Anginex-conjugated liposomes for targeting of angiogenic endothelial cells

Identification of a tumor angiogenesis specific ligand would allow targeting of tumor vasculature. Lipidic vehicles can be used to deliver therapeutic agents for treatment of disease or contrast agents for molecular imaging. A targeting ligand would allow specific delivery of such formulations to angiogenic sites, thereby reducing side effects and gaining efficiency. Anginex, a synthetic 33-mer angiostatic peptide, has been described to home angiogenically activated endothelium, suggesting an ideal candidate as targeting ligand. To investigate this application of anginex, fluorescently labeled paramagnetic liposomes were conjugated with anginex. Using phase contrast and fluorescence microscopy as well as magnetic resonance imaging (MRI), we demonstrate that anginex-conjugated liposomes bind specifically to activated endothelial cells, suggesting application as an angiogenesis targeting agent for molecular targeting and molecular imaging of angiogenesis-dependent disease.     

Antibody-based targeting of the tumor vasculature

Conventional cytotoxic therapies of cancer often suffer from a lack of specificity, leading to a poor therapeutic index and considerable toxicities to normal organs. An elegant way to overcome the disadvantages of conventional tumor therapy is the selective delivery of therapeutics to the tumor site by their conjugation to a carrier molecule specific for a tumor-associated molecular marker. Markers expressed on the tumor's vasculature represent particularly attractive targets for a site-specific pharmacodelivery due to their inherent accessibility for blood-borne agents and the various therapeutic options that they allow, ranging from intraluminal blood coagulation to the recruitment of immune cells. In this review, we will outline advances in the preclinical and clinical evaluation of antibody-based vascular targeting agents, describe technologies for the discovery of novel vascular targets and discuss future prospects for vascular targeting applications.     

A novel strategy of selective gene delivery by using a uniform magnetic field

The application of a magnetic field to enhance the transfection efficiency has been reported to be mainly dependent on the magnetic force generated by a magnetic field gradient to attract paramagnetic bead-conjugated carrier and polynucleotide complexes. This strategy has the advantage of targeting a point or an area on the culture vessel. However, it is difficult to target deeply placed tissues in vivo. Uniform magnetic field-correlated effect is applicable to such a purpose. Here, we attempted to establish a novel procedure for uniform magnetic field-dependent enhancement of transfection efficiency. We examined the effect of a 1.5 mT uniform magnetic field on cellular reactive oxygen species (ROS) level and transfection efficiency mediated by a ROS-sensitive transfection carrier. Our experimental results revealed that a 1.5 mT uniform magnetic field transiently decreased cellular ROS levels and strongly enhanced transfection efficiency mediated by polyethylenimine (PEI). The uniform magnetic field-dependent enhancement of PEI-mediated in vivo transfection was confirmed in the livers of mice. Local intensification of a uniform magnetic field in a culture dish resulted in selective gene delivery into cells on the target area. Although further examination and improvement are necessary for this procedure, our findings provide a novel option for spatial control of gene delivery.     

Attaching histidine-tagged peptides and proteins to lipid-based carriers through use of metal-ion-chelating lipids

The therapeutic potential of selected peptides and proteins is enormous, with applications ranging from use as therapeutic vaccines, as modulators of intracellular signaling pathways and as highly selective agents capable of recognizing unique extracellular targets. We have been pursuing development of hybrid lipid-based carrier formulations designed to take advantage of the therapeutic benefits of peptides selected for their ability to act in a complementary fashion with the carrier system. In this regard, it is critical to have simple and versatile methods to promote and control the binding of diverse peptides to a broad range of carrier formulations. As demonstrated here, recombinant proteins and synthetic peptides containing poly-histidine residues (4 to 10) can be specifically bound to liposomes containing a metal-ion-chelating lipid, DOGS-NTA-Ni. The potential of this approach is demonstrated using two functional peptides, AntpHD-Cw3 (applications for vaccine production) and AHNP (specificity for Her-2 expressing cells).     

Antibody-drug therapeutic conjugates: Potential of antibody-siRNAs in cancer therapy

Codelivery is a promising strategy of targeted delivery of cytotoxic drugs for eradicating tumor cells. This rapidly growing method of drug delivery uses a conjugate containing drug linked to a smart carrier. Both two parts usually have therapeutic properties on the tumor cells. Monoclonal antibodies and their derivatives, such as Fab, scFv, and bsAb due to targeting high potent have now been attractive candidates as drug targeting carrier systems. The success of some therapeutic agents like small interfering RNA (siRNA), a small noncoding RNAs, with having problems such as enzymatic degradation and rapid renal filtration need to an appropriate carrier. Therefore, the aim of this study is to review the recent enhancements in development of antibody drug conjugates (ADCs), especially antibody–siRNA conjugates (SRCs), its characterizations and mechanisms in innovative cancer therapy approaches.     

