Facile Separation of PEGylated Liposomes Enabled by Anti-PEG scFv.

PEGylated nanocarriers have gained increasing attention due to reduced toxicity and enhanced circulation compared with free drugs. According to guidances of drug regulatory departments worldwide, it is crucial to determine free and liposomal drug concentrations; however, the conventional used separation methods including dialysis, ultrafiltration, and solid-phase extraction (SPE) have drawbacks of time-consuming, drug leakage, environmental pollution or error bias of trace level drug. Here we developed a facile PEG-scFv-based separation method combined with HPLC to quantify free doxorubicin (DOX) and liposomal DOX in plasma. Anti-PEG single chain variable fragment antibody (PEG-scFv) was adopted to sediment PEGylated liposomes by simple incubation and low speed centrifugation. Compared to SPE, it demonstrated sufficient accuracy and sensitivity to evaluate free and liposomal DOX with intact liposomes. Therefore, it can serve as an alternative approach of SPE, which is suitable for quality assessment and pharmacokinetics evaluation of PEGylated liposomal drugs and possible other PEGylated nanocarriers.

Deciphering Protein Corona by scFv-Based Affinity Chromatography.

It remains challenging to precisely decipher the structural and functional characteristics of protein coronas. To overcome the drawbacks frequently occurring in the traditional separation methods, an anti-PEG single-chain variable fragment (PEG-scFv) based affinity chromatography (AfC) was developed to achieve precise and efficient separation of protein coronas on PEGylated liposomes (sLip). His-tagged PEG-scFv could readily capture sLip without affecting protein corona compositions, and separate sLip/protein complex from plasma protein aggregates and endogenous vesicles through the Ni-NTA column. AfC demonstrated 43-fold higher protein corona collecting efficiency than centrifugation, which was extremely crucial for separation of in vivo protein coronas due to the limitation of sample size. AfC evaded contamination by endogenous vesicles and protein aggregates occurring in centrifugation, and reserved the loosely bound proteins, providing an unprecedented approach to deeply decipher protein coronas. The scFv-based AfC also paves new avenues for the separation of protein coronas formed on other nanomedicines.

Factors Influencing the Immunogenicity and Immunotoxicity of Cyclic RGD Peptide-Modified Nanodrug Delivery Systems.

c(RGDyK)-modified liposomes have been shown to be immunogenic and potentially trigger acute systemic anaphylaxis upon repeated intravenous injection in both BALB/c nude mice and ICR mice. However, questions concerning the potential influence of mouse strains, immunization routes, drug carrier properties, and changes in c(RGDyK) itself on the immunogenicity and resultant immunotoxicity (anaphylaxis) of cyclic RGD peptide-modified nanodrug delivery systems remain unanswered. Here, these potential impact factors were investigated, aiming to better understand the immunological properties of cyclic RGD peptide-based nanodrug delivery systems and seek for solutions for this immunogenicity-associated issue. It was revealed that anaphylaxis caused by intravenous c(RGDyK)-modified drug delivery systems might be avoided by altering the preimmunization route (i.e., subcutaneous injection), introducing positively charged lipids into the liposomes and by using micelles or red blood cell membrane (RBC)-based drug delivery systems as the carrier. Different murine models showed different incidences of anaphylaxis following intravenous c(RGDyK)-liposome stimulation: anaphylaxis was not observed in both SD rats and BALB/c mice and was less frequent in C57BL/6 mice than that in ICR mice. In addition, enlarging the peptide ring of c(RGDyK) by introducing amino sequence serine-glycine-serine reduced the incidence of anaphylaxis post the repeated intravenous c(RGDyKSGS)-liposome stimulation. However, immunogenicity of cyclic RGD-modified drug carriers could not be reversed, although some reduction in IgG antibody production was observed when ICR mice were intravenously stimulated with c(RGDyK)-modified micelles, RBC membrane-based drug delivery systems and c(RGDyKSGS)-liposomes instead of c(RGDyK)-liposomes. This study provides a valuable reference for future application of cyclic RGD peptide-modified drug delivery systems.

Treatment of Lung Cancer by Peptide-Modified Liposomal Irinotecan Endowed with Tumor Penetration and NF-κB Inhibitory Activities.

