PEGylated Poly(amidoamine) dendrimer-based dual-targeting carrier for treating brain tumors

A dual-targeting drug carrier (PAMAM-PEG-WGA-Tf) based on the PEGylated fourth generation (G = 4.0) PAMAM dendrimer with transferrin (Tf) and wheat germ agglutinin (WGA) on the periphery and doxorubicin (DOX) loaded in the interior was synthesized and its BBB penetration and tumor targeting properties were explored. DLS and TEM measurements revealed the size of PAMAM-PEG-WGA-Tf was in the range of 14-20 nm. It reduced the cytotoxicity of DOX to the normal cells greatly, while efficiently inhibited the growth rate of the C6 glioma cells. The assay of transport across the BBB showed that PAMAM-PEG-WGA-Tf delivered 13.5% of DOX in a period of 2 h, demonstrating an enhanced transport ratio as compared to the ratio of 8% for PAMAM-PEG-WGA, 7% for PAMAM-PEG-Tf and 5% for free DOX in the same period of time. The accumulation of DOX in the tumor site was increased due to the targeting effects of both Tf and WGA, leading to the complete breakage of the avascular C6 glioma spheroids in vitro.     

PEG化PAMAM树状大分子的合成及其作为药物载体的研究

研究经聚乙二醇(PEG)进行表面修饰的聚酰胺-胺树枝状大分子作为药物载体时对药物的包裹及释放能力。用经三氟乙基磺酸单甲氧基(Tresylate)活化的相对分子质量为5000的单甲氧基聚乙二醇(Tresylated MPEG-5000)对聚酰胺-胺G4.0-PAMAM树状大分子修饰,目标产物PEG化树状大分子用FT-IR1、H NMR进行结构表征。MTT研究其细胞毒性。通过包裹与释放实验研究该药物载体对抗癌药物甲氨蝶呤(MTX)的包裹及释放能力。每个修饰后的树状大分子可包裹33个抗癌药物甲氨蝶呤分子,细胞毒指数较低,释药速度减慢。修饰后的树状大分子与未PEG化的树状大分子载体相比具有更强的包裹能力,并具有一定的药物缓释功能;细胞毒性试验表明,其胞毒性与未PEG化的树状大分子相比明显偏低。     

PEGylated PAMAM dendrimer–doxorubicin conjugate-hybridized gold nanorod for combined photothermal-chemotherapy

We prepared pH-sensitive drug–dendrimer conjugate-hybridized gold nanorod as a promising platform for combined cancer photothermal-chemotherapy under in vitro and in vivo conditions. Poly(ethylene glycol)-attached PAMAM G4 dendrimers (PEG–PAMAM) were first covalently linked on the surface of mercaptohexadecanoic acid-functionalized gold nanorod (MHA-AuNR), with subsequent conjugation of anti-cancer drug doxorubicin (DOX) to dendrimer layer using an acid-labile-hydrazone linkage to afford PEG–DOX–PAMAM–AuNR particles. The particles with a high PEG–PAMAM dendrimer coverage density (0.28 per nm² AuNR) showed uniform sizes and excellent colloidal stability. In vitro drug release studies demonstrated that DOX released from PEG–DOX–PAMAM–AuNR was negligible under normal physiological pH, but it was enhanced significantly at a weak acidic pH value. The efficient intracellular acid-triggered DOX release inside of lysosomes was confirmed using confocal laser scanning microscopy analysis. Furthermore, the combined photothermal-chemo treatment of cancer cells using PEG–DOX–PAMAM–AuNR for synergistic hyperthermia ablation and chemotherapy was demonstrated both in vitro and in vivo to exhibit higher therapeutic efficacy than either single treatment alone, underscoring the great potential of PEG–DOX–PAMAM–AuNR particles for cancer therapy.     

