Nanoparticles In Tumor Tissue Research Articles

Versatile Bi2MoO6/Prussian Blue-Au nanoplatform for oxygen-self-produced and GSH-depleted enhanced sonodynamic efficacy

Deprivation of oxygen and scavenging of reactive oxygen species (ROS) severely restrict the antitumor efficiency of sonodynamic therapy (SDT). To address these challs, we report the Bi2MoO6/Prussian Blue-Au (BMO/PB-Au) nanosystem as piezoelectric sonosensitiser for highly efficient ROS production under ultrasonic irradiation. In this system, the nanosystem has catalase-like (CAT) and glutathione oxidase (GSHOD) catalytic activity, which can enhance SDT effectively by producing reactive oxygen species and consuming glutathione (GSH). While the narrow bandgap and heterojunctions contribute to the improved charge separation and charge recombination suppression of the piezoelectric semiconductor BMO, accelerating ROS generation. Packaging MCF-7 cancer cell membranes (CM) on the surface of BMO/PB-Au will effectively improve the enrichment of nanoparticles in tumor tissue. The in vivo results showed that the BMO/PB-Au@CM nanoplatform can effectively inhibit tumor growth through the enhanced SDT effect. Our findings provide a paradigm to rationally design hypoxia-relieve and GSH-depleted SDT platform to for promoting cancer therapy efficiency.

Decitabine/paclitaxel co-delivery systems modified with anti-PD-L1 antibodies mediate chemoimmunotherapy for Triple negative breast cancer

Triple-negative breast cancer (TNBC) is one of the major clinical problems to be solved urgently, because of its high malignancy, poor targeted therapy effect and easy occurrence of drug resistance and metastasis. Here, methyltransferase DNMT1 was identified as a key factor mediating PTX resistance for TNBC. Decitabine (DEC), an inhibitor of DNMT1, can inhibit the proliferation and metastasis of TNBC cells and reverse PTX resistance. In this study, we reported a new delivery system (DEC/PTX NPs@αPD-L1) co-loaded with DEC and PTX modified by anti-PD-L1 monoclonal antibody (αPD-L1), which can overcome drug resistance and metastasis through multi-mode synergistic effect. αPD-L1 increases the enrichment of nanoparticles in tumor tissue through active targeting effect, and blocks PD-L1 on the surface of TNBC cells, thereby activating anti-tumor immune while enhancing internalization of nanoparticles by tumor cells. Inside tumor cells, DEC inhibits EMT process and cancer stem cells to overcome PTX resistance and metastasis. PTX can not only exerts direct tumor killing effect, but also inhibit Treg cells from remodeling immune microenvironment, and induces efficient immunogenic death in cooperation with DEC. This delivery system, realizing tumor-specific synchronized chemoimmunotherapy, represents a promising therapeutic platform for TNBC.

Lipidic Formulations Inspired by COVID Vaccines as Smart Coatings to Enhance Nanoparticle-Based Cancer Therapy.

Recent advances in nanomedicine have led to the introduction and subsequent establishment of nanoparticles in cancer treatment and diagnosis. Nonetheless, their application is still hindered by a series of challenges related to their biocompatibility and biodistribution. In this paper, we take inspiration from the recently produced and widely spread COVID vaccines, based on the combinational use of ionizable solid lipid nanoparticles, cholesterol, PEGylated lipids, and neutral lipids able to incorporate mRNA fragments. Here, we focus on the implementation of a lipidic formulation meant to be used as a smart coating of solid-state nanoparticles. The composition of this formulation is finely tuned to ensure efficient and stable shielding of the cargo. The resulting shell is a highly customized tool that enables the possibility of further functionalizations with targeting agents, peptides, antibodies, and fluorescent moieties for future in vitro and in vivo tests and validations. Finally, as a proof of concept, zinc oxide nanoparticles doped with iron and successively coated with this lipidic formulation are tested in a pancreatic cancer cell line, BxPC-3. The results show an astonishing increase in cell viability with respect to the same uncoated nanoparticles. The preliminary results presented here pave the way towards many different therapeutic approaches based on the massive presence of highly biostable and well-tolerated nanoparticles in tumor tissues, such as sonodynamic therapy, photodynamic therapy, hyperthermia, and diagnosis by means of magnetic resonance imaging.

