Cristal Cerqueira-Coutinho

Anti-MUC1 nano-aptamers for triple-negative breast cancer imaging by single-photon emission computed tomography in inducted animals: initial considerations

The early and specific detection of tumors remains a barrier in oncology, especially in cases such as the triple-negative breast cancer (TNBC). To address this gap, aptamers have found an important application in the recognition of tumor biomarkers such as mucin 1 (MUC1). However, there are still some difficulties in the use of aptamer, as their rapid biological clearance makes their use as drugs limited. In this study, the anti-MUC1 aptamer was used as a drug delivery system (DDS) for a radioactive polymeric nanoparticle (NP) in the imaging of TNBCs. Thus, poly(lactic-co-glycolic acid) NPs loaded with the anti-MUC1 aptamer and labeled with technetium-99m were used for a biodistribution study and imaging of TNBC. The results confirmed that the NP was successfully obtained, with a mean size of 262 nm, according to the dynamic light scattering data. The biodistribution assay in induced animal models with TNBC showed that although there was a high capture by intestine (>30%), the DDS developed had a high tumor uptake (5%) and with great in vivo imaging properties, corroborating the possibility of use of this DDS as an imaging drug for TNBC.

Comparison of biodistribution profile of monoclonal antibodies nanoparticles and aptamers in rats with breast cancer

Abstract The use of monoclonal antibodies and aptamers is growing every single day, as the use of nanoparticle systems. Although most of the products are under investigation, there are a few commercialized products available at the market, for human consume. In this study, we have compared three formulations (aptamer anti-MUC1, monoclonal antibody – Trastuzumab and monoclonal antibodies nanoparticles – PLA/PVA/MMT trastuzumab) to identify their profile as also to understand their behavior into an alive biological system. In this direction the radiolabeling of the products were done and they were all tested in animals (in vivo) in two conditions: healthy rats and breast cancer induced animals. The results showed that the nanoparticle has the better biodistribution profile, followed by the aptamer. We conclude that more studies and a global effort to elucidate the biological behavior of drugs and especially nano-drugs are necessary.

Drug metabolism: Comparison of biodistribution profile of holmium in three different compositions in healthy Wistar rats.

Radioisotope holmium is a candidate to be used in cancer treatment and diagnosis. There are different holmium salts and they present distinct solubility and consequently different biodistribution profiles. In this work, we aimed to evaluate the biodistribution profiles of two holmium salts (chloride and sulfate) and holmium nanoparticles (oxide) through an in vivo biodistribution assay using animal model. Samples were labeled with technetium-99m and administered in Wistar rats by retro-orbital route. Holmium chloride is highly soluble in water and it was quickly filtered by the kidneys while holmium sulfate that presents lower solubility in water was mainly found in the liver and the spleen. However, both the salts showed a similar biodistribution profile. On the other hand, holmium oxide showed a very different biodistribution profile since it seemed to interact with all organs. Due to its particle size range (approximately 100nm) it was not intensively filtered by the kidneys being found in high quantities in many organs, for this reason its use as a nanoradiopharmaceutical could be promising in the oncology field.

MUC1 aptamer-capped mesoporous silica nanoparticles for controlled drug delivery and radio-imaging applications

Mucin 1 (MUC1) is a cell surface protein overexpressed in breast cancer. Mesoporous silica nanoparticles (MSNs) loaded with safranin O, functionalized with aminopropyl groups and gated with the negatively charged MUC1 aptamer have been prepared (S1-apMUC1) for specific targeting and cargo release in tumoral versus non-tumoral cells. Confocal microscopy studies showed that the S1-apMUC1 nanoparticles were internalized in MDA-MB-231 breast cancer cells that overexpress MUC1 receptor with subsequent pore opening and cargo release. Interestingly, the MCF-10-A non-tumorigenic breast epithelial cell line that do not overexpress MUC1, showed reduced (S1-apMUC1) internalization. Negligible internalization was also found for S1-ap nanoparticles that contained a scrambled DNA sequence as gatekeeper. S2-apMUC1 nanoparticles (similar to S1-apMUC1 but loaded with doxorubicin) internalized in MDA-MB-231 cells and induced a remarkable reduction in cell viability. Moreover, S1-apMUC1 nanoparticles radio-labeled with 99mTc (S1-apMUC1-Tc) showed a remarkable tumor targeting in in vivo studies with MDA-MB-231 tumor-bearing Balb/c mice.