Current chemotherapy for lung cancer achieved limited efficacy due to poor tumor targeting and tissue penetration. Another obstacle in the therapy is activated nuclear factor-κB (NF-κB) in tumor cells, which plays a crucial role in promotion of antiapoptosis and drug resistance. In this study, we utilized a multifunctional liposome loaded with irinotecan and surface modified with a cell-permeable NF-κB inhibitor (CB5005), for treatment of non-small-cell lung carcinoma. CB5005 downregulated the level of NF-κB-related protein in the nuclei of A549 cells, and increased cellular uptake of the modified liposomes. In vivo antitumor activity in mice bearing A549 xenografts revealed that modification with CB5005 significantly improved the tumor inhibition rate of irinotecan. Immunohistochemical assays showed that the tumors treated with CB5005-modified liposomes possessed the most apoptotic cells and the lowest level of p50 in the cell nuclei. These results strongly suggest that antitumor efficacy of the irinotecan liposomes can be enhanced by tumor-penetrating and NF-κB-inhibiting functions of CB5005. Consequently, CB5005-modified liposomes provide a possible synergistic therapy for lung cancer, and would also be appropriate for other types of tumors associated with elevated NF-κB activity.

Short Peptide-Mediated Brain-Targeted Drug Delivery with Enhanced Immunocompatibility.

Peptide ligands have been exploited as versatile tools to facilitate targeted delivery of nanocarriers. However, the effects of peptide ligands on immunocompatibility and therapeutic efficacy of liposomes remain intricate. Here, a short and stable brain targeted peptide ligand D8 was modified on the surface of doxorubicin-loaded liposomes (D8-sLip/DOX), demonstrating prolonged blood circulation and lower liver distribution in comparison to the long and stable D-peptide ligand DCDX-modified doxorubicin-loaded liposomes (DCDX-sLip/DOX) by mitigating natural IgM absorption. Despite the improved pharmacokinetic profiles, D8-sLip/DOX exhibited comparable brain targeting capacity in ICR mice and antiglioblastoma efficacy to DCDX-sLip/DOX in nude mice bearing intracranial glioblastoma. However, dramatic accumulation of DCDX-sLip/DOX in liver (especially during the first 8 h after intravenous injection) resulted in pathological symptoms, including nuclei swelling, necrosis of liver cells, and inflammation. These results suggest that short peptide ligand-mediated brain-targeted drug delivery systems possessing enhanced immunocompatibility are promising to facilitate efficient brain transport with improved biosafety.

Structure Reconstruction of LyP-1: Lc(LyP-1) Coupling by Amide Bond Inspires the Brain Metastatic Tumor Targeted Drug Delivery.

The stability and binding affinity of targeting ligands are very important in active targeting drug delivery. Herein we used LyP-1 peptide as a model peptide to investigate chemical-biology-based strategies in the design of peptide ligands for active targeting. LyP-1 is a short peptide cyclized with a disulfide bond. It can specifically bind to tumor cells and tumor lymphatics through the interaction with cell-surface protein p32/gC1qR. Lc(LyP-1), with a same sequence of LyP-1, is coupled by amide bond. It showed better cellular uptake and stability in blood in our previous research. Further, usually d-peptide demonstrates higher stability than l-peptide, and it may contribute to better active targeting ability in vivo. Herein, we designed a retro-inverso isomer of Lc(LyP-1), termed Dc(LyP-1), expecting to inspire brain metastatic tumor targeted drug delivery. However, although Lc(LyP-1) showed lower stability than Dc(LyP-1) in fresh rat bold serum, both the 4T1 cellular uptake capacity (89.20%) and p32 protein binding affinity (7.39 × 10-6) were significantly higher than those (33.41%, 1.37 × 10-5) of Dc(LyP-1). Further, Lc(LyP-1) modified PEG-PLA micelles displayed much higher in vivo distribution in brain metastatic tumor than Dc(LyP-1). All results suggested that Lc(LyP-1) had a better performance than Dc(LyP-1) in brain metastatic tumor-targeted drug delivery.