In vitro enzymatic stability of dendritic peptides

PEGylated polyamidoamine (PAMAM) dendrimers as drug carriers have been a topic of interest because of their biomedically favorable features, including minimal toxicity, reduced immunogenicity, and excellent solubility in aqueous and most organic solutions. A PEG shell on dendrimer surface may provide steric hindrance, known as stealth properties of PEG, to stabilize drug molecules to be delivered. In this article, the effects of PEG and coupling sequence of drug, PEG, and dendrimer in modulating the stability of delivered drug molecules were evaluated. N-succinyl-Ala-Ala-Pro-Phe-p-nitroanilide was chosen as a model peptide. Dendritic peptides, that is, peptide-dendrimer, peptide-PAMAM-PEG, and peptide-PEG-dendrimer, were constructed based on Starbursttrade mark G3.0 PAMAM dendrimer and characterized by (1)H-NMR spectroscopy. Hydrolysis of dendritic peptides was catalyzed by alpha-chymotrypsin in pH 7.4 PBS buffer containing 5% DMF (v/v) at room temperature. The enzymatic stability of dendritic peptides was peptide-PAMAM-PEG > peptide-PAMAM > free peptide > peptide-PEG-PAMAM. The ratio of PEG/peptide could be reduced for increasing peptide loading while maintaining the delivered peptides' relatively high enzymatic stability. The quantitative analysis of dendritic peptide/enzyme interactions provided the understandings of the molecular structure/stability relationships of dendrimer/drug for the design of an optimal PEGylated dendrimer-based drug-delivery system.     

The targeted delivery of anticancer drugs to brain glioma by PEGylated oxidized multi-walled carbon nanotubes modified with angiopep-2

In this study, a dual-targeting drug delivery system based on PEGylated oxidized multi-walled carbon nanotubes (O-MWNTs) modified with angiopep-2 (O-MWNTs-PEG-ANG) was successfully developed for treatment of brain glioma. O-MWNTs can not only distribute in brains but also accumulate in tumors, and have ultrahigh surface area with remarkably high loading anticancer drug of doxorubicin (DOX), which was selected as drug carrier. Angiopep-2 can specifically combine to the low-density lipoprotein receptor-related protein (LRP) receptor overexpressed on the blood-brain barrier (BBB) and glioma cells, which was selected as targeting ligand. The cooperative dual-targeting to brain glioma by O-MWNTs-PEG-ANG was evaluated by intracellular tracking in vitro and fluorescence imaging in vivo, which demonstrated that the combination of O-MWNTs-PEG and angiopep-2 constituted an ideal dual-targeting drug delivery system. The anti-glioma effect of DOX-loaded O-MWNTs-PEG-ANG (DOX-O-MWNTs-PEG-ANG) was assessed by C6 cytotoxicity and median survival time of glioma bearing mice, which showed a better anti-glioma effect than DOX. The biological safety of O-MWNTs-PEG-ANG was evaluated by BCEC and C6 cytotoxicity, hematology analysis and CD68 immunohistochemical analysis, which proved O-MWNTs-PEG-ANG was good biocompatibility and low toxicity. The biological safety of DOX-O-MWNTs-PEG-ANG was evaluated by histopathological analysis, which suggested a lower cardiac toxicity than DOX. In conclusion, O-MWNTs-PEG-ANG is a promising dual-targeting carrier to deliver DOX for the treatment of brain tumor.     

新型多肽聚酰胺-胺型靶向药物载体的载药性能及细胞吸收和毒性

背景：前期研究通过噬菌体展示体内筛选方法获得了一条NCI-H460非小细胞肺癌特异结合的多肽(Lung cancer targeting peptide, LCTP),将该多肽与修饰的聚酰胺-胺型(Polyamidoamine, PAMAM)树枝状高分子材料连接制备了纳米靶向药物载体PAMAM-Ac-FITC-LCTP,该载体在体内外对非小细胞肺癌NCI-H460具有很好的靶向性。 目的：在前期研究基础上,进一步研究PAMAM-Ac-FITC-LCTP靶向载体对阿霉素的包埋、释放及其细胞吸收和毒性性能。 方法：以筛选到的多肽LCTP为靶向剂,构建了PAMAM-Ac-FITC-LCTP靶向载体。采用物理包埋法将PAMAM-Ac- FITC-LCTP与阿霉素连接,通过体外透析实验观察载体对药物的缓释功能,共聚焦显微镜观察细胞对药物的吸收。以游离阿霉素作为对照,MTT法观察载体载药后对NCI-H460细胞的作用。 结果与结论：PAMAM-Ac-FITC-LCTP对阿霉素的最大包埋率为7.46%。载体对药物具有明显的缓释作用,离子浓度、pH和温度对药物的释放具有影响,说明PAMAM-Ac-FITC-LCTP主要是通过静电相互作用与阿霉素结合。PAMAM-Ac- FITC-LCTP/阿霉素短时间内较单独药物更高效进入NCI-H460细胞,而复合物24 h 的细胞毒性与阿霉素对细胞的毒性基本一致。以上结果说明PAMAM-Ac-FITC-LCTP可能是一个肿瘤治疗和诊断中很有用的药物靶向传输载体。     