Magnetizable needles and wires--modeling an efficient way to target magnetic microspheres in vivo

The in vivo targeting of tumors with magnetic microspheres is currently realized through the application of external non-uniform magnetic fields generated by rare-earth permanent magnets or electromagnets. Our theoretical work suggests a feasible procedure for local delivery of magnetic nano- and microparticles to a target area. In particular, thin magnetizable wires placed throughout or close to the target area and magnetized by a perpendicular external uniform background magnetic field are used to concentrate magnetic microspheres injected into the target organ's natural blood supply. The capture of the magnetic particles and the building of deposits thereof in the blood vessels of the target area were modeled under circumstances similar to the in vivo situation. This technique could be applied to magnetically targeted cancer therapy or magnetic embolization therapy with magnetic particles that contain anticancer agents, such as chemotherapeutic drugs or therapeutic radioisotopes.     

Investigation of parameters influencing incorporation,retention and cellular cytotoxicity in liposomal formulations of poorly soluble camptothecin

Abstract

Improving tumor delivery of lipophilic drugs through identifying advanced drug carrier systems with efficient carrier potency is of high importance. We have performed an investigative approach to identify parameters that affect liposomes’ ability to effectively deliver lipophilic camptothecin (CPT) to target cells. CPT is a potent anticancer drug, but its undesired physiological properties are impairing its therapeutic use. In this study, we have identified parameters influencing incorporation and retention of lipophilic CPT in liposomes, evaluating the effect of lipid composition, lipid chemical structure (head and tail group variations, polymer inclusion), zeta potential and anisotropy. Polyethyleneglycol (PEG) surface decoration was included to avoid liposome fusing and increase the potential for prolonged in vivo circulation time. The in vitro effect of the different carrier formulations on cell cytotoxicity was compared and the effect of active targeting of one of the formulations was evaluated. We found that a combination of liposome surface charge, lipid headgroup and carbon chain unsaturation affect CPT incorporation. Retention in liposomes was highly dependent on the liposomal surroundings and liposome zeta potential. Inclusion of lipid tethered PEG provided stability and prevented liposome fusing. PEGylation negatively affected CPT incorporation while improving retention. In vitro cell culture testing demonstrated that all formulations increased CPT potency compared to free CPT, while cationic formulations proved significantly more toxic to cancer cells that healthy cells. Finally, antibody mediated targeting of one liposome formulation further enhanced the selectivity towards targeted cancer cells, rendering normal cells fully viable after 1 hour exposure to targeted liposomes.     

Cell Labeling and Targeting with Superparamagnetic Iron Oxide Nanoparticles

Targeted delivery of cells and therapeutic agents would benefit a wide range of biomedical applications by concentrating the therapeutic effect at the target site while minimizing deleterious effects to off-target sites. Magnetic cell targeting is an efficient, safe, and straightforward delivery technique. Superparamagnetic iron oxide nanoparticles (SPION) are biodegradable, biocompatible, and can be endocytosed into cells to render them responsive to magnetic fields. The synthesis process involves creating magnetite (Fe₃O₄) nanoparticles followed by high-speed emulsification to form a poly(lactic-co-glycolic acid) (PLGA) coating. The PLGA-magnetite SPIONs are approximately 120 nm in diameter including the approximately 10 nm diameter magnetite core. When placed in culture medium, SPIONs are naturally endocytosed by cells and stored as small clusters within cytoplasmic endosomes. These particles impart sufficient magnetic mass to the cells to allow for targeting within magnetic fields. Numerous cell sorting and targeting applications are enabled by rendering various cell types responsive to magnetic fields. SPIONs have a variety of other biomedical applications as well including use as a medical imaging contrast agent, targeted drug or gene delivery, diagnostic assays, and generation of local hyperthermia for tumor therapy or tissue soldering.     

核定位信号肽修饰的抗肿瘤纳米载药体系

纳米载药体系作为一类具有可控性和靶向性的药物递送工具,可以保护生物分子药物免于细胞内快速酶促降解、免于快速血液清除,确保将生物分子药物安全递送至作用部位,从而有效改善药物的生物利用度,提高药物疗效并降低毒副作用,在生物医学领域具有广阔的应用前景,在功能材料研究和肿瘤靶向治疗研究中受到广泛关注.近年来,通过使用功能性生物...     