A d-Peptide Ligand of Integrins for Simultaneously Targeting Angiogenic Blood Vasculature and Glioma Cells.

The current prognosis of glioma patients remains poor after intensive multimodal treatments, which is partially due to the existence of the blood-brain tumor barrier (BBTB). In the present study, a novel "bifunctional ligand" (termed DVS) was developed by retro-inverso isomerization. DVS is a ligand of integrins highly expressed on glioma cells and tumor neovasculature. DVS exhibited exceptional stability in serum and demonstrated significantly higher targeting efficiency for glioma and HUVEC cells compared with the parent L-peptide. As a result, DVS modified micelles (DVS-MS) exhibited high encapsulation efficiency of doxorubicin, ideal size distribution, and sustained release behavior of the payload. In vivo studies showed that DVS-MS could target and efficiently deliver fluorescence to tumor cells and tumor vasculature not only in the mice bearing subcutaneous tumors but also in those bearing intracranial tumors. Moreover, doxorubicin loaded DVS modified micelles exerted potent tumor growth inhibitory activity against subcutaneous and intracranial human glioma in comparison to drug loaded plain micelles and LVS modified micelles. Therefore, DVS appears to be a suitable targeting ligand with potential applications for glioma targeted drug delivery.

Glioma-Targeted Drug Delivery Enabled by a Multifunctional Peptide.

The rapid proliferation of glioma relies on vigorous angiogenesis for the supply of essential nutrients; thus, a radical method of antiglioma therapy should include blocking tumor neovasculature formation. A phage display selected heptapeptide, the glioma-initiating cell peptide GICP, was previously reported as a ligand of VAV3 protein (a Rho GTPase guanine nucleotide exchange factor), which is overexpressed on glioma cells and tumor neovasculature. Therefore, GICP holds potential for the multifunctional targeting of glioma (tumor cells and neovasculature). We developed GICP-modified micelle-based paclitaxel delivery systems for antiglioma therapy in vitro and in vivo. GICP and GICP-modified PEG-PLA micelles (GICP-PEG-PLA) could be significantly taken up by U87MG cells, a human cell line derived from malignant gliomas and human umbilical vein endothelial cells (HUVECs). Furthermore, GICP-PEG-PLA micelles demonstrated enhanced penetration in a tumor spheroid model in vitro in comparison to unmodified micelles. In vivo, DiR-loaded GICP-PEG-PLA micelles exhibited superior accumulation in the tumor region by targeting neovasculature and glioma cells in nude mice bearing subcutaneous glioma. When loaded with paclitaxel, GICP-PEG-PLA micelles could more effectively suppress tumor growth and neovasculature formation than unmodified micelles in vivo. Our results indicated that GICP could serve as a promising multifunctional ligand for glioma targeting.

Erythrocyte Membrane-Wrapped pH Sensitive Polymeric Nanoparticles for Non-Small Cell Lung Cancer Therapy.

The application of nano drug delivery systems (NDDSs) may enhance the effectiveness of chemotherapeutic drugs in vivo. However, the short blood circulation time and poor drug release profile in vivo are still two problems with them. Herein, by using red blood cell membrane (RBCm) wrapping and pH sensitive technology, we prepared RBCm wrapped pH sensitive poly(l-γ-glutamylcarbocistein)-paclitaxel (PGSC-PTX) nanoparticles (PGSC-PTX@RBCm NPs), to prolong the circulation time in blood and release PTX timely and adequately in acidic tumor environment. The PGSC-PTX NPs and PGSC-PTX@RBCm NPs showed spherical morphology with average sizes about 50 and 100 nm, respectively. The cytotoxicity of PGSC-PTX@RBCm NPs was considerably decreased compared with that of PGSC-PTX NPs. PTX release from PGSC-PTX and PGSC-PTX@RBCm NPs at pH 6.5 was remarkably higher than those at pH 7.4, respectively. The PGSC-PTX@RBCm NPs exhibited remarkably decreased uptake by macrophages than PGSC-PTX NPs. The area under the curve within 72 h (AUC0-72h) for is significantly higher than PGSC-PTX NPs. The PGSC-PTX@RBCm NPs also showed significantly stronger growth-inhibiting effect on tumor than PGSC-PTX NPs. These results indicated that PGSC-PTX@RBCm NPs have acidic drug release sensitivity, the characteristics of long circulation, and remarkable tumor growth inhibiting effect. This study may provide an effective strategy for improving the antitumor effect of NDDS.

iNGR-Modified Liposomes for Tumor Vascular Targeting and Tumor Tissue Penetrating Delivery in the Treatment of Glioblastoma.

The tumor vascular barrier and tumor stroma barrier become the two main obstacles in the in vivo delivery of nanomedicines. In this study, to overcome the two barriers, we used iNGR, a tumor-penetrating peptide, to modify the liposomes to increase their accumulation and penetration in tumor tissues. First, iNGR-modified sterically stabilized liposomes (iNGR-SSL) were prepared, which showed vesicle sizes of about 100 nm and narrow size distribution. The uptake of iNGR-SSL by U87MG cells and HUVECs were significantly more than that of unmodified liposome. The in vivo imaging study demonstrated that iNGR modification remarkably increased the accumulation of the liposome in orthotopic tumor tissues of animal model. The immunofluorescence staining analysis proved that iNGR-SSL could penetrate through tumor blood vessels and into the deep tumor tissues. The cytotoxicity of iNGR-modified doxorubicin-loaded liposomes (iNGR-SSL/DOX) on U87MG and HUVECs cells in vitro was significantly enhanced than that of unmodified doxorubicin-loaded liposomes (SSL/DOX). The iNGR-SSL/DOX also showed comparatively (p < 0.05) stronger cytotoxicity on tumor than SSL/DOX, which should be resulted from the increased tumor accumulation and penetration mediated by iNGR. This study proved that iNGR peptide modification might be an effective method to enhance the tumor penetrating ability of liposomes in tumor tissue and their antitumor effect.

Noninvasive delivery of oligonucleotide by penetratin-modified polyplexes to inhibit protein expression of intraocular tumor.

Our present study aimed to develop an antisense oligonucleotide (ASO) delivery system to achieve gene silencing in intraocular tumor via topical instillation. ASO specific for luciferase was chosen as model drug, polyamidoamine (PG5) was employed to condense ASO, and penetratin (Pene) was used to enhance cellular uptake. Nanoscale PG5/ASO/Pene polyplex was stabilized via noncovalent bonding. In vitro evaluations indicated that PG5/ASO/Pene exhibited improved cell-penetrating and gene silencing ability compared with naked ASO and PG5/ASO. Subcutaneous and orthotopic tumor models expressing luciferase were established in nude mice. After treated by PG5/ASO/Pene, immunohistochemical results of subcutaneous tumors showed significant inhibition of luciferase expression via peritumoral injection, and bioluminescence from orthotopic tumor was obviously weakened via topical instillation. To date, few works were successful in noninvasive treatment of intraocular diseases using antisense strategy, this penetratin-modified polyplex could be a promising vector to inhibit protein expression by effectively delivering ASOs into the eye.

D-SP5 Peptide-Modified Highly Branched Polyethylenimine for Gene Therapy of Gastric Adenocarcinoma.

Peptide-mediated targeting of tumors has become an effective strategy for cancer therapy. Retro-inverso peptides resist protease degradation and maintain their bioactivity. We used the retro-inverso peptide D(PRPSPKMGVSVS) (D-SP5) as a targeting ligand to develop gene therapy for gastric adenocarcinoma. D-SP5 has a higher affinity for human gastric adenocarcinoma (SGC7901) cells compared with that of its parental peptide, L(SVSVGMKPSPRP) (L-SP5). Polyethylenimine (PEI)/pDNA, polyethylene glycol (mPEG)-PEI/pDNA and D-SP5-PEG-PEI/pDNA were prepared for further study. Quantitative luciferase assays showed the transfection efficiency of D-SP5-PEG-PEI/pGL(4.2) was larger compared with that of mPEG-PEI/pGL(4.2). Flow cytometry assays revealed that the apoptosis rates of SGC7901 cells treated with D-SP5-PEG-PEI/pTRAIL were larger than mPEG-PEI/pTRAIL. Western blot assays indicated that the expression of tumor necrosis factor-related apoptosis inducing ligand (TRAIL) protein in SGC7901 cells treated with D-SP5-PEG-PEI/pTRAIL was higher compared with that in cells treated with mPEG-PEI/pTRAIL. In vivo pharmacodynamics study revealed that D-SP5-PEG-PEI/pTRAIL could inhibit the growth of gastric adenocarcinoma SGC7901 xenografts in nude mice. Our results demonstrate that D-SP5-PEG-PEI is a safe and efficient gene delivery vector with potential applications in antitumor gene therapy.

