Ilaiáli Souza Leite

Nanostructured electrospun nonwovens of poly(ε-caprolactone)/quaternized chitosan for potential biomedical applications

Blend solutions of poly(ε-caprolactone) (PCL) and N-(2-hydroxy)-propyl-3-trimethylammonium chitosan chloride (QCh) were successfully electrospun. The weight ratio PCL/QCh ranged in the interval 95/5-70/30 while two QCh samples were used, namely QCh1 (DQ¯ = 47.3%; DPv¯ = 2218) and QCh2 (DQ¯ = 71.1%; DPv¯ = 1427). According to the characteristics of QCh derivative and to the QCh content on the resulting PCL/QCh nonwoven, the nanofibers displayed different average diameter (175 nm-415 nm), and the nonwovens exhibited variable porosity (57.0%-81.6%), swelling capacity (175%-425%) and water vapor transmission rate (1600 g m-2 24 h-2500 g m-2 24 h). The surface hydrophilicity of nonwovens increases with increasing QCh content, favoring fibroblast (HDFn) adhesion and spreading. Tensile tests revealed that the nonwovens present a good balance between elasticity and strength under both dry and hydrated state. Results indicate that the PCL/QCh electrospun nonwovens are new nanofibers-based biomaterials potentially useful as wound dressings.

Photodynamic inactivation of microorganisms which cause pulmonary diseases with infrared light: an in vitro study

Lower respiratory infections are among the leading causes of death worldwide. In this study, it was evaluated the interaction of indocyanine green, a photosensitizer activated by infrared light, with alveolar macrophages and the effectiveness of the photodynamic therapy using this compound against Streptococcus pneumoniae . Initial experiments analyzed indocyanine green toxicity to alveolar macrophages in the dark with different drug concentrations and incubation times, and macrophage viability was obtained with the MTT method. The average of the results showed viability values below 90% for the two highest concentrations. Experiments with Streptococcus pneumoniae showed photodynamic inactivation with 10 μM indocyanine green solution. Further experiments with the bacteria in co-culture with AM will be conducted verifying the photodynamic inactivation effectiveness of the tested drug concentrations and incubation periods using infrared light.

Pneumonia treatment by photodynamic therapy with extracorporeal illumination ‐ an experimental model

Infectious pneumonia is a major cause of morbidity/mortality, mainly because of the increasing rate of microorganisms resistant to antibiotics. Photodynamic Therapy (PDT) is emerging as a promising approach, as effects are based on oxidative stress, preventing microorganism resistance. In two previous studies, the in vitro inactivation of Streptococcus pneumoniae using indocyanine green (ICG) and infrared light source was a success killing 5 log10 colony‐forming units (CFU/mL) with only 10 μmol/L ICG. In this work, a proof‐of‐principle protocol was designed to treat lung infections by PDT using extracorporeal illumination with a 780 nm laser device and also ICG as photosensitizer. Hairless mice were infected with S. pneumoniae and PDT was performed two days after infection. For control groups, CFU recovery ranged between 103–104/mouse. For PDT group, however, no bacteria were recovered in 80% of the animals. Based on this result, animal survival was evaluated separately over 50 days. No deaths occurred in PDT group, whereas 60% of the control group died. Our results indicate that extracorporeal PDT has the potential for pneumonia treatment, and pulmonary decontamination with PDT may be used as a single therapy or as an antibiotics adjuvant.

Pulmonary decontamination for photodynamic inactivation with extracorporeal illumination

