Characterizing an siRNA-Containing Lipid-Nanoparticle Prepared by a Microfluidic Reactor: Small-Angle X-ray Scattering and Cryotransmission Electron Microscopic Studies.

A new cationic-lipid/siRNA particle that was designed to deliver siRNA was investigated by the combination of small-angle X-ray scattering (SAXS), asymmetric field flow fractionation coupled with multiangle light scattering, and cryotransmission electron microscopy (cryo-TEM). The particle was prepared through two-step mixing using a microfluidic technique. In the first step, siRNA was premixed with a cationic lipid in an EtOH-rich solution. In the second step, the premixed solution was mixed with other lipids, followed by solvent exchange with water. SAXS showed formation of a siRNA/cationic lipid pair in the first step, and this pair consisted of the major part of the core in the final particle. The relationship between the hydrodynamic radius and the radius of gyration indicated the formation of a densely packed core and PEG-rich shell, confirming a well-known core-shell model. SAXS and cryo-TEM showed that the ordering of the core structure enhanced as the siRNA content increased.

Pharmacokinetic evaluation of liposomal nanoparticle-encapsulated nucleic acid drug: A combined study of dynamic PET imaging and LC/MS/MS analysis.

In vivo biodistribution analyses, especially in tumors, of nucleic acids delivered with nanoparticles are important to develop drug delivery technologies for medical use. We previously developed wrapsome® (WS), an ~100 nm liposomal nanoparticle that can encapsulate siRNA, and reported that WS accumulates in tumors in vivo and inhibits their growth by an enhanced permeability and retention effect. In the present study, we evaluated the pharmacokinetics of nucleic acid-containing nanoparticles by combining dynamic positron emission tomography (PET) imaging and liquid chromatography-tandem mass spectrometry (LC/MS/MS) analysis. An 18-mer phosphorothioate oligodeoxynucleotide (ODN), trabedersen, was used as a model drug and was encapsulated in WS. Dynamic PET imaging and time-activity curve analysis of WS-encapsulated 64Cu-labeled ODNs administered to mice with MIA PaCa-2 subcutaneous xenograft tumors showed tumor accumulation (~3% injected dose per gram (%ID/g)) and liver accumulation (~30 %ID/g) at 24 h. Under these conditions, LC/MS/MS analysis showed that the level of intact ODNs was 1.62 %ID/g in the tumor and 1.70 %ID/g in the liver. From these pharmacokinetic data, the intact/accumulated ODN ratios were calculated using the following equation: intact/accumulated ODN ratio (%) = %ID/g LC/MS/MS, tissue, mean/%ID/g PET, tissue, mean × 100. Interestingly, the ratios for the tumor and kidney were maintained at 20-50% over 48 h after administration of the WS-encapsulated form. In contrast, the ratio for the liver rapidly decreased at 24 h, showing the same pattern as that for naked ODN. These different patterns indicate that WS effectively protected the ODN in the tumor and kidney, but protected it less efficiently in the liver. A combined approach of dynamic PET imaging and LC/MS/MS analysis will assist the development of nanoparticle-encapsulated nucleic acid drugs, such as those using WSs, to determine their detailed pharmacokinetics.

Dynamic analysis of fluid distribution in the gastrointestinal tract in rats: positron emission tomography imaging after oral administration of nonabsorbable marker, [(18)F]Deoxyfluoropoly(ethylene glycol).

To develop potent drugs for oral use, information on their pharmacokinetic (PK) properties after oral administration is of great importance. We have recently reported the utility of positron emission tomography (PET) for the analysis of gastrointestinal (GI) absorption of radiolabeled compounds. In this study, PET image analysis was performed in rats using a novel PET probe, [(18)F]deoxyfluoropoly(ethylene glycol)s, with an average molecular weight of 2 kDa ([(18)F]FPEG), as a nonabsorbable marker to elaborate the GI physiology in more detail, such as segmental transition of the administered water, and fluid volume and distribution in the intestine. After oral administration of [(18)F]FPEG solution to rats, a 90 min PET scan with continuous blood sampling was performed, and then the disposition of radioactivity in each part of GI tract was investigated. From blood PK analysis, it was confirmed that the bioavailability of [(18)F]FPEG was quite low in rats. PET image analysis showed that the radioactivity after oral administration of [(18)F]FPEG solution rapidly passed through the stomach, spread into the proximal small intestine, and then transited toward the distal region of the small intestine without decreasing the radioactivity during GI transition. Radiometabolite analysis revealed that the radioactivity in intestinal mucosal tissues, blood, and urine was mainly derived from unchanged [(18)F]FPEG. It was also found that the volume of interest (VOI) after oral administration of the radiotracer enables an understanding of the time-dependent manner of effective fluid volume changes in the stomach and the small intestine. In addition, the rate constant of the intestinal transition of radioactivity in each intestinal segment was calculated by kinetic model analysis, which revealed that PET analysis enables us to determine the GI transit from the same individuals and that it is applicable to determine site-specific intestinal absorption. In conclusion, we demonstrated the high potency of PET imaging technique to elucidate the distribution of orally administered solution in the GI tract in vivo.

Systemic delivery of small interfering RNA by use of targeted polycation liposomes for cancer therapy.

Novel polycation liposomes decorated with cyclic(Cys-Arg-Gly-Asp-D-Phe) peptide (cyclicRGD)-polyethylene glycol (PEG) (RGD-PEG-polycation liposomes (PCL)) were previously developed for cancer therapy based on RNA interference. Here, we demonstrate the in vivo delivery of small interfering RNA (siRNA) to tumors by use of RGD-PEG-PCL in B16F10 melanoma-bearing mice. Pharmacokinetic data obtained by positron emission tomography showed that cholesterol-conjugated siRNA formulated in RGD-PEG-PCL markedly accumulated in the tumors. Delivered by RGD-PEG-PCL, a therapeutic cocktail of siRNAs composed of cholesterol-conjugated siRNAs for c-myc, MDM2, and vascular endothelial growth factor (VEGF) were able to significantly inhibit the growth of B16F10 melanoma both in vitro and in vivo. These data suggest that targeted delivery of siRNAs by use of RGD-PEG-PCL has considerable potential for cancer treatment.

[In vivo imaging of liposomal small interfering RNA (siRNA) trafficking by positron emission tomography].

In the development of nucleic acid medicines such as small interfering RNA (siRNA) drugs, one problem is how to study the pharmacokinetics and pharmacodynamics, since the precise in vivo behavior of siRNA is hard to detect. In this research, to establish a highly sensitive detection system of siRNA biodistribution in the whole body, the technology of positron imaging was applied. First, a one-step synthetic method in which double-stranded siRNA was directly labeled by a positron emitter, (18)F, was developed. By using [(18)F]-labeled siRNA ([(18)F]-siRNA), the complex of siRNA and polycation liposomes (PCL) containing dicetylphosphate tetraethylenepentamine (TEPA-PCL) was prepared. Then, the biodistribution of the siRNA after intravenous administration to mice was analyzed by planar positron imaging system (PPIS). As a result, whereas naked [(18)F]-siRNA was immediately excreted in mouse bladder after administration, the complex with cationic liposome (CL) was trapped in the lungs. Furthermore, [(18)F]-siRNA carried with PEGylated CL (PL) was distributed throughout the body, suggesting that it circulated in the bloodstream for an extended period of time. Additionally, PET imaging revealed more detailed biodistribution of the siRNA than in vivo imaging system (IVIS) because PET imaging is not affected by the depth variation of target tissues. On the other hand, to induce high accumulation of siRNAs against c-myc, MDM2, and VEGF in tumor tissue, a tumor-targeting probe, RGD peptide, was grafted at the top of PEG chain in PEGylated TEPA-PCL and the effect of the complex on experimental lung metastasis of B16 melanoma was examined. The complex suppressed the progression of tumor. We believe that the positron imaging data would support the development of siRNA agent for clinical use.

Dicetyl phosphate-tetraethylenepentamine-based liposomes for systemic siRNA delivery.

Dicetyl phosphate-tetraethylenepentamine (DCP-TEPA) conjugate was newly synthesized and formed into liposomes for efficient siRNA delivery. Formulation of DCP-TEPA-based polycation liposomes (TEPA-PCL) complexed with siRNA was examined by performing knockdown experiments using stable EGFP-transfected HT1080 human fibrosarcoma cells and siRNA for GFP. An adequate amount of DCP-TEPA in TEPA-PCL and N/P ratio of TEPA-PCL/siRNA complexes were determined based on the knockdown efficiency. Then, the biodistribution of TEPA-PCL modified with poly(ethylene glycol) (PEG) was examined in BALB/c mice. As a result, TEPA-PCL modified with PEG6000 avoided reticuloendothelial system uptake and showed long circulation in the bloodstream. On the other hand, PEGylation of TEPA-PCL/siRNA complexes caused dissociation of a portion of the siRNA from the liposomes. However, we found that the use of cholesterol-conjugated siRNA improved the interaction between TEPA-PCL and siRNA, which allowed PEGylation of TEPA-PCL/siRNA complexes without siRNA dissociation. In addition, TEPA-PCL complexed with cholesterol-conjugated siRNA showed potent knockdown efficiency in stable luciferase-transfected B16-F10 murine melanoma cells. Finally, the biodistribution of cholesterol-conjugated siRNA formulated in PEGylated TEPA-PCL was examined by performing near-infrared fluorescence imaging in Colon26 NL-17 murine carcinoma-bearing mice. Our results showed that tumor targeting with siRNA via systemic administration was achieved by using PEGylated TEPA-PCL combined with active targeting with Ala-Pro-Arg-Pro-Gly, a peptide used for targeting angiogenic endothelium.

Synthesis of long-chain [¹8F]Deoxyfluoropoly(ethylene glycol) methyl ethers and their noninvasive pharmacokinetic analysis by positron emission tomography.

[¹8F]DeoxyfluoroPEG methyl ethers with an average molecular weight of 2 kDa ([¹8F]1a) and 10 kDa ([¹8F]1b) were synthesized by the fluorination of the tosylates 3a,b with [¹8F]nBu4NF at 80°C for 20 min followed by flash filtration through a Sep-Pak Plus Alumina-N cartridge. After the intravenous administration of [¹8F]1a and [¹8F]1b to rats, their pharmacokinetics was analyzed by noninvasive, real-time, whole-living-body monitoring using positron imaging technology. The effect of PEG's molecular weight on their blood circulation and organ clearance were quantitatively visualized for the first time.

PET imaging of brain cancer with positron emitter-labeled liposomes.

Since nanocarriers such as liposomes are known to accumulate in tumors of tumor-bearing animals, and those that have entrapped a positron emitter can be used to image a tumor by PET, we applied (18)F-labeled 100-nm-sized liposomes for the imaging of brain tumors. Polyethylene glycol (PEG)-modified liposomes, which are known to accumulate in tumors by passive targeting and those modified with Ala-Pro-Arg-Pro-Gly, which are known to home into angiogenic sites were used. Those liposomes labeled with DiI fluorescence accumulated in a glioma implanted in a rat brain 1h after the injection, although they did not accumulate in the normal brain tissues due to the protection afforded by the blood-brain barrier. Preformed liposomes were easily labeled with 1-[(18)F]fluoro-3,6-dioxatetracosane, and enabled the imaging of gliomas by PET with higher contrast than that obtained with [(18)F]deoxyfluoroglucose. In addition, the smallest tumor among those tested, having a diameter of 1mm was successfully imaged by the liposomal (18)F. Therefore, nanocarrier-based imaging of brain tumors is promising for the diagnosis of brain cancer and possible drug delivery-based therapy.

T cell-independent B cell response is responsible for ABC phenomenon induced by repeated injection of PEGylated liposomes.

Repeated injection of polyethyleneglycol-modified (PEGylated) liposomes causes a rapid clearance of them from the bloodstream, this phenomenon is called accelerated blood clearance (ABC). In the present study, we focused on the immune system responsible for the ABC phenomenon. PEGylated liposomes were preadministered to BALB/c mice and [(3)H]-labeled ones were then administered to them 3 days after the preadministration. Consistent with our previous results, the preadministration with PEGylated liposomes triggered the rapid clearance of [(3)H]-labeled PEGylated liposomes from the bloodstream, but that with PEGylated liposomes encapsulating doxorubicin (Dox) did not. In addition, we found that the ABC phenomenon was observed when a mixture of free Dox and PEGylated liposomes was preadministered. These data indicate that immune cells responsible for the ABC phenomenon might be selectively damaged by the Dox encapsulated in PEGylated liposomes. The ABC phenomenon was also observed in BALB/c nu/nu mice, but not in BALB/c SCID mice. The amount of anti-PEG IgM antibody induced by the stimulation with the PEGylated liposomes was significantly increased in the BALB/c nu/nu mice, but not in the BALB/c SCID ones. These data indicate that a T cell-independent B cell response would play a significant role in the ABC phenomenon. Furthermore, the present study suggests that PEGylated liposomes might be recognized by B cells as a thymus-independent type 2 (TI-2) antigen. The present study provides important information for the future development of liposomal medicines.

Development of double-stranded siRNA labeling method using positron emitter and its in vivo trafficking analyzed by positron emission tomography.