Retro-inverso CendR peptide-mediated polyethyleneimine for intracranial glioblastoma-targeting gene therapy.

The development of nonviral gene delivery vectors offers the potential to provide effective treatment for glioblastoma in the form of gene therapy. Here, we report the use of retro-inverso C-end rule (CendR) peptide D(RPPREGR) as a targeting ligand to prepare a D(RPPREGR)-PEG-PEI gene vector. D(RPPREGR) peptide specifically recognized the neuropilin-1 receptor that was overexpressed on U87 glioma cells, and showed enhanced tumor spheroid penetration ability. Compared with parental RGERPPR, D(RPPREGR) possessed improved biological stability and had a higher affinity for U87 glioma cells; it also showed enhanced penetration of the tumor spheroid. mPEG-PEI/pDNA and D(RPPREGR)-PEG-PEI/pDNA complexes were prepared and MTT assay results revealed that the cytotoxicity of D(RPPREGR)-PEG-PEI complexes was significantly lower than that of PEI complexes, with cell survival rates above 80%. Qualitative and quantitative in vitro transfection results revealed that D(RPPREGR)-PEG-PEI complex transfection efficiencies were 1.9 times higher than those of mPEG-PEI. Fluorescent imaging and frozen sections of brain tissue demonstrated that the D(RPPREGR) modification improved the in vivo transfection efficiency of mPEG-PEI in nude mice bearing U87 gliomas. An antiglioblastoma assay revealed that D(RPPREGR)-PEG-PEI carrying the therapeutic gene pORF-hTRAIL significantly prolonged the survival time of intracranial U87 glioma-bearing mice from 25 to 30 days. Therefore, D(RPPREGR)-PEG-PEI appears to be suitable for use as a safe and efficient gene delivery vehicle with potential applications in glioblastoma gene therapy.

Tumor-penetrating peptide mediation: an effective strategy for improving the transport of liposomes in tumor tissue.

Currently, the inefficient transport of liposomes in tumor tissue hinders their clinical application. Tumor-penetrating peptides (TPP) are a series of targeting peptides with the function of penetrating tumor blood vessels and tumor stroma. This work aimed to improve the penetration of liposomes in tumor tissues by TPP modification, thereby enhancing the antitumor effect. First, RPARPAR, a TPP, was modified to the surface of liposomes loaded with doxorubicin. The RPARPAR-modified liposomes (RPA-LP) and unmodified liposomes (LP) showed spherical morphology with average sizes about 90 nm. RPA-LP exhibited remarkably increased cellular accumulation by PC-3 tumor cells than LP as evidenced by the cellular uptake test. The in vivo imaging study confirmed that RPARPAR modification significantly increased the liposome accumulation in subcutaneous tumor tissues. RPA-LP could penetrate through tumor blood vessels and tumor stroma and into the deep tumor tissues as evidence by the immunofluorescence staining analysis. The cytotoxicity of RPARPAR-modified doxorubicin liposomes (RPA-LP-DXR) is considerably increased compared with that of doxorubicin liposomes (LP-DXR). The RPA-LP-DXR also showed significantly (p < 0.005) stronger growth-inhibiting effect on tumor than LP-DXR, possibly due to the tumor-penetrating ability of RPA-LP and targeted killing of tumor cells. This study proved that TPP mediation may be an effective strategy for improving the transport of liposomes in tumor tissue.

In vivo evaluation of an in-situ hydrogel system for vaginal administration.