Preparation and cytotoxic activity of poly(ethylene glycol)-modified poly(amidoamine) dendrimers bearing adriamycin

We have developed poly(amidoamine) (PAMAM) dendrimers that have poly(ethylene glycol) (PEG) grafts at all dendrimer chain ends. To obtain PEG-modified dendrimers with sites for conjugation of anticancer drugs for this study, we prepared PAMAM G4 dendrimers that have a glutamic acid (Glu) residue at every chain end of dendrimer; PEG chains were attached to amino groups of Glu residues. We then combined the anticancer drug adriamycin to side chains of the Glu residues using an amide bond, [PEG-Glu(ADR)-G4], or hydrazone bond, [PEG-Glu(NHN-ADR)-G4]. For the dendrimers bearing adriamycin through amide linkage, adriamycin was released only slightly at pH 7.4 and 5.5. Although a negligible level of release occurred at pH 7.4 for dendrimers with adriamycin via hydrazone linkage, a remarkable extent of adriamycin release was induced at pH 5.5, which corresponds to the pH of late endosome. These adriamycin-bearing dendrimers showed much lower toxicity to HeLa cells than did free adriamycin. However, compared to PEG-Glu(ADR)-G4, PEG-Glu(NHN-ADR)-G4 exhibited 7 times higher cytotoxicity, suggesting the importance of pH-sensitive hydrazone linkage for high cytotoxicity. Furthermore, the PEG-modified dendrimers exhibited an equivalent level of toxicity to that of adriamycin-resistant SBC-3/ADR100 cells and their parent adriamycin-sensitive SBC-3 cells.     

Synthesis and characterization of thermoresponsive polyamidoamine–polyethylene glycol–poly(d,l-lactide) core–shell nanoparticles

This work describes the synthesis and characterization of novel thermoresponsive highly branched polyamidoamine–polyethylene glycol–poly(d,l-lactide) (PAMAM–PEG–PDLLA) core–shell nanoparticles. A series of dendritic PEG–PDLLA nanoparticles were synthesized through conjugation of PEG of various chain lengths (1500, 6000 and 12,000 g mol^?1) to polyamidoamine (PAMAM) dendrimer G3.0 and subsequent ring-opening polymerization of DLLA. The ninhydrin assay, ¹H NMR, Fourier transform infrared spectroscopy, dynamic light scattering and atomic force microscopy were used to characterize the structure and compositions of dendritic PEG–PDLLA nanoparticles. The sol–gel phase transition of aqueous dendritic PEG–PDLLA solutions was measured using UV–visual spectroscopy. According to our results dendritic PEG–PDLLA nanoparticles in aqueous solution can self-assemble into sub-micron/micron aggregates, the size of which is dependent on temperature and PEG–PDLLA chain length. Further, dendritic PEG–PDLLA solutions exhibit a sol–gel phase transition with increasing temperature. The constructed dendritic PEG–PDLLA nanoparticles possessed high cytocompatibility, which was significantly improved compared with PAMAM dendrimers. The potential of dendritic PEG–PDLLA nanoparticles for encapsulation of water-insoluble drugs such as camptothecin was demonstrated. The dendritic PEG–PDLLA nanoparticles we developed offer greater structural flexibility and provide a novel nanostructured thermoresponsive carrier for drug delivery.     

