Frederico D. Menezes

New methodology for obtaining CdTe quantum dots by using ultrasound

Luminescent CdTe quantum dots (Qdots) have been produced at few minutes by using a new, simple and fast methodology in an aqueous medium by using ultrasound irradiation to accelerate the process of tellurium reduction. The structural and optical properties were characterized by TEM, XRD, absorption and fluorescence spectrocopy. The produced Qdots are in a strong quantum confinement regime and have only one fluorescence band. Moreover, the nanoparticles seem to be monodispersed, which is in accordance with the fluorescence results. We have developed a simple route for preparing monodispersed CdTe Qdots in an aqueous media. The use of ultrasound allows the morphology to be better controlled and the surfaces defects of Qdots to be reduced.

Fluorescent II-VI semiconductor quantum dots in living cells: nonlinear microspectroscopy in an optical tweezers system.

In this work we used a setup consisting of an optical tweezers combined with a nonlinear microspectroscopy system to perform scanning microscopy and obtain emission spectra using two photon excited (TPE) luminescence of captured single living cells labeled with core-shell fluorescent semiconductor quantum dots (QDs). The QDs were obtained via colloidal synthesis in aqueous medium with an adequate physiological resulting pH. Sodium polyphosphate was used as the stabilizing agent. The results obtained show the potential presented by this system as well as by these II-VI fluorescent semiconductor quantum dots to perform spectroscopy in living trapped cells in any neighborhood and dynamically observe the cell chemical reactions in real time.

Application of colloidal semiconductor quantum dots as fluorescent labels for diagnosis of brain glial cancer

In this work we present the preparation, characterization and conjugation of colloidal core shell CdS-Cd(OH)2 quantum dots to health and cancer glial rats living cells in culture media. The particles were obtained via colloidal synthesis in aqueous medium, with final pH=7.3-7.4. Laser Scan Confocal Microscopy (LSCM) and Fluorescence Microscopy were used to evaluate fluorescence intensities and patterns of health and cancer (glioblastoma) glial cells labeled with the quantum dots in different time intervals. Health and cancer glial cells clearly differ in their fluorescence intensities and patterns. These different fluorescence intensities and patterns may be associated to differences concerning cellular membrane and metabolic features of health and cancer cells. The results obtained indicate the potential of the methodology for fast and precise cancer diagnostics.

Molecular differentiation of Leishmania protozoarium using CdS quantum dots as biolabels

In this work we applied core-shell CdS/Cd(OH)2 quantum dots (QDs) as fluorescent labels in the Leishmania amazonensis protozoarium. The nanocrystals (8-9 nm) are obtained via colloidal synthesis in aqueous medium, with final pH=7 using sodium polyphosphate as the stabilizing agent. The surface of the particles is passivated with a cadmium hydroxide shell and the particle surface is functionalized with glutaraldehyde. The functionalized and non-functionalized particles were conjugated to Leishmania organisms in the promastigote form. The marked live organisms were visualized using confocal microscopy. The systems exhibit a differentiation of the emission color for the functionalized and non-functionalized particles suggesting different chemical interactions with the promastigote moieties. Two photon emision spectra (λexc=795nm) were obtained for the promastigotes labeled with the functionalized QDs showing a significant spectral change compared to the original QDs suspension. These spectral changes are discussed in terms of the possible energy deactivation processes.

Odor recognition systems for natural gas odorization monitoring

This paper presