were loaded with Alexa 488-OVAL and delivery was assessed by fluorescence microscopy. By 6 and 24 h after administration, Alexa 488-OVAL deposits were widely distributed throughout brain, with apparent cellular uptake in midbrain by 6 h after administration. In quantitative studies, liposomes were loaded with (111)In-OVAL, and distribution to brain and peripheral tissues was monitored by gamma counting at 1, 4, 6, and 24 h after administration. The highest brain concentrations were achieved at the shortest time point, 1 h, for both liposomal and aqueous OVAL. However, the liposomes yielded higher (111)In-OVAL concentrations in brain than (111)In-OVAL in PBS. Moreover, a 2 microg/microL form of liposomal OVAL yielded a higher percentage of dose in brain, and a lower percentage in stomach and intestines, than twice the volume of a 1 microg/microL preparation. Cationic liposomes may provide a novel, noninvasive strategy for delivery of neuroactive proteins to the brain for treatment of central nervous system disorders.
Journal of Pharmaceutical Sciences 09/2009; 99(4):1745-61. · 3.06 Impact Factor
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ABSTRACT: The use of magnetic drug targeting (MDT) to selectively deliver chemotherapeutic drugs to tumor cells is a widely investigated approach; however, the notion of targeting tumor endothelial cells by this method is a fairly new concept. Positively-charged (cationic) liposomes have an extraordinarily high affinity for tumor vessels, but heterogeneous targeting is frequently observed. In order to improve on the overall efficiency of targeting tumor vessels, we investigated the use of an externally applied magnetic field together with magnetic cationic liposomes (MCLs) for cancer treatment. We examined the antitumor effect of the chemotherapeutic agent vinblastine loaded in MCLs, using a murine model of melanoma. Two hours following i.v. administration of MCLs, we observed significant tumor vascular uptake with use of an external magnet (15.9 +/- 6.3%) compared to no magnet (5 +/- 1.3%). The administration of vinblastine-loaded MCLs with the magnet produced a significant antitumor effect, reducing the presence of tumor nodules in preferential sites of metastasis compared to untreated and free drug control groups. CD31 immunostaining revealed a decrease in the general length of tumor blood vessels, altered vascular morphology and interruptions in the tumor vascular lining for the vinblastine-loaded MCL groups. Drug-loaded MCLs with magnetic fields may represent a promising combination approach for cancer treatment.
Cancer Science 06/2009; 100(8):1537-43. · 3.33 Impact Factor
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ABSTRACT: Current treatments for pancreatic cancer have failed to effectively manage the disease, and hence, more effective treatment approaches are urgently needed. Studies suggest that mucin O-glycosylation limits the cytotoxic effect of fluorouracil (5-FU) against the growth of human pancreatic cancer cells in vitro. In the present study, we investigated the relationship between the levels of mucin O-glycosylation expressed in pancreatic tumours and the antitumour effect of 5-FU. The inhibition of O-glycosylation was achieved by intratumoural (IT) injections of benzyl-alpha-GalNAc. Immunohistochemical staining of human pancreatic tumours revealed relatively high (Capan-1) and moderate (HPAF-II) expression levels of MUC1 mucin compared to MUC1 negative control (U-87 MG human glioblastoma) tumours. The antitumour effects of 5-FU (given systemically) against Capan-1 tumours improved significantly following IT injections of benzyl-alpha-GalNAc. Histochemical staining of tumour sections revealed a reduced number of neoplastic cells in tumours exposed to benzyl-alpha-GalNAc prior to 5-FU treatment compared to 5-FU alone. Furthermore, intracellular uptake of 5-FU by Capan-1 cells was significantly greater following injections of benzyl-alpha-GalNAc; however, no such effect was observed with U-87 MG cells. Mucin overexpression reduces intracellular drug uptake, antineoplastic and antitumour drug effects, which may have important clinical implications in treatment.