New approaches for enhancing the photosensitivity, antibacterial activity, and controlled release behavior of non-porous silica-titania nanoplatforms.

This research presents a new approach for the synthesis of inorganic nano-platforms containing >2 layers. Nano-platforms were characterized using scanning electron microscopy, X-ray diffraction, fluorescence and Fourier transform infrared spectroscopy, fluorescence microscopy, dynamic light scattering, thermogravimetric analysis, Brunauer-Emmett-Teller, etc. Since it has been reported that the maximum tolerable dose of non-porous silica nanoparticles (NPs) in in-vivo studies is higher than that of mesoporous silica, the non-porous silica was prepared. Curcumin (CUR) was trapped between the surfaces of the spherical non-porous silica and titania NPs (<100nm) as both fluorescent and therapeutic agents, thus resulting in increased loading capacity of the non-porous silica NPs, as well as providing significant photosensitivity, antibacterial activity, and controlled release. In addition, the surface of NPs was enriched with Methyl violet-10B (MV-10B), and Rhodamine B (RhB). Silica@CUR@titania exhibited approximately 9-fold higher fluorescence intensity than silica@CUR NPs. This finding enabled us to design nano-platforms with minimum toxic effect due to low contents of RhB for bioimaging applications. The antimicrobial efficiency of nano-platforms was evaluated against P. aeruginosa, E. coli, S. typhimurium, K. pneumonia, S. epidermidis, S. aureus, B. subtilis, B. cereus, and E. faecalis. It was concluded that titania markedly lowered the minimum inhibitory concentration values (MICs) of CUR against all bacteria except B. subtilis and P. aeruginosa. Theoretical simulation was also performed to clarify the accumulation of functionalized NPs in tumor tissue.

Effects of Particle Geometry for PLGA-Based Nanoparticles: Preparation and In Vitro/In Vivo Evaluation.

The physicochemical properties (size, shape, zeta potential, porosity, elasticity, etc.) of nanocarriers influence their biological behavior directly, which may result in alterations of the therapeutic outcome. Understanding the effect of shape on the cellular interaction and biodistribution of intravenously injected particles could have fundamental importance for the rational design of drug delivery systems. In the present study, spherical, rod and elliptical disk-shaped PLGA nanoparticles were developed for examining systematically their behavior in vitro and in vivo. An important finding is that the release of the encapsulated human serum albumin (HSA) was significantly higher in spherical particles compared to rod and elliptical disks, indicating that the shape can make a difference. Safety studies showed that the toxicity of PLGA nanoparticles is not shape dependent in the studied concentration range. This study has pioneering findings on comparing spherical, rod and elliptical disk-shaped PLGA nanoparticles in terms of particle size, particle size distribution, colloidal stability, morphology, drug encapsulation, drug release, safety of nanoparticles, cellular uptake and biodistribution. Nude mice bearing non-small cell lung cancer were treated with 3 differently shaped nanoparticles, and the accumulation of nanoparticles in tumor tissue and other organs was not statistically different (p > 0.05). It was found that PLGA nanoparticles with 1.00, 4.0 ± 0.5, 7.5 ± 0.5 aspect ratios did not differ on total tumor accumulation in non-small cell lung cancer.

Hyaluronic Acid Modified Au@SiO2@Au Nanoparticles for Photothermal Therapy of Genitourinary Tumors.

Bladder cancer and prostate cancer are the most common malignant tumors of the genitourinary system. Conventional strategies still face great challenges of high recurrence rate and severe trauma. Therefore, minimally invasive photothermal therapy (PTT) has been extensively explored to address these challenges. Herein, fluorescent Au nanoparticles (NPs) were first prepared using glutathione as template, which were then capped with SiO2 shell to improve the biocompatibility. Next, Au nanoclusters were deposited on the NPs surface to obtain Au@SiO2@Au NPs for photothermal conversion. The gaps between Au nanoparticles on their surface could enhance their photothermal conversion efficiency. Finally, hyaluronic acid (HA), which targets cancer cells overexpressing CD44 receptors, was attached on the NPs surface via 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride (EDC) chemistry to improve the accumulation of NPs in tumor tissues. Photothermal experiments showed that NPs with an average size of 37.5 nm have a high photothermal conversion efficiency (47.6%) and excellent photostability, thus exhibiting potential application as a PTT agent. The temperature of the NPs (100 μg·mL-1) could rapidly increase to 38.5 °C within 200 s and reach the peak of 57.6 °C with the laser power density of 1.5 W·cm-2 and irradiation time of 600 s. In vivo and in vitro PTT experiments showed that the NPs have high biocompatibility and excellent targeted photothermal ablation capability of cancer cells. Both bladder and prostate tumors disappeared at 15 and 18 d post-treatment with HA-Au@SiO2@Au NPs, respectively, and did not recur. In summary, HA-Au@SiO2@Au NPs can be used a powerful PTT agent for minimally invasive treatment of genitourinary tumors.

Glutathione Pulse Therapy: Promote Spatiotemporal Delivery of Reduction-Sensitive Nanoparticles at the "Cellular Level" and Synergize PD-1 Blockade Therapy.

Spatiotemporal delivery of nanoparticles (NPs) at the “cellular level” is critical for nanomedicine, which is expected to deliver as much cytotoxic drug into cancer cells as possible when NPs accumulate in tumors. However, macrophages and cancer‐associated fibroblasts (CAFs) that are present within tumors limit the efficiency of spatiotemporal delivery. To overcome this limitation, glutathion pulse therapy is designed to promote reduction‐sensitive Larotaxel (LTX) prodrug NPs to escape the phagocytosis of macrophages and penetrate through the stromal barrier established by CAFs in the murine triple negative breast cancer model. This therapy improves the penetration of NPs in tumor tissues as well as the accumulation of LTX in cancer cells, and remodels the immunosuppressive microenvironment to synergize PD‐1 blockade therapy. More importantly, a method is established that can directly observe the biodistribution of NPs between different cells in vivo to accurately quantify the target drugs accumulated in these cells, thereby advancing the spatiotemporal delivery research of NPs at the “cellular level.”

Investigation of the Distribution of Magnetic Nanoparticles in Tumor Tissues by the Method of Scanning Magnetic Force Nanotomography

The development of effective biomedical technologies using magnetic nanoparticles (MNPs) for the tasks of oncotherapy and nanodiagnostics requires the development and implementation of new methods for the analysis of micro- and nanoscale distributions of MNPs in the volume of cells and tissues. The paper presents a new approach to three-dimensional analysis of MNP distributions - scanning magnetic force nanotomography as applied to the study of tumor tissues. Correlative reconstruction of MNP distributions and nanostructure features of the studied tissues made it possible to quantitatively estimate the parameters of three-dimensional distributions of composite nanoparticles based on silicon and iron oxide obtained by femtosecond laser ablation and injected intravenously and intratumorally into tumor tissue samples of B16/F1 mouse melanoma. The developed technology based on the principles of scanning probe nanotomography is applicable for studying the features of three-dimensional micro- and nanoscale distributions of magnetic nanoparticles in biomaterials, cells and tissues of various types.

An Alternative Technique for Monitoring the Live Interaction of Monocytes and Tumor Cells with Nanoparticles in the Mouse Lung.

Nanomaterials are increasingly used for the diagnosis and treatment of cancer, including lung cancer. For the clinical translation of nano-based theranostics, it is vital to detect and monitor their accumulation in the tumor, as well as their interaction with tumor, immune cells, and the tumor microenvironment (TME). While high resolution microscopy of fixed tumor specimens can provide some of this information from individual thin slices, it cannot capture cellular events over time and lacks 3D information of the tumor tissue. On the other hand, in vivo optical procedures either fall short of providing the necessary cellular resolution, as in the case of epifluorescence optical imaging, or are very demanding, as for instance intravital lung microscopy. We describe an alternative approach to investigate nanoparticle-cell interactions in entire mouse lung lobes, by longitudinal live cell confocal microscopy at nanometer resolution. By filling the lung ex vivo with 1% agarose, we were able to stabilize the lung lobes and visualize the interaction of fluorescent cells and nanoparticles for at least 4 hours post mortem. This high resolution ex vivo live cell imaging approach is an easy 4D tool for assessing several dynamic processes in tumor tissue, such as the traffic of cells, shedding of extracellular vesicles (EVs), and the accumulation of nanoparticles in tumor tissue. Graphic abstract: Schematic of the workflow for live cell imaging in the mouse lung.