Glioma targeted delivery strategy of doxorubicin-loaded liposomes by dual-ligand modification

The blood-brain barrier (BBB) is the protective parclose of brain safety, but it is also the main obstacle of the drug delivery to cerebral parenchyma, which hamper therapy for brain diseases. In this work, a glioma targeted drug delivery system was developed through loading doxorubicin into Angiopep-2 and TAT peptide dual-modified liposomes (DOX-TAT-Ang-LIP). Low-density lipoprotein receptor-related protein-1 (LRP1) was one receptor overexpressed on both BBB and glioma cytomembranes. Angiopep-2, a specific ligand of LRP1, exhibited high LRP1 binding efficiency. Additionally, TAT could penetrate through cell membranes without selectivity via an unsaturated pathway. To avoid the receptor saturation of Angiopep-2, TAT was also conjugated on the surface of liposomes, providing that the liposomes not only have effective BBB penetrating effect, but also have the glioma targeting function. The prepared DOX liposomes appeared good stability and narrow dispersity in serum with a diameter of 90 nm, and exhibited sustained DOX release behaviors. The conjunctions of Angiopep-2 and TAT were confirmed by ¹H NMR spectra. The BBB model, cellular uptake observations, antiproliferation study, and the cell ultrastructure analyses suggested that DOX-TAT-Ang-LIP could not only penetrate through BBB via transcytosis, but also concentrate in glioma, then enter into glioma cells and finally result in the necrosis of glioma cells.     

Encapsulation of 2-methoxyestradiol within multifunctional poly(amidoamine) dendrimers for targeted cancer therapy

We report here a general approach to using multifunctional poly(amidoamine) (PAMAM) dendrimer-based platform to encapsulate a potential anticancer drug for targeted cancer therapy. In this approach, amine-terminated generation 5 (G5) PAMAM dendrimers were sequentially modified with fluorescein isothiocyanate (FI) and folic acid (FA) via covalent conjugation, followed by an acetylation reaction to neutralize the remaining amines of the dendrimer surfaces. The synthesized multifunctional dendrimers (G5.NHAc-FI-FA) were then used to complex a potential anticancer drug, 2-methoxyestradiol (2-ME) for targeted delivery of the drugs to cancer cells overexpressing high-affinity folic acid receptors (FAR). We show that the formed G5.NHAc-FI-FA/2-ME complexes with each dendrimer encapsulating approximately 3.7 2-ME molecules are water soluble and stable. In vitro release studies show that 2-ME complexed with the multifunctional dendrimers can be released in a sustained manner. 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay in conjunction with cell morphology observation demonstrates that the G5.NHAc-FI-FA/2-ME complexes can specifically target and display specific therapeutic efficacy to cancer cells overexpressing high-affinity FAR. Findings from this study suggest that multifunctional dendrimers may be used as a general drug carrier to encapsulate various cancer drugs for targeted therapy of different types of cancer.     

Angiopep-conjugated poly(ethylene glycol)-co-poly(ε-caprolactone) nanoparticles as dual-targeting drug delivery system for brain glioma

Dual-targeting nanoparticle drug delivery system was developed by conjugating Angiopep with PEG-PCL nanoparticles (ANG-NP) through bifunctional PEG to overcome the limitations of low transport of chemotherapeutics across the Blood-brain barrier (BBB) and poor penetration into tumor tissue. ANG-NP can target the low-density lipoprotein receptor-related protein (LRP) which is over-expressed on the BBB and glioma cells. Compared with non-targeting nanoparticles, a significantly higher amount of rhodamine isothiocyanate-labeled dual-targeting nanoparticles were endocytosed by U87 MG cells. The antiproliferative and cell apoptosis assay of paclitaxel-loaded ANG-NP (ANG-NP-PTX) demonstrated that ANG-NP-PTX resulted in enhanced inhibitory effects to U87 MG glioma cells. The transport ratios across the BBB model in vitro were significantly increased and the cell viability of U87 MG glioma cells after crossing the BBB was obviously decreased by ANG-NP-PTX. Enhanced accumulation of ANG-NP in the glioma bed and infiltrating margin of intracranial U87 MG glioma tumor-bearing in vivo model were observed by real time fluorescence image. In conclusion, Angiopep-conjugated PEG-PCL nanoparticles were prospective in dual-targeting drug delivery system for targeting therapy of brain glioma.     

Folate coupled poly(ethyleneglycol) conjugates of anionic poly(amidoamine) dendrimer for inflammatory tissue specific drug delivery

Folate receptor is overexpressed on the activated (but not quiescent) macrophages in both animal models and human patients with naturally occurring rheumatoid arthritis. The aim of this study was to prepare folate targeted poly(ethylene glycol) (PEG) conjugates of anionic dendrimer (G3.5 PAMAM) as targeted drug delivery systems to inflammation and to investigate its biodistribution pattern in arthritic rats. Folate-PEG-PAMAM conjugates, with different degrees of substitution were synthesized by a two-step reaction through a carbodiimide-mediated coupling reaction and loaded with indomethacin. Folate-PEG conjugation increased the drug loading efficiency by 10- to 20-fold and the in vitro release profile indicated controlled release of drug. The plasma pharmacokinetic parameters indicated an increased AUC, circulatory half-life and mean residence time for the folate-PEG conjugates. The tissue distribution studies revealed significantly lesser uptake by stomach for the folate-PEG conjugates, thereby limiting gastric-related side effect. The time-averaged relative drug exposure (r(e)) of the drug in paw for the folate-PEG conjugates ranged from 1.81 to 2.37. The overall drug targeting efficiency (T(e)) was highest for folate-PEG conjugate (3.44) when compared to native dendrimer (1.72). The folate-PEG-PAMAM conjugates are the ideal choice for targeted delivery of antiarthritic drugs to inflammation with reduced side-effects and higher targeting efficiency.     

Multi-functional liposomes having temperature-triggered release and magnetic resonance imaging for tumor-specific chemotherapy

For development of tumor-specific chemotherapy, we designed liposomes with temperature-triggered drug release and magnetic resonance imaging (MRI) functions. We prepared multi-functional liposomes by incorporating thermosensitive poly(2-ethoxy(ethoxyethyl)vinyl ether) chains with a lower critical solution temperatures around 40 °C and polyamidoamine G3 dendron-based lipids having Gd(3+) chelate residues into pegylated liposomes. These stable doxorubicin (DOX)-loaded liposomes retained DOX in their interior below physiological temperature but released DOX immediately at temperatures greater than 40 °C. They exhibited excellent ability to shorten the longitudinal proton relaxation time. When administered intravenously into colon 26 tumor-bearing mice, accumulated liposomes in tumors increased with time, reaching a constant level 8 h after administration by following T(1)-weighted MRI signal intensity in tumors. Liposome size affected the liposome accumulation efficiency in tumors: liposomes of about 100 nm diameter were accumulated more efficiently than those with about 50 nm diameter. Tumor size also affected accumulation: more efficient accumulation occurred in larger tumors. Tumor growth was strongly suppressed when liposomes loaded with DOX were administered intravenously into tumor-bearing mice and the tumor was heated mildly at 44 °C for 10 min at 8 h after administration. Multi-functional liposomes having temperature-triggered drug release and MRI functions might engender personalized chemotherapy, providing efficient patient-optimized chemotherapy.     

纳米纤维介导的紫杉醇/阿霉素序贯联合治疗SHg-44胶质瘤

背景：纳米纤维技术可同时担载多种药物,避开血脑屏障限制实现脑胶质瘤的序贯联合化疗。 目的：用乳液电纺法制备同时担载紫杉醇和阿霉素的聚乙二醇-聚乳酸共聚物纳米纤维并实现两种药物的序贯释放,探讨纳米纤维介导的紫杉醇和阿霉素序贯联合治疗SHg-44胶质瘤的效果及机制。 方法:实验分为4组,1640培养液对照组,1%阿霉素组,1%紫杉醇组,5%(阿霉素+紫杉醇)组。采用高效液相色谱法测定紫杉醇和阿霉素的体外释放情况。四甲基偶氮唑盐法检测纳米纤维介导的紫杉醇和阿霉素序贯治疗对SHg-44胶质瘤细胞的增殖抑制率;流式细胞仪检测法检测紫杉醇和阿霉素序贯治疗对SHg-44胶质瘤细胞的凋亡诱导作用。 结果与结论：纳米纤维介导的紫杉醇和阿霉素序贯治疗对SHg-44胶质瘤细胞具有明显的生长抑制及促凋亡作用,且作用效果好于单独药物应用。提示聚乙二醇-聚乳酸纳米纤维作为一种药物载体能提高紫杉醇和阿霉素对SHg-44胶质瘤细胞增殖抑制和诱导凋亡作用。     

Targeted delivery of chlorotoxin-modified DNA-loaded nanoparticles to glioma via intravenous administration