Development of a photoprotective and antioxidant nanoemulsion containing chitosan as an agent for improving skin retention

Sunscreens are destined to topical application and should protect skin against ultraviolet radiation; furthermore, they are toxic substances and should not reach the bloodstream, so they must be retained in the skin. In the present work, an oil‐in‐water photoprotective and antioxidant nanoemulsion (NE) containing chitosan was developed. Preliminary studies were performed aiming to choose the surfactant to be used in this NE; stability of the formulas was determined by dynamic light scattering after their preparation and after 7 days. A blend of surfactants, polyoxyethylene sorbitan monooleate, and sorbitan monooleate was selected for the preparation of the NE, as well as the following organic sunscreens: benzophenone‐3, diethylamino hydroxybenzoyl hexylbenzoate, octocrylene and octylmethoxycinnamate, and also pomegranate antioxidant extract and chitosan. The antioxidant extract with the highest antioxidant activity was chosen based on a screening of plant extracts by DPPH• (2,2‐diphenyl‐1‐picrylhydrazyl) assay. Photostability of the sunscreens and in vitro efficacy and safety of the formulations were also evaluated. Results showed that the developed photoprotective and antioxidant NE containing chitosan was stable for at least 6 months, photostable when irradiated in a solar simulator, and effective. Additionally, chitosan acted by promoting retention of the formulation in epidermis, thus increasing formulation safety.

Development and characterization of repellent formulations based on nanostructured hydrogels

Abstract Diseases caused by insects could lead to epidemic scenarios in urban areas and insect repellents are a shield against a wide range of insects, but they need to be safe without compromising efficacy. Ethyl butylacetylaminopropionate (EB) is a synthetic mosquito repellent, which could be used in products for adults and children due to its low-allergenic potential. The aim of this study was to develop and characterize EB and Poloxamer 407 nanoemulsions regarding their droplets mean size, pH, rheological properties, cytotoxicity and in vitro permeation profile. The developed formulations (F1 with 12.5% of EB and F2 with 25% of EB) were compared with a commercial formulation containing 12.5% of EB. Droplets mean size was determined by DLS, and for both nanoemulsions they were around 200 nm; however, the commercial formulation presented a droplets mean size of 10 nm, which could contribute to its high permeation. F1 and F2 presented a gel-like behavior, however F2 presented lower viscosity due to the presence of more EB between the polymer chains preventing them to interact with each other. Also, F2 was less retained by the epidermis when compared to F1 probably due to its lower viscosity. For the cytotoxicity assay only F2, which presented the highest concentration of EB was tested, and it was not toxic to the cells. This result could be also extended to F1 which presented half the EB concentration. The present study demonstrated that EB and Poloxamer 407 nanoemulsions are promising as new insect-repellent formulations.

Diagnosing gastrointestinal stromal tumours by single photon emission computed tomography using nano-radiopharmaceuticals based on bevacizumab monoclonal antibody

The use of nanoparticles is increasing each day. Although only a few nanoparticle drugs are on the market, their research and development are immense. In the field of cancer, the number of new drugs is very large, however, the efficacies of those drugs are very limited. In this study we developed a new radioactive nanoparticle for gastrointestinal stromal tumour imaging and early detection. The results suggest that this nanoparticle may be used for imaging as well as for treatment due the efficacy and inherent quality of nanoparticle systems, especially regarding the higher enhanced permeability and retention effect.

Diagnosing lung cancer using etoposide microparticles labeled with 99mTc

Abstract The diagnosis of lung cancer mostly occurs when the cancer is already in an advanced stage. In this situation, there are few options for the treatment and most of them have few chances of success. In this study, we developed and tested etoposide microparticles as a diagnostic agent for imaging lung cancer at early stages of development. We tested etoposide microparticles labeled with technetium 99m in inducted mice. The results demonstrated that over 10% of the total dose used was uptake by the tumor site. Also, the results showed that the microparticles had a good renal clearance and low uptake by liver and spleen. The data suggest that these micro-radiopharmaceuticals may be used for lung cancer imaging exam, especially single-photo emission computed tomography (SPECT).

Niosomes as Nano-Delivery Systems in the Pharmaceutical Field.

Nanosystems used in the pharmaceutical field aim to guarantee a controlled release and efficacy boost with dose reduction of the drug. The same active ingredient could be vehiculated in different concentrations in distinct nanosystems. Among these nanostructures, the vesicular ones present a versatile delivery system that could be applied to encapsulate lipophilic, amphiphilic, and hydrophilic compounds. Liposomes are the most well-known vesicular nanosystems; however, there are others, such as niosomes, that are composed of nonionic surfactants that are polymeric or conventional. Niosomes could be prepared using the thin film hydration method, in which the active ingredient is solubilized in organic solvent with the surfactant or in aqueous solution depending on its polarity. In addition, co-surfactants could be used to improve stabilization and vesicle integrity because they occupy regions in the interface where the mainly surfactant could not reach. Vesicular nanosystems could be characterized by different techniques, such as microscopy, dynamic light scattering, nuclear magnetic resonance, and others. These nanostructures could be applied to drugs (administered by different routes) or to gene and cosmetic delivery systems.