Quantitation method of loss powers using commercial magnetic nanoparticles based on superparamagnetic behavior influenced by anisotropy for hyperthermia

Local hyperthermia using magnetic nanoparticles has attracted attention as a less invasive cancer therapy. Accurate estimation of heat dissipation of magnetic nanoparticles is important for hyperthermia treatment. In this study, the magnetization properties and heat dissipation of Feraheme®, Resovist®, and Synomag®-D commercial magnetic nanoparticles was measured. The effective core diameter and anisotropy constant were estimated by the Langevin function taking into consideration the effect of anisotropy. The required frequency and intensity of an applied magnetic field with respect to the weight and concentration of magnetic nanoparticles in an assumed spherical tumor were estimated based on measurement and theory of magnetic relaxation. A method to quantitate realistic heat dissipation of magnetic nanoparticles in tumor tissue by measurement of their magnetization properties is introduced. Because the physical rotation of magnetic nanoparticles is inhibited in tumor tissue, the realistic heat dissipation is estimated by solidifying a mass of nanoparticles in an experimental sample. The specific loss power and intrinsic loss power as the heat dissipations of magnetic nanoparticles were estimated from the area of the magnetization curves. The results indicated that only the linear component of magnetization was associated with the loss powers. Our method to quantitate loss powers and the index for applied magnetic field will facilitate the clinical application of hyperthermia treatment using magnetic nanoparticles.

Effect of Acoustic Radiation Force on the Distribution of Nanoparticles in Solid Tumors.

Acoustic radiation force (ARF) might improve the distribution of nanoparticles (NPs) in tumors. To study this, tumors growing subcutaneously in mice were exposed to focused ultrasound (FUS) either 15 min or 4 h after the injection of NPs, to investigate the effect of ARF on the transport of NPs across the vessel wall and through the extracellular matrix. Quantitative analysis of confocal microscopy images from frozen tumor sections was performed to estimate the displacement of NPs from blood vessels. Using the same experimental exposure parameters, ARF was simulated and compared with the experimental data. Enhanced interstitial transport of NPs in tumor tissues was observed when FUS (10 MHz, acoustic power 234 W/cm2, 3.3% duty cycle) was given either 15 min or 4 h after NP administration. According to acoustic simulations, the FUS generated an ARF per unit volume of 2.0×106 N/m3. The displacement of NPs was larger when FUS was applied 4 h after NP injection compared with after 15 min. This study shows that ARF might contribute to a modest improved distribution of NPs into the tumor interstitium.

Targeted NIRF/MR dual-mode imaging of breast cancer brain metastasis using BRBP1-functionalized ultra-small iron oxide nanoparticles.

Tumor metastasis to brain is the main clinical manifestation of patients with advanced breast cancer, leading to poor survival prognosis. In order to detect the early incidence of brain metastasis, it is urgent to develop hypersensitive contrast agents for multimode imaging. In this study, PEG-phospholipids coated, a phage play derived peptide, BRBP1 peptide modified ultra-small iron oxide nanoparticles were prepared for targeted NIRF and MR imaging of breast cancer brain metastasis. The nanoparticles showed 10nm core-shell, high relaxivity values and photon emission efficiency in vitro. The nanoparticles offered a T2 contrast imaging effect and near-infrared fluorescent signal enhancement. Compared with control peptide modified nanoparticles, the MR/NIRF imaging signal of BRBP1-modified nanoparticles in tumor tissue was significantly enhanced, which should be induced by the targeting ability of BRBP1 peptide. These results indicated that BRBP1-SPIO@mPEG (DiR) nanoparticles could be applied as an effective targeted delivery system for diagnosis of breast cancer brain metastasis.