Pharmacokinetic study of small interfering RNA (siRNA) is an important issue for the development of siRNAs for use as a medicine. For this purpose, a novel and favorable positron emitter-labeled siRNA was prepared by amino group-modification using N-succinimidyl 4-[fluorine-18] fluorobenzoate ([(18)F]SFB), and real-time analysis of siRNA trafficking was performed by using positron emission tomography (PET). Naked [(18)F]-labeled siRNA or cationic liposome/[(18)F]-labeled siRNA complexes were administered to mice, and differential biodistribution of the label was imaged by PET. The former was cleared quite rapidly from the bloodstream and excreted from the kidneys; but in contrast, the latter tended to accumulate in the lungs. We also confirmed the biodistribution of fluorescence-labeled naked siRNA and cationic liposome/siRNA complexes by use of a near-infrared fluorescence imaging system. As a result, a similar biodistribution was observed, although quantitative data were obtained only by planar positron imaging system (PPIS) analysis but not by fluorescence in vivo imaging. Our results indicate that PET imaging of siRNA provides important information for the development of siRNA medicines.

[Elucidation of accelerated blood clearance phenomenon caused by repeat injection of PEGylated nanocarriers].

Liposomes modified with polyethylene glycol (PEG) can stably exist in the bloodstream because the PEG on the liposomes attracts a water shell to the liposomal surface. Since these liposomes are long circulating nanocarriers, they are used as drug and gene delivery tools. Repeat injection of PEGylated liposomes, however, is known to induce the accelerated blood clearance (ABC) phenomenon. In the ABC phenomenon, PEGylated liposomes that are injected subsequent to the first injection are cleared rapidly from the bloodstream and accumulate in the liver, resulting in loss of their long-circulating characteristics. The induction of ABC phenomenon is related to the production of anti-PEG IgM from splenic B cells. To elucidate the mechanism of the phenomenon, we firstly examined the relationship between the induction of ABC phenomenon and the concentration of PEGylated liposomes, and observed that the high dose of those did not induce the phenomenon. Next, we investigated whether polymeric micelles trigger ABC phenomenon or not. Finally, the size-dependency of ABC phenomenon was investigated by use of variously sized PEGylated liposomes and polymeric micelles having PEG chains. Our data suggest that the initiation of ABC phenomenon would be size-dependent, and particles smaller than 30 nm did not induce ABC phenomenon. We anticipate that the elucidation of the ABC phenomenon will be helpful for the development of DDS formulations.

In vivo distribution of liposome-encapsulated hemoglobin determined by positron emission tomography.

Positron emission tomography (PET) is a noninvasive imaging technology that enables the determination of biodistribution of positron emitter-labeled compounds. Lipidic nanoparticles are useful for drug delivery system (DDS), including the artificial oxygen carriers. However, there has been no appropriate method to label preformulated DDS drugs by positron emitters. We have developed a rapid and efficient labeling method for lipid nanoparticles and applied it to determine the movement of liposome-encapsulated hemoglobin (LEH). Distribution of LEH in the rat brain under ischemia was examined by a small animal PET with an enhanced resolution. While the blood flow was almost absent in the ischemic region observed by [(15)O]H(2)O imaging, distribution of (18)F-labeled LEH in the region was gradually increased during 60-min dynamic PET scanning. The results suggest that LEH deliver oxygen even into the ischemic brain from the periphery toward the core of ischemia. The real-time observation of flow pattern, deposition, and excretion of LEH in the ischemic rodent brain was possible by the new methods of positron emitter labeling and PET system with a high resolution.

[Antineovascular gene therapy by Ago2 knockdown].

Small interfering RNA (siRNA), which induces sequence-dependent gene silencing, has been widely studied. We previously developed polycation liposomes (PCL) as carriers of plasmid DNA and succeeded in showing their potent gene expression efficiency. In the present study, we optimized PCL for siRNA transfection and used it to determine the role of Argonaute2 (Ago2), a main constitution protein of RNA-induced silencing complex (RISC), on angiogenesis. We determined the biological effect of Ago2 knockdown on the angiogenic potential of endothelial cells. Human umbilical vein endothelial cells (HUVECs) stimulated with cytokines including vascular endothelial growth factor (VEGF) were used as an in vitro angiogenesis model. Our data showed that Ago2 knockdown using polycation liposomal Ago2-siRNA (siAgo2) suppressed indispensable processes of angiogenesis, namely endothelial cell proliferation and tube formation. Furthermore, TUNEL staining indicated that the treatment with siAgo2 increased apoptotic cells in comparison to that with control siRNA. These results might be caused by disorder of microRNA system. Next, we attempted to construct systemic siRNA delivery system targeting to angiogenic vessels. Synthetic siRNA was incorporated in polycation liposomes modified with polyethyleneglycol (PEG) and the functional peptide on their surface. Peptide-modified liposomes enhanced cellular uptake of siRNA in comparison with non-modified liposomes. Thus APRPG-modified liposomal siAgo2 may be useful for tumor treatment.