Structure-based discovery of small molecules targeting different surfaces of protein-kinase CK2

Protein kinase CK2 is an unfavorable pronostic marker in several cancers and has consequently emerged as a relevant therapeutic target. Several classes of ATP-competitive inhibitors have been identified, showing variable effectiveness. The molecular architecture of this multisubunit enzyme could offer alternative strategies to develop small molecule inhibitors targeting different surfaces of the kinase. Polyoxometalates were identified as original CK2 inhibitors targeting key structural elements located outside the active site. In addition, the CK2 subunit interface represents an exosite distinct from the catalytic cavity that can be targeted by peptides or small molecules to achieve functional effects.     

超顺磁氧化铁纳米探针用于磁共振分子成像的研究进展

分子影像学是近年来分子生物学和影像学相结合而形成的新型交叉学科,磁共振分子成像技术是分子影像学的重要手段之一,为临床医学诊断提供重要依据。但是由于不同组织之间的弛豫时间相互重叠等问题,导致较小的病变难以显示,磁共振造影剂能提高对软组织的分辨率,其中超顺磁性氧化铁纳米探针作为近年来发展起来的一种新型磁共振分子造影剂。由于具有敏感性、安全性、大的比表面积、高稳定性、靶向性等优点,近年来已成为国内外研究的热点之一。本文就超顺磁性氧化铁纳米探针的增强原理、制备工艺及靶向作用做一综述,以期为该技术的应用与研究提供借鉴和启示。     

Bio-encapsulation of microbial cells for targeted agricultural delivery

Biofertilizers, namely Rhizobium and biocontrol agents such as Pseudomonas and Trichoderma have been well established in the field of agricultural practices for many decades. Nevertheless, research is still going on in the field of inoculant production to find methods to improve advanced formulation and application in fields. Conventionally used solid and liquid formulations encompass several problems with respect to the low viability of microorganisms during storage and field application. There is also lack of knowledge regarding the best carrier in conventional formulations. Immobilization of microorganisms however improves their shelf-life and field efficacy. In this context, microencapsulation is an advanced technology which has the possibility to overcome the drawbacks of other formulations, results in extended shelf-life, and controlled microbial release from formulations enhancing their application efficacy. This review discusses different microencapsulation technologies including the production strategies and application thereof in agricultural practices.     

Promising approaches in using magnetic nanoparticles in oncology

The development of new and effective drug delivery systems for cancer treatment represents one of the significant challenges facing biomedical technology in the last decade. Among the different methods of drug delivery, magnetic drug targeting, by enabling specific delivery of chemotherapeutic agents through the use of magnetic nanoparticles and magnetic field gradient, could be a promising approach. Recently, magnetic nanoparticles have attracted additional attention because of their potential as contrast agents for magnetic resonance imaging and heat mediators for cancer therapy. This review summarizes these approaches in the use of magnetic nanoparticles in biomedical applications and novel methods for their optimization.     

Assessment of liposome delivery using scintigraphic imaging

Scintigraphic imaging is a valuable tool for the development of liposome-based therapeutic agents. It provides the ability to non-invasively track and quantitate the distribution of liposomes in the body. Liposomes labeled with technetium-99 m (99mTc) are particularly advantageous for imaging studies because of their favorable physical characteristics. Examples of how scintigraphic imaging studies have contributed to the evaluation and development of a variety of liposome formulations will be presented. These include liposomes for targeting processes with inflammation associated increased vascular permeability such as healing bone fractures and viral infections; liposomes for intraarticular delivery; and liposomes for delivery of agents to lymph nodes located in the extremities, the mediastinum and the peritoneum. Scintigraphic studies of liposome distribution are very informational and often suggest new drug delivery applications for liposomes.     

Liposome-enabled synergistic interaction of antimicrobial agents

Antimicrobial agents may interact synergistically when both drugs are present at the infected site for an adequate period of time at sufficient concentrations. Generally speaking, the agents in the combination show different tissue distributions and pharmacokinetics. By co-encapsulation of the drugs in a drug carrier, like liposomes, parallel tissue distributions of both drugs may be ensured and drug concentrations at the site of infection may be increased. In this presentation therapeutic efficacy of liposome-co-encapsulated gentamicin (GN) and ceftazidime (CZ) will be shown in a GN-CZ-susceptible and GN-CZ-resistant Klebsiella pneumoniae-pneumonia in rats.     