Involvement of Caveolin-1-mediated transcytosis in the intratumoral accumulation of liposomes

For achieving efficient cancer treatment, it is important to elucidate the mechanism responsible for the accumulation of nanoparticles in tumor tissue. Recent studies suggest that nanoparticles are not delivered merely through gaps between tumor endothelial cells. We previously reported that the maturation of the vascular structure by the vascular endothelial cell growth factor receptor 2 (VEGFR2) using a previously developed siRNA delivery technology (RGD-MEND) significantly enhanced the accumulation of nanoparticles in types of cancers that area vessel-rich (renal cell carcinoma). This result was completely inconsistent with the generally accepted theory of the enhanced permeability and retention (EPR) effect. We hypothesized that a caveolin-1 (Cav1)-mediated transcellular route would be involved with the penetration of nanoparticles into tumor vasculature. To reveal the exact mechanism responsible for this enhancement, we observed the delivery of long-circulating liposomes (LPs) after Cav1 was co-suppressed by RGD-MEND with VEGFR2. The enhanced delivery of LPs by siRNA against VEGFR2 (siVEGFR2) was accompanied by the elevated expression of the Cav1 protein. In addition, Cav1 knockdown by siRNA against Cav1 (siCav1) canceled the enhanced delivery of LPs by siVEGFR2. The injection of siCav1 had no effect on the formation of alpha smooth muscle actin or vascular endothelial cell adhesion molecules. These results suggest that a Cav1-induced transcellular route and not a paracellular route, at least partially, contributes to the accumulation of nanoparticles in tumors.

Electron microscopic characteristic of local immune processes during regression of developed experimental tumors under the influence of magnetite nanoparticles.

e14179 Background: Previously, regression of the developed transplanted tumors under the influence of magnetite nanoparticles (NPs) as monofactor was shown. The purpose of the study was to reveal signs of intercellular interactions in the zone of tumors regressed under the influence of magnetite NPs. Methods: Experiments were carried out on 14 white outbred male rats (180-200 g) with transplanted sarcoma 45 of an initial volume of 0.7-1.3 cm3. After 6 peritumoral injections of magnetite NPs (10 ± 2 nm) in the form of magnetic fluid AM-01 ("AM-Kub", Ekaterinburg) twice a week in a single dose of 17.7 mg/kg, 5 out of 7 rats of the main group demonstrated a regression of the tumor from 1.5-3 cm3 to 0.7 ± 0.2 cm3 (in the control group – 9.7 ± 1.9 cm3, p &lt; 0.01). Ultrathin sections of the tumor tissue of 12 animals (including 7 rats of the main group) were examined in electron microscope JEOL JEM-1011 (Japan). Results: Under effective action of magnetite NPs in tumor tissue, in addition to necrosis, apoptosis and autophagy were marked. In the case of apoptosis, chromatin condensation in compact masses and separation of apoptotic bodies were observed. Significantly more common autophagic cell death was identified by violation of the integrity of the cell membrane and the presence of autophagosomes. Numerous signs of activation of cell-cell interactions with participation of immune cells were observed. Diverse groups of 2-4 contacting cells included macrophages, lymphocytes, plasmocytes, degranulated mast cells, neutrophils in various combinations with distinct signs of the metabolic activity. Invagination of macrophages cytoplasm into the cytoplasm of tumor cells, close adjacency of the cytoplasmic membranes of neutrophils and lymphocytes at considerable length, tight intertwining of mast cell cytoplasmic processes and engulfing of the mast cell granules by macrophages were noted. Conclusions: The results supplement the characteristics of immune processes during the self-dependent antitumor action of magnetite NPs.

In Vivo Pharmacokinetics Assessment of Indocyanine Green-Loaded Nanoparticles in Tumor Tissue with a Dynamic Diffuse Fluorescence Tomography System.