Infectious pneumonia is a major cause of morbidity and mortality, despite advances in diagnostics and therapeutics in pulmonary infections. One of the major difficulties associated with the infection comes from the high rate of antibiotic resistant microorganisms, claiming for the use of alternative techniques with high efficiency and low cost. The photodynamic inactivation (PDI) is emerging as one of the great possibilities in this area, once its action is oxidative, not allowing microorganism develops resistance against the treatment. PDI for decontamination pulmonary has potential for treatment or creating better conditions for the action of antibiotics. In this study, we are developing a device to implement PDI for the treatment of lung diseases with extracorporeal illumination. To validate our theory, we performed measurements in liquid phantom to simulate light penetration in biological tissues at various fluency rates, the temperature was monitored in a body of hairless mice and the measurements of light transmittance in this same animal model. A diode laser emitting at 810 nm in continuous mode was used. Our results show 70% of leakage at 0.5 mm of thickness in phantom model. The mouse body temperature variation was 5.4 °C and was observed light transmittance through its chest. These results are suggesting the possible application of the extracorporeal illumination using infrared light source. Based on these findings, further studies about photodynamic inactivation will be performed in animal model using indocyanine green and bacteriochlorin as photosensitizers. The pulmonary infection will be induced with Streptococcus pneumoniae and Klebsiella pneumoniae.

In vitro evaluation of photodynamic therapy using redox-responsive nanoparticles carrying PpIX

Photodynamic therapy (PDT) is a technique that combines light’s interaction with a photoactive substance to promote cellular death and that has been used to treat a wide range of maladies. Cancer is among the leading causes of death worldwide and has been a central issue assessed by PDT research and clinical trials over the last 35 years, but its efficiency has been hampered by photosensitizer buildup at treatment site. Nanotechnology has been addressing drug delivery problems by the development of distinct nanostructured platforms capable of increasing pharmacological properties of molecules. The association of nanotechnology’s potential to enhance photosensitizer delivery to target tissues with PDT’s oxidative damage to induce cell death has been rising as a prospect to optimize cancer treatment. In this study, we aim to verify and compare the efficiency of PDT using redox-responsive silica-based nanoparticles carrying protoporphyrin IX (PpIX) in vitro, in both tumor and healthy cells. Dose-response experiments revealed the higher susceptibility of murine melanoma cells (B16-F10 cell line) to PDT (630 nm, 50 J/cm2) when compared to human dermal fibroblasts (HDFn): after 24 h of incubation with 50 μg/mL nanoparticles solutions, approximately 80 % of B16- F10 cells were killed, while similar results were obtained in HDFn cultures when solutions over 150 μg/mL were used. Uptake and ROS generation assays suggest increased nanoparticle internalization in the tumor cell line, in comparison with the healthy cells, and greater ROS levels were observed in B16-F10 cells.

Near–infrared photodynamic inactivation of S. pneumoniae and its interaction with RAW 264.7 macrophages

Pneumonia is the main cause of children mortality worldwide, and its major treatment obstacle stems from the microorganisms increasing development of resistance to several antibiotics. Photodynamic therapy has been presenting, for the last decades, promising results for some subtypes of cancer and infections. In this work we aimed to develop a safe and efficient in vitro protocol for photodynamic inactivation of Streptococcus pneumoniae, one of the most commonly found bacteria in pneumonia cases, using two near-infrared light sources and indocyanine green, a FDA approved dye. Photodynamic inactivation experiments with bacteria alone allowed to determine the best parameters for microbial inactivation. Cytotoxicity assays with RAW 264.7 macrophages evaluated the safety of the PDI. To determine if the photodynamic inactivation had a positive or negative effect on the natural killing action of macrophages, we selected and tested fewer indocyanine green concentrations and 10 J/cm2 on macrophage-S. pneumoniae co-cultures. We concluded that ICG has potential as a photosensitizer for near-infrared photodynamic inactivation of S. pneumoniae, producing minimum negative impact on RAW 264.7 macrophages and having a positive interaction with the immune cells microbicidal action.

Uso do método cooperativo de aprendizagem Jigsaw adaptado ao ensino de nanociência e nanotecnologia

In our days, the effects which are studied in the fields of Nanoscience and Nanotechnology (NN it is based on the application of a short course to high school students, along with a variation of the method of Cooperative Learning Jigsaw, in which we use a scientific text as a focus for the activity. It was found that the combination of these activities enabled students to understand and correlate the different concepts related to N&N, as well as form and expand their conceptual bases in a cooperative way.