European journal of cancer (Oxford, England: 1990) 12/2008; 45(1):164-73. · 4.12 Impact Factor
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ABSTRACT: The use of second generation cationic liposomes to deliver cytotoxic drugs to solid tumors is a rational and promising therapeutic approach, given the natural affinity of cationic carrier molecules for the tumor microvasculature. Cationic liposomal therapeutics are effective in the treatment of cancers that are resistant to conventional chemotherapy and other treatment modalities. Researchers are now exploring novel ways to combine cationic nanosystems with other treatment approaches. For example, strategies for using cationic liposomes with hyperthermia or magnetic fields have been evaluated. Drug-loaded cationic liposomes have been documented to induce tumor vascular defects, alter vascular function and limit the growth of the primary tumors and metastasis. In this review, we discuss general features of the endothelium as a function of its tissue environment. We discuss the rationale for targeting tumor vessels over the tumor interstitial matrix, and for the development of second generation cationic lipids and liposomes for tumor vascular targeting. We evaluate the benefits of incorporating the polymer polyethylene-glycol (PEG) in conventional and cationic liposomes for nonspecific and relatively vascular-specific tumor targeting, respectively. Finally, we review preclinical and clinical investigations evaluating drug-loaded cationic liposomes in cancer treatment.
Journal of Pharmaceutical Sciences 07/2008; 98(2):411-29. · 3.06 Impact Factor
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ABSTRACT: Chemotherapy is a popular treatment approach against cancer but significant uptake of drugs by normal tissues is still a major limitation. Magnetic drug targeting (MDT) has been used to improve localized drug delivery to interstitial tumor targets. MDT is now being developed to improve drug delivery to tumor vessels. We thus seek to understand the role of magnetite (MAG-C) in drug loading, influence on cytotoxicity and vascular targeting characteristics. The inclusion of MAG-C at lower concentrations (0.5 mg/ml) in cationic liposomes did not alter the efficiency of loading etoposide, but at higher concentrations (2.5 mg/ml) incorporation decreased from 80+/-3.4% to 44+/-4.26%. MAG-C reduced the incorporation of dacarbazine. The incorporation was significantly lower compared to liposomal etoposide, both in the presence and absence of MAG-C. The incorporation efficiency of vinblastine sulfate in cationic liposomes was similar for low and relatively high MAG-C content; values for incorporation were 21+/-0.11 and 23+/-2, respectively. Polyethylene-glycol improved the efficiency of loading chemotherapeutic agents regardless of drug type. Additionally, cytotoxicity and tumor vascular targeting characteristics of liposome therapeutics were not influenced by MAG-C. The components used to prepare magnetic liposomes for MDT should be optimized for maximum therapeutic benefit.
Biomaterials 12/2007; 28(31):4673-83. · 7.40 Impact Factor
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ABSTRACT: Cationic liposomes preferentially target tumor vasculature compared to vessels in normal tissues. The distribution of cationic liposomes along vascular networks is, however, patchy and heterogeneous. To target vessels more uniformly we combined the electrostatic properties of cationic liposomes with the strength of an external magnet. We report part I of development. We evaluated bilayer physical properties of our preparations. We investigated interaction of liposomes with target cells including the role of PEG (polyethylene-glycol), and determined whether magnetic cationic liposomes can respond to an external magnetic field. The inclusion of relatively high concentration of MAG-C (magnetite) at 2.5 mg/ml significantly increased the size of cationic liposomes from 105+/-26.64 to 267+/-27.43 nm and reduced the zeta potential from 64.55+/-16.68 to 39.82+/-5.26 mv. The phase transition temperature of cationic liposomes (49.97+/-1.34 degrees C) reduced with inclusion of MAG-C (46.05+/-0.21 degrees C). MAG-C cationic liposomes were internalized by melanoma (B16-F10 and HTB-72) and dermal endothelial (HMVEC-d) cells. PEG partially shielded cationic charge potential of MAG-C cationic liposomes, reduced their ability to interact with target cells in vitro, and uptake by major RES organs. Finally, application of external magnet enhanced tumor retention of magnetic cationic liposomes.
Biochimica et Biophysica Acta 04/2007; 1768(3):427-38. · 4.66 Impact Factor
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Robert B Campbell
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ABSTRACT: Over the past few decades significant advances have been made in the development of nanopharmaceuticals (including phospholipid and polymer-based therapeutics) against cancer. There is still, however, room for improvement. Today, many researchers are focusing on the development of innovative approaches to selectively deliver drugs to solid tumors, while minimizing insult to healthy tissues. Unfortunately, the majority of these efforts are confronted by physiological barriers that reduce the clinical dose required to effectively manage the disease state. In an effort to develop promising nanopharmaceutical products of the future, we review the most important problems facing drug delivery experts today. We discuss here, the physiological role of solid tumors in delivery and transport of nanopharmaceutical products. The nature of tumors in terms of their unique anatomical structure and functions is also discussed. Finally, an overview of ways to overcome physiological barrier functions and exploit tumor pathogenesis for therapeutic gain is provided.
Anti-Cancer Agents in Medicinal Chemistry (Formerly Current Medicinal Chemistry - Anti-Cancer Agents) 12/2006; 6(6):503-12. · 2.86 Impact Factor
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ABSTRACT: Human pancreatic adenocarcinoma is a major leading cause of cancer mortality in the United States. Given that current strategies are relatively ineffective against this disease, new treatments are being developed. Liposomes possessing relatively high cationic lipid content preferentially accumulate in tumor angiogenic vessels compared to vessels in normal tissues. We therefore seek to develop cationic liposomes for targeting pancreatic tumor vessels.
We report development of 5-fluorouracil (5-FU) and doxorubicin hydrochloride (DOX) loaded in PEGylated cationic liposomes (PCLs). We evaluate cell association, intracellular fate, and cytotoxicity. Human pancreatic cancer cells HPAF-II and Capan-1, and endothelial cells HMEC-1 and HUVEC were used in this study. Intratumoral distribution of PCLs in (HPAF-II) tumors was determined by intravital microscopy.
HUVEC and HMEC-1 were most susceptible to 5-FU after 24 and 48 h, compared to HPAF-II and Capan-1. We observed >90% incorporation of 5-FU and DOX in PCLs for 3-20 mol% preparations, with reduced incorporation for >20 mol% formulations. PCLs showed significantly higher association with human endothelial versus pancreatic cancer cells, and improved growth inhibitory properties of DOX. Intravital microscopy revealed distribution of PCLs along HPAF-II vessels.
Targeting human pancreatic cancer with PCLs may represent a rational alternative to conventional strategies.
Pharmaceutical Research 12/2006; 23(12):2809-17. · 4.09 Impact Factor
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ABSTRACT: Transport parameters determine the access of drugs to tumors. However, technical difficulties preclude the measurement of these parameters deep inside living tissues. To this end, we adapted and further optimized two-photon fluorescence correlation microscopy (TPFCM) for in vivo measurement of transport parameters in tumors. TPFCM extends the detectable range of diffusion coefficients in tumors by one order of magnitude, and reveals both a fast and a slow component of diffusion. The ratio of these two components depends on molecular size and can be altered in vivo with hyaluronidase and collagenase. These studies indicate that TPFCM is a promising tool to dissect the barriers to drug delivery in tumors.
Nature Medicine 03/2004; 10(2):203-7. · 22.46 Impact Factor
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ABSTRACT: Tumor vessels possess unique physiological features that might be exploited for improving drug delivery. In the present study, we investigate the possibility of modifying polyethylene glycol-ylated liposome cationic charge of polyethylene glycol coated liposomes to optimize delivery to tumor vessels using biodistribution studies and intravital microscopy. The majority of liposomes accumulated in the liver, and increasing charge resulted in lower retention in the spleen and blood. Although overall tumor uptake was not affected by charge in the biodistribution studies, intravital microscopy showed that increasing the charge content from 10 to 50 mol % doubled the accumulation of liposomes in tumor vessels, suggesting a change in intratumor distribution; no significant effect of charge on interstitial accumulation could be detected, possibly attributable to spatial heterogeneity. Increased vascular accumulation of cationic liposomes was similar in two different tumor types and sites. Our results suggest that optimizing physicochemical properties of liposomes that exploit physiological features of tumors and control the intratumor distribution of these drug carriers should improve vascular-specific delivery.
Cancer Research 01/2003; 62(23):6831-6. · 7.86 Impact Factor
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ABSTRACT: Using cationic liposomes to deliver cytotoxic molecules to the tumor microvasculature is currently being developed for the treatment of cancer and other angiogenesis-related diseases. To improve on their beneficial properties, the authors have examined whether the particular cationic lipid type and lipid content employed are important factors influencing cellular interactions and formulation effects. The authors prepared different PEG (polyethylene glycol)-modified cationic liposomes (PCLs) with varying percent cationic lipid content and lipid type, and evaluated liposome size, surface charge (zeta) potential, and cellular properties in vitro. The cell lines used were human umbilical vein (HUVEC), lung microvascular (HMVEC-L and HPVE-26), coronary microvascular (HMVEC-C), dermal microvascular (HMVEC-D), and immortalized dermal microvascular (HMEC-1) endothelial cells. In vitro experiments consisted of cellular uptake and cytotoxicity studies, fluorescence-activated cell sorting (FACS) analysis, fluorescence, and transmission electron microscopic analysis. Liposome size and zeta potential analysis of five different PCLs revealed significant differences in their physicochemical properties. Some cationic lipids formed relatively toxic liposomes compared to others. The efficiency of loading chemotherapeutic drugs (doxorubicin hydrochloride, etoposide), affinity of PCLs for endothelial cells, and formulation effects varied according to cationic lipid content and the lipid type. Cellular uptake was observed in lung, dermal, and coronary endothelial cells. Heparan sulfate proteoglycans were found present on HMEC-1 cells, which may have enabled PCL uptake. In conclusion, physicochemical properties of cationic liposomes and their ability to interact with endothelial cells are important factors to consider during the early stages of formulation development for the treatment of cancer and other angiogenesis-dependent diseases.
Endothelium 15(4):189-201. · 1.65 Impact Factor
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Alain Pluen,
Yves Boucher,
Saroja Ramanujan,
Trevor D McKee,
Takeshi Gohongi,
Emmanuelle di Tomaso,
Edward B Brown,
Yotaro Izumi, Robert B Campbell,
David A. Berk,
Rakesh K Jain
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ABSTRACT: The large size of many novel therapeutics impairs their transport through the tumor extracellular matrix and thus limits their therapeutic effectiveness. We propose that extracellular matrix composition, structure, and distribution determine the transport properties in tumors. Furthermore, because the characteristics of the extracellular matrix largely depend on the tumor–host interactions, we postulate that diffusion of macromolecules will vary with tumor type as well as anatomical location. Diffusion coefficients of macromolecules and liposomes in tumors growing in cranial windows (CWs) and dorsal chambers (DCs) were measured by fluorescence recovery after photobleaching. For the same tumor types, diffusion of large molecules was significantly faster in CW than in DC tumors. The greater diffusional hindrance in DC tumors was correlated with higher levels of collagen type I and its organization into fibrils. For molecules with diameters comparable to the interfibrillar space the diffusion was 5- to 10-fold slower in DC than in CW tumors. The slower diffusion in DC tumors was associated with a higher density of host stromal cells that synthesize and organize collagen type I. Our results point to the necessity of developing site-specific drug carriers to improve the delivery of molecular medicine to solid tumors.