The purpose of this study was to show a systematic strategy for assessing the pharmacokinetics of indocyanine green (ICG)-loaded nanoparticles in the tumor tissue based on a dynamic diffuse fluorescence tomography (DFT) system. Twelve-seven-week-old male Balb/c nude mice bearing HepG2/ADR hepatocellular carcinoma were randomly divided into four groups (n= 3 per group). Four hundred microliters of three types of ICG-loaded nanoparticles (content of ICG: 50μg/ml) and free ICG (50μg/ml) was intravenously injected into the mice in each group, respectively. Afterwards, the real-time tomographic images on the spatial level were acquired at 2-11min, 30min, 1, 2, 3, 4, 6, 8, 10, 12, and 24h post-injection, and pharmacokinetic rates were derived for semi-quantitative assessment of the pharmacokinetics of nanoparticles at the tumor site using our proposed pharmacokinetic analysis method. The results obtained from our proposed dynamic DFT experiment demonstrated the distribution of different ICG formulations on the spatial level and enabled the semi-quantitative analysis of the pharmacokinetics of nanoparticles in the tumor tissue. The obtained pharmacokinetic rates effectively reflected the metabolic processes of nanoparticles in the tumor tissue, which proves to be beneficial for the development of tumor diagnosis and therapy.

Targeted Drug Delivery and Image-Guided Therapy of Heterogeneous Ovarian Cancer Using HER2-Targeted Theranostic Nanoparticles.

Cancer heterogeneity and drug resistance limit the efficacy of cancer therapy. To address this issue, we have developed an integrated treatment protocol for effective treatment of heterogeneous ovarian cancer.Methods: An amphiphilic polymer coated magnetic iron oxide nanoparticle was conjugated with near infrared dye labeled HER2 affibody and chemotherapy drug cisplatin. The effects of the theranostic nanoparticle on targeted drug delivery, therapeutic efficacy, non-invasive magnetic resonance image (MRI)-guided therapy, and optical imaging detection of therapy resistant tumors were examined in an orthotopic human ovarian cancer xenograft model with highly heterogeneous levels of HER2 expression.Results: We found that systemic delivery of HER2-targeted magnetic iron oxide nanoparticles carrying cisplatin significantly inhibited the growth of primary tumor and peritoneal and lung metastases in the ovarian cancer xenograft model in nude mice. Differential delivery of theranostic nanoparticles into individual tumors with heterogeneous levels of HER2 expression and various responses to therapy were detectable by MRI. We further found a stronger therapeutic response in metastatic tumors compared to primary tumors, likely due to a higher level of HER2 expression and a larger number of proliferating cells in metastatic tumor cells. Relatively long-time retention of iron oxide nanoparticles in tumor tissues allowed interrogating the relationship between nanoparticle drug delivery and the presence of resistant residual tumors by in vivo molecular imaging and histological analysis of the tumor tissues. Following therapy, most of the remaining tumors were small, primary tumors that had low levels of HER2 expression and nanoparticle drug accumulation, thereby explaining their lack of therapeutic response. However, a few residual tumors had HER2-expressing tumor cells and detectable nanoparticle drug delivery but failed to respond, suggesting additional intrinsic resistant mechanisms. Nanoparticle retention in the small residual tumors, nevertheless, produced optical signals for detection by spectroscopic imaging.Conclusion: The inability to completely excise peritoneal metastatic tumors by debulking surgery as well as resistance to chemotherapy are the major clinical challenges for ovarian cancer treatment. This targeted cancer therapy has the potential for the development of effective treatment for metastatic ovarian cancer.

Development of Novel Lignin-Based Targeted Polymeric Nanoparticle Platform for Efficient Delivery of Anticancer Drugs.

The clinical applications of natural anticancer drugs are being restricted by poor water solubility, fast clearance in the circulation, lack of targeting to tumor cells, and poor tissue penetration. To address these problems, in this study, we developed a novel lignin-based targeted polymeric nanoparticles (NPs) platform, folic acid-polyethylene glycol-alkaline lignin conjugates (FA-PEG-AL), via self-assembly for delivery of anticancer drug (hydroxyl camptothecin, HCPT). These lignin-based nanoparticles had moderate particle size (∼150 nm) with a narrow size distribution (PDI < 0.1), exhibited excellent biocompatibility, high drug loading efficiency (∼24.2 wt % of HCPT), prolonged blood circulation time (∼7-fold of free HCPT), and enhanced cellular uptake (∼5-fold of free HCPT). Besides, the drug biodistribution study confirmed preferred accumulation of FA-PEG-AL/HCPT NPs in tumor tissue. Subsequent tumor xenograft test revealed superior tumor suppression efficacy and reduced side effects of FA-PEG-AL/HCPT NPs compared with free HCPT. Therefore, the prepared lignin-based FA-PEG-AL/HCPT NPs would be a promising candidate for anticancer drugs delivery.