Gene therapy offers great potential for brain glioma. However, therapeutic genes could not reach glioma spontaneously. A glioma-targeting gene delivery system is highly desired to transfer exogenous genes throughout the tumor focus. In this study, the nanoscopic high-branching dendrimer, polyamidoamine (PAMAM), was selected as the main vector. Chlorotoxin (CTX), which has been demonstrated to bind specifically to receptor expressed in glioma, was exploited as the targeting ligand to conjugate PAMAM via bifunctional polyethyleneglycol (PEG), yielding PAMAM-PEG-CTX. The cellular uptake of CTX itself was observed apparently in C6 glioma cells, almost not in 293 cells. The modification of CTX could significantly increase the cellular uptake of vectors and the DNA-loaded nanoparticles (NPs) in C6 cells. The in vivo distribution of PAMAM-PEG-CTX/DNA NPs in the brain was higher than that of PAMAM/DNA NPs and PAMAM-PEG/DNA NPs. Furthermore, the gene expression of PAMAM-PEG-CTX/DNA NPs was higher and?broader in glioma than that of unmodified and PEG-modified counterparts. The TUNEL analysis showed a more wide-extended apoptosis in the CTX-modified group, compared to other groups including commercial temozolomide group. The median survival time of CTX-modified group and temozolomide group was 59.5 and 49 days, respectively, significantly longer than that of other groups. The results suggested that CTX could be exploited as a special glioma-targeting ligand, and PAMAM-PEG-CTX/DNA NPs is a potential non-viral delivery system for gene therapy of glioma via intravenous administration.     

Complexation of Mefenamic Acid by Low‐Generation PAMAM Dendrimers: Insight from NMR Spectroscopy Studies and Molecular Dynamics Simulations

The complexation of mefenamic acid (MA) with poly(amido amine) dendrimers of the second and third generation (PAMAM‐G2 and PAMAM‐G3) at pH 7.0 is studied by aqueous solubility experiments, DOSY and 2D‐NOESY spectroscopy, and fully atomistic molecular dynamics (MD) simulations. Solubility profiles account for the formation of MA:PAMAM complexes of the type 10:1 and 15:1, for PAMAM‐G2 and PAMAM‐G3, respectively, with a maximum solubilization enhancement of 14.6 mol of MA per mol dendrimer. Diffusion ordered sepectroscopy (DOSY) and nuclear Overhauser effect spectroscopy (NOESY) experiments suggest that MA association occurs through both external electrostatic interactions with the PAMAM surface and internal encapsulation into the deep dendrimer cavities. MD simulations are consistent with these experimental findings and show that the internal drug encapsulation is enhanced as the dendrimer generation increases. The involvement of internal and external interactions in the complexation of MA with low‐generation PAMAM dendrimers differs from the general behavior expected for acidic anionic guests, for which external electrostatic contacts with the positively charged PAMAM surface have been postulated as the most relevant factor for drug association.

     

Brain-targeting gene delivery and cellular internalization mechanisms for modified rabies virus glycoprotein RVG29 nanoparticles

A 29 amino-acid peptide derived from the rabies virus glycoprotein (RVG29) was exploited as a ligand for efficient brain-targeting gene delivery. RVG29 was modified on polyamidoamine dendrimers (PAMAM) through bifunctional PEG, then complexed with DNA, yielding PAMAM–PEG–RVG29/DNA nanoparticles (NPs). The NPs were observed to be uptaken by brain capillary endothelial cells (BCECs) through a clathrin and caveolae mediated energy-depending endocytosis. The specific cellular uptake can be inhibited by free RVG29 and GABA but not by nicotinic acetylcholine receptor (nAchR) agonists/antagonists, indicating RVG29 probably relates to the GABA_B receptor besides nAchR reported previously. PAMAM–PEG–RVG29/DNA NPs showed higher blood-brain barrier (BBB)-crossing efficiency than PAMAM/DNA NPs in an in vitro BBB model. In vivo imaging showed that the NPs were preferably accumulated in brain. The report gene expression of the PAMAM–PEG–RVG29/DNA NPs was observed in brain, and significantly higher than unmodified NPs. Thus, PAMAM–PEG–RVG29 provides a safe and noninvasive approach for the gene delivery across the BBB.     