The vaginal retention and local irritation of a carrageenan, poloxamer 407 and carbopol-based thermosensitive hydrogel system for vaginal drug delivery was assessed. Results showed that the residence of hydrogel in the mouse vagina following intravaginal administration was prolonged by carrageenan and further prolonged by the addition of a mucoadhesive component (carbopol). The optimal hydrogel formulation was proven to be safe for vaginal use in rabbits.

[Modification by wheat germ agglutinin delays the ocular elimination of liposome].

The purpose of this study is to explore the feasibility of wheat germ agglutinin (WGA) modified liposome as a vehicle for ophthalmic administration. Liposome loaded with 5-carboxyfluorescein (FAM) was prepared by lipid film hydration method. WGA was thiolated and then conjugated to the surface of the liposome via polyethylene glycol linker to constitute the WGA-modified and FAM-loaded liposome (WGA-LS/FAM). The amount of thiol groups on each WGA molecule was determined, and the bioactivity of WGA was estimated after it was modified to the surface of liposome. The physical and chemical features of the WGA-modified liposome were characterized and the ocular bioadhesive performance was evaluated in rats. The result showed that each thiolated WGA molecule was conjugated with 1.32 thiol groups. WGA-LS/FAM had a mean size of (97.40 +/- 1.39) nm, with a polydispersity index of 0.23 +/- 0.01. The entrapment efficacy of FAM was about (2.95 +/- 0.21)%, and only 4% of FAM leaked out of the liposome in 24 h. Erythrocyte agglutination test indicated that after modification WGA preserved the binding activity to glycoprotein. The in vivo ocular elimination of WGA-LS/FAM fitted first-order kinetics, and the elimination rate was significantly slower than that of the unmodified liposome, demonstrating WGA-modified liposome is bioadhesive and suitable for ophthalmic administration.

Combination of PEGylation and Cationization on Phospholipid-Coated Cyclosporine Nanosuspensions for Enhanced Ocular Drug Delivery.

Strong precorneal clearance mechanisms including reflex blink, constant tear drainage, and rapid mucus turnover constitute great challenges for eye drops for effective drug delivery to the ocular epithelium. In this study, cyclosporine A (CsA) for the treatment of dry eye disease (DED) was selected as the model drug. Two strategies, PEGylation for mucus penetration and cationization for potent cellular uptake, were combined to construct a novel CsA nanosuspension (NS@lipid-PEG/CKC) by coating nanoscale drug particles with a mixture of lipids, DSPE-PEG2000, and a cationic surfactant, cetalkonium chloride (CKC). NS@lipid-PEG/CKC with the mean size ∼173 nm and positive zeta potential ∼+40 mV showed promoted mucus penetration, good cytocompatibility, more cellular uptake, and prolonged precorneal retention without obvious ocular irritation. More importantly, NS@lipid-PEG/CKC recovered tear production and goblet cell density more efficiently than the commercial cationic nanoemulsion on a dry eye disease rat model. All results indicated that a combination of PEGylation and cationization might provide a promising strategy to coordinate mucus penetration and cellular uptake for enhanced drug delivery to the ocular epithelium for nanomedicine-based eye drops.

Glutathione-sensitive RGD-poly(ethylene glycol)-SS-polyethylenimine for intracranial glioblastoma targeted gene delivery.

BACKGROUND: Reductively reversible and hydrolytically degradable cationic polymers have been used as gene delivery systems. The present study aimed to enhance the low transfection efficiency caused by PEGylation by taking advantage of a nonviral vector containing a disulfide linkage. METHODS: The novel reducible targeted gene vector c(RGDyK)-poly(ethylene glycol)-SS-polyethylenimine (RGD-PEG-SS-PEI), representing a combination of RGD-PEG with PEI through a disulfide linkage, was synthesized and its reduction-sensitivity was tested in the presence of glutathione. The RGD-PEG-SS-PEI/pDNA complexes were formed and their stability was evaluated by agarose gel electrophoresis in both phosphate-buffered saline and Dulbecco's modified Eagle's medium with 10% serum. In vitro transfection efficiency and cell viability assay of the different polymers was performed for U87 cells using pEGFP-N2 and pGL4.2 reporter gene systems. RGD-PEG-SS-PEI/pDsRED-N1 and RGD-PEG-PEI/pDsRED-N1 complexes were injected intravenously into the U87 cell-bearing nude mice via their tail vein to investigate in vivo gene expression. RESULTS: RGD-PEG-SS-PEI has been synthesized successfully and its reduction-sensitivity was confirmed in the presence of glutathione. The RGD-PEG-SS-PEI/pDNA complexes demonstrated good stability in both conditions. In comparison with mPEG-PEI/pDNA for gene delivery, the RGD-PEG-SS-PEI/pDNA complex provided improved levels of transfection efficiency and reduced cytotoxicity when tested in U87 cells in vitro, and also enhanced levels of gene expression in the brains of intracranial U87 glioblastoma-bearing mice as demonstrated using dsRed gene transfer and bioimaging in vivo. CONCLUSIONS: The results of the present study suggest that RGD-PEG-SS-PEI represents a promising candidate for further study in glioblastoma and combined gene therapies.

Potent retro-inverso D-peptide for simultaneous targeting of angiogenic blood vasculature and tumor cells.

The application of tumor targeting ligands for the treatment of cancer holds the promise of enhanced efficacy and reduced toxicity. L-SP5 ((L)(SVSVGMKPSPRP)) is a peptide that recognizes tumor neovasculature but not normal blood vessels (Lee et al., Cancer Res.2007, 67, 10958-65). The current report presents the design and application of D-SP5 ((D)(PRPSPKMGVSVS)), a novel retro-inverso analogue of L-SP5. Peptides D-SP5 and parental L-SP5 are shown to compete for the same target sites of a yet unknown cellular target and possess a dual-targeting bioactivity for both activated endothelial cells (HUVEC) and several tumor cell lines. Cellular uptake experiments showed superior in vitro targeting abilities of D-SP5 compared with L-SP5, such as enhanced internalization into stimulated HUVEC or KB, U87, and SGC tumor cells. A radioligand receptor binding assay revealed a higher cell affinity of D-SP5 in all tested cell lines, with K(d) values for D-SP5 about 2-fold lower than for L-SP5. An up to 3-fold higher maximum binding capacity (B(max)) to cells of D-SP5 was noted. Fluorescein-labeled D-SP5 upon intravenous administration displayed strong association with tumor endothelium. D-SP5-conjugated PEG-DSPE micelles displayed enhanced tumor homing (evidenced by near-infrared in vivo imaging). When loaded with doxorubicin, D-SP5 micelles could markedly suppress tumor growth with higher efficacy than L-SP5 micelles both in vitro and in vivo in KB tumor xenografts. In summary, the data demonstrate that D-SP5 displays higher binding affinities toward tumor endothelium as well as tumor cells and enhanced tumor targeting capability in vitro and in vivo.

Fatty acid-based strategy for efficient brain targeted gene delivery.

PURPOSE: To investigate a fatty acid-based strategy for efficient brain targeted gene delivery and to understand mechanism(s) of this small molecule-mediated brain gene delivery strategy. METHODS: A series of fatty acids (FAs) were conjugated with polyethylenimine (PEI25k). A near-infrared fluorescence probe, IR820, was used to study in vivo and ex vivo brain targeting ability of these fatty acid-PEI conjugates (FA-PEIs). Brain uptake of FA-PEI25k/rhodamine-6-isothiocyanate (RITC)-labeled DNA nanoparticles was investigated via a fluorescence imaging method. Moreover, pEGFP was used as a model gene to study in vitro and in vivo transfection effect of the ideal FA-PEI25k conjugate. RESULTS: FA modification did not have interference with the complexation between DNA and the PEI25k. The FA-PEI25k conjugates showed excellent brain targeting ability compared with unmodified PEI25k. Among these FA-PEI25k conjugates studied, myristic acid (MC)-PEI25k showed sustained brain distribution profile and higher brain DNA uptake. Furthermore, MC-PEI25k/pEGFP nanoparticles was able to achieve efficient in vitro and in vivo gene transfection. GFP expression was observed at different brain regions in vivo. CONCLUSIONS: These results demonstrated that the small molecule fatty acid, particularly myristic acid-based brain gene delivery strategy, is promising to mediate efficient gene transfection in the brain.