Tumor associated macrophages and angiogenesis dual-recognizable nanoparticles for enhanced cancer chemotherapy

Tumor-associated macrophages (TAMs) and angiogenesis are increasingly considered as the pivotal factors that affect tumor progress. Herein, we developed the paclitaxel (PTX)-loaded nanoparticles (NP/PTX) and decorated it with an innovative peptide YI (YINP/PTX) for simultaneously targeting delivery of drug to TAMs and angiogenesis. We demonstrated that the modification of YI peptide significantly enhanced the internalization of nanoparticles by cells and accumulation of nanoparticles in tumor tissues, but down regulated the distribution of them in normal tissues especially the liver. We also made a confirmation that the YI peptide decorated nanoparticles had an excellent co-localization with TAMs and angiogenesis in vivo. Finally, in the HT-26 colorectal tumor-bearing mice, a pharmacodynamic evaluation was performed and results showed that the YINP/PTX was more effective than other PTX formulations in anti-tumor growth. These results together suggested that the prepared nanoparticles are promising in targeting delivery of chemotherapeutics to tumor microenvironment for enhancing tumor therapy effect.

Celecoxib normalizes the tumor microenvironment and enhances small nanotherapeutics delivery to A549 tumors in nude mice

Barriers presented by the tumor microenvironment including the abnormal tumor vasculature and interstitial matrix invariably lead to heterogeneous distribution of nanotherapeutics. Inspired by the close association between cyclooxygenase-2 (COX-2) and tumor-associated angiogenesis, as well as tumor matrix formation, we proposed that tumor microenvironment normalization by COX-2 inhibitors might improve the distribution and efficacy of nanotherapeutics for solid tumors. The present study represents the first time that celecoxib, a special COX-2 inhibitor widely used in clinics, was explored to normalize the tumor microenvironment and to improve tumor nanotherapeutics delivery using a human-derived A549 tumor xenograft as the solid tumor model. Immunofluorescence staining of tumor slices demonstrated that oral celecoxib treatment at a dose of 200 mg/kg for two weeks successfully normalized the tumor microenvironment, including tumor-associated fibroblast reduction, fibronectin bundle disruption, tumor vessel normalization, and tumor perfusion improvement. Furthermore, it also significantly enhanced the in vivo accumulation and deep penetration of 22-nm micelles rather than 100-nm nanoparticles in tumor tissues by in vivo imaging and distribution experiments and improved the therapeutic efficacy of paclitaxel-loaded micelles in tumor xenograft-bearing mouse models in the pharmacodynamics experiment. As celecoxib is widely and safely used in clinics, our findings may have great potential in clinics to improve solid tumor treatment.

Optimization of the sensitivity/doses relationship for a bench-top EDXRF system used for in vivo quantification of gold nanoparticles

The present work is devoted to optimizing the sensitivity-doses relationship of a bench-top EDXRF system, with the aim of achieving a detection limit of 0.010mg/ml of gold nanoparticles in tumor tissue (clinical values expected), for doses below 10mGy (value fixed for in vivo application). Tumor phantoms of 0.3cm3 made of a suspension of gold nanoparticles (15nm AurovistTM, Nanoprobes Inc.) were studied at depths of 0–4mm in a tissue equivalent cylindrical phantom. The optimization process was implemented configuring several tube voltages and aluminum filters, to obtain non-symmetrical narrow spectra with fixed FWHM of 5keV and centered among the 11.2–20.3keV. The used statistical figure of merit was the obtained sensitivity (with each spectrum at each depth) weighted by the delivered surface doses. The detection limit of the system was determined measuring several gold nanoparticles concentrations ranging from 0.0010 to 5.0mg/ml and a blank sample into tumor phantoms, considering a statistical fluctuation within 95% of confidence. The results show the possibility of obtaining a detection limit for gold nanoparticles concentrations around 0.010mg/ml for surface tumor phantoms requiring doses around 2mGy.