Broad-spectrum bioactivities of silver nanoparticles: the emerging trends and future prospects

There are alarming reports of growing microbial resistance to all classes of antimicrobial agents used against different infections. Also the existing classes of anticancer drugs used against different tumours warrant the urgent search for more effective alternative agents for treatment. Broad-spectrum bioactivities of silver nanoparticles indicate their potential to solve many microbial resistance problems up to a certain extent. The antibacterial, antifungal, antiviral, antiprotozoal, acaricidal, larvicidal, lousicidal and anticancer activities of silver nanoparticles have recently attracted the attention of scientists all over the world. The aim of the present review is to discuss broad-spectrum multifunctional activities of silver nanoparticles and stress their therapeutic potential as smart nanomedicine. Much emphasis has been dedicated to the antimicrobial and anticancer potential of silver nanoparticles showing their promising characteristics for treatment, prophylaxis and control of infections, as well as for diagnosis and treatment of different cancer types.     

Bio-encapsulation of microbial cells for targeted agricultural delivery

Biofertilizers, namely Rhizobium and biocontrol agents such as Pseudomonas and Trichoderma have been well established in the field of agricultural practices for many decades. Nevertheless, research is still going on in the field of inoculant production to find methods to improve advanced formulation and application in fields. Conventionally used solid and liquid formulations encompass several problems with respect to the low viability of microorganisms during storage and field application. There is also lack of knowledge regarding the best carrier in conventional formulations. Immobilization of microorganisms however improves their shelf-life and field efficacy. In this context, microencapsulation is an advanced technology which has the possibility to overcome the drawbacks of other formulations, results in extended shelf-life, and controlled microbial release from formulations enhancing their application efficacy. This review discusses different microencapsulation technologies including the production strategies and application thereof in agricultural practices.     

Protein complexes in transport vesicle targeting

The transport of material between membrane-bounded organelles in eukaryotic cells requires the accurate delivery of different classes of carrier vesicles to specific target compartments. Recent studies indicate that different targeting reactions involve distinct protein complexes that act to mark the target organelle for incoming vesicles. This review focuses on the proteins and protein complexes that have been implicated in various targeting reactions.     

Emerging concepts in designing next-generation multifunctional nanomedicine for cancer treatment

Nanotherapy has emerged as an improved anticancer therapeutic strategy to circumvent the harmful side effects of chemotherapy. It has been proven to be beneficial to offer multiple advantages, including their capacity to carry different therapeutic agents, longer circulation time and increased therapeutic index with reduced toxicity. Over time, nanotherapy evolved in terms of their designing strategies like geometry, size, composition or chemistry to circumvent the biological barriers. Multifunctional nanoscale materials are widely used as molecular transporter for delivering therapeutics and imaging agents. Nanomedicine involving multi-component chemotherapeutic drug-based combination therapy has been found to be an improved promising approach to increase the efficacy of cancer treatment. Next-generation nanomedicine has also utilized and combined immunotherapy to increase its therapeutic efficacy. It helps in targeting tumor immune response sparing the healthy systemic immune function. In this review, we have summarized the progress of nanotechnology in terms of nanoparticle designing and targeting cancer. We have also discussed its further applications in combination therapy and cancer immunotherapy. Integrating patient-specific proteomics and biomarker based information and harnessing clinically safe nanotechnology, the development of precision nanomedicine could revolutionize the effective cancer therapy.     

Fe3O4/ 生物可降解复合材料研究

磁性氧化铁纳米粒子因具有尺寸小、低毒性和超顺磁性等特点,已经引起了生物化工、医药工业领域的广泛关注。生物可降解高分子材料是生物医用高分子研究中最活跃的领域之一,已广泛用于外科手术缝合线,植入体材料及药物释放载体等。将Fe3O4和生物可降解高分子材料进行复合,可以扩大两者的应用范围,达到理想的治疗效果,并有望开创临床治疗的新时代。本文介绍了磁性四氧化三铁粒子的化学制备方法,包括共沉淀法、溶胶-凝胶法、微乳液法,并对各种方法的优缺点进行了比较;重点阐述了磁性壳聚糖,磁性聚乳酸,磁性PEG,磁性PCL复合材料的制备,及它们在酶的固定化、磁靶向药物及基因载体等医学领域的应用,显示了Fe3O4/生物可降解复合材料在医学领域的广阔应用前景;最后对复合材料走向临床应用所面临的问题及发展前景进行了讨论。