Particle size-dependent triggering of accelerated blood clearance phenomenon.

A repeat-injection of polyethylene glycol-modified liposomes (PEGylated liposomes) causes a rapid clearance of them from the blood circulation in certain cases that is referred to as the accelerated blood clearance (ABC) phenomenon. In the present study, we examined whether polymeric micelles trigger ABC phenomenon or not. As a preconditioning treatment, polymeric micelles (9.7, 31.5, or 50.2 nm in diameter) or PEGylated liposomes (119, 261 or 795 nm) were preadministered into BALB/c mice. Three days after the preadministration [(3)H]-labeled PEGylated liposomes (127 nm) as a test dose were administered into the mice to determine the biodistribution of PEGylated liposomes. At 24h after the test dose was given, accelerated clearance of PEGylated liposomes from the bloodstream and significant accumulation in the liver was observed in the mice preadministered with 50.2-795 nm nanoassemblies (PEGylated liposomes or polymeric micelles). In contrast, such phenomenon was not observed with 9.7-31.5 nm polymeric micelles. The enhanced blood clearance and hepatic uptake of the test dose (ABC phenomenon) were related to the size of triggering nanoassemblies. Our study provides important information for developing both drug and gene delivery systems by means of nanocarriers.

Antineovascular therapy with angiogenic vessel-targeted polyethyleneglycol-shielded liposomal DPP-CNDAC.

Causing damage to angiogenic vessels is a promising approach for cancer chemotherapy. The present study is a codification of a designed liposomal drug delivery system (DDS) for antineovascular therapy (ANET) with 2'-C-cyano-2'-deoxy-1-beta-D-arabino-pentofuranosylcytosine (CNDAC). The authors have previously reported that liposomalized 5'-O-dipalmitoylphosphatidyl CNDAC (DPP-CNDAC), a phospholipid derivative of the novel antitumor nucleoside CNDAC, is quite useful for ANET. DPP-CNDAC liposomes modified with APRPG, a peptide having affinity toward angiogenic vessels, efficiently suppressed tumor growth by damaging angiogenic endothelial cells. In the present study, the authors masked the hydrophilic moiety of DPP-CNDAC, namely, CNDAC, on the liposomal surface with APRPG-polyethyleneglycol (PEG) conjugate to improve the availability of DPP-CNDAC liposomes. The use of the APRPG-PEG conjugate attenuated the negative zeta-potential of the DPP-CNDAC liposomes and reduced the agglutinability of them in the presence of serum. These effects improved the blood level of DPP-CNDAC liposomes in colon 26 NL-17 tumor-bearing BALB/c male mice, resulting in enhanced accumulation of them in the tumor. Laser scanning microscopic observations indicated that APRPG-PEG-modified DPP-CNDAC liposomes (LipCNDAC/APRPG-PEG) colocalized with angiogenic vessels and strongly induced apoptosis of tumor cells, whereas PEG-modified DPP-CNDAC liposomes (LipCNDAC/PEG) did not. In fact, LipCNDAC/APRPG-PEG suppressed the tumor growth more strongly compared to LipCNDAC/PEG and increased significantly the life span of the mice. The present study is a good example of an effective liposomal DDS for ANET that is characterized by: (i) phospholipid derivatization of a certain anticancer drug to suit the liposomal formulation; (ii) PEG-shielding for masking undesirable properties of the drug on the liposomal surface; and (iii) active targeting to angiogenic endothelial cells using a specific probe.

Synthesis and evaluation of a novel lipid-peptide conjugate for functionalized liposome.

A novel lipid analog based on amino acids for liposome modification was developed. It consisted of three different kinds of amino acid derivatives and two fatty acids, and can react directly with the peptide synthesized first on resin by Fmoc solid-phase synthesis. In this study, lipid analog conjugated with HIV-TAT peptide (domain of human immunodeficiency virus TAT protein) was synthesized and successfully incorporated into liposome. The liposome containing the lipopeptide bearing HIV-TAT exhibited efficient cellular uptake.