Uniform brain tumor distribution and tumor associated macrophage targeting of systemically administered dendrimers

Effective blood–brain tumor barrier penetration and uniform solid tumor distribution can significantly enhance therapeutic delivery to brain tumors. Hydroxyl-functionalized, generation-4 poly(amidoamine) (PAMAM) dendrimers, with their small size, near-neutral surface charge, and the ability to selectively localize in cells associated with neuroinflammation may offer new opportunities to address these challenges. In this study we characterized the intracranial tumor biodistribution of systemically delivered PAMAM dendrimers in an intracranial rodent gliosarcoma model using fluorescence-based quantification methods and high resolution confocal microscopy. We observed selective and homogeneous distribution of dendrimer throughout the solid tumor (∼6 mm) and peritumoral area within fifteen minutes after systemic administration, with subsequent accumulation and retention in tumor associated microglia/macrophages (TAMs). Neuroinflammation and TAMs have important growth promoting and pro-invasive effects in brain tumors. The rapid clearance of systemically administered dendrimers from major organs promises minimal off-target adverse effects of conjugated drugs. Therefore, selective delivery of immunomodulatory molecules to TAM, using hydroxyl PAMAM dendrimers, may hold promise for therapy of glioblastoma.     

Doxorubicin conjugated to D-alpha-tocopheryl polyethylene glycol 1000 succinate (TPGS): conjugation chemistry, characterization, in vitro and in vivo evaluation

To develop a polymer-anticancer drug conjugate, D-alpha-tocopheryl polyethylene glycol 1000 succinate (TPGS) was employed as a carrier of doxorubicin (DOX) to enhance its therapeutic effects and reduce its side effects. Doxorubicin was chemically conjugated to TPGS. The molecular structure, drug loading efficiency, drug release kinetics and stability of the conjugate were characterized. The cellular uptake, intracellular distribution, and cytotoxicity were accessed by using MCF-7 breast cancer cells and C6 glioma cells as in vitro cell model. The conjugate showed higher cellular uptake efficiency and broader distribution within the cells. Judged by IC(50), the conjugate was found 31.8, 69.6, 84.1% more effective with MCF-7 cells and 43.9, 87.7, 42.2% more effective with C6 cells than the parent drug after 24, 48, 72 h culture, respectively. The in vivo pharmacokinetics and biodistribution were investigated after an i.v. administration at 5 mg DOX/kg body weight in rats. Promisingly, 4.5-fold increase in the half-life and 24-fold increase in the area-under-the-curve (AUC) of DOX were achieved for the TPGS-DOX conjugate compared with the free DOX. The drug level in heart, gastric and intestine was significantly reduced, which is an indication of reduced side effects. Our TPGS-DOX conjugate showed great potential to be a prodrug of higher therapeutic effects and fewer side effects than DOX itself.     

Dual targeting effect of Angiopep-2-modified, DNA-loaded nanoparticles for glioma

Gene therapy offers a promising cure of brain glioma and tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) is able to induce cell apoptosis of glioma selectively without affecting the normal cells. In this study, the nanoscopic high-branching dendrimer, polyamidoamine (PAMAM), was selected as the principal vector. Angiopep-2, which can target to the low-density lipoprotein receptor-related protein-1 (LRP1) expressed on BCECs and glial cells, was exploited as the targeting ligand to conjugate PAMAM via bifunctional polyethyleneglycol (PEG) and then complexed with the DNA, designated as PAMAM-PEG-Angiopep/DNA nanoparticles (NPs). The cellular uptake mechanism explored in glial cells showed that the DNA of PAMAM-PEG-Angiopep/DNA NPs entered into the nuclei through the endosome/lysosome pathway. The in?vivo biodistribution of PAMAM-PEG-Angiopep/DNA NPs in the brain especially the tumor site was higher than that of PAMAM-PEG/DNA NPs and PAMAM/DNA NPs. Furthermore, the TUNEL analysis showed a more wide-extended apoptosis in the PAMAM-PEG-Angiopep/pORF-TRAIL NPs treated group, compared to other groups including commercial Temozolomide-treated one. The median survival time of PAMAM-PEG-Angiopep/pORF-TRAIL NPs and Temozolomide treated on brain tumor-bearing mice was 61 and 49 days respectively, significantly longer than that of other groups. Besides, the NPs suggested low cytotoxicity after in?vitro transfection. Thus, the results showed that Angiopep-2 could be exploited as a specific ligand to cross the BBB and targeted to glial cells, and PAMAM-PEG-Angiopep/DNA NPs can be a potential non-viral delivery system for gene therapy of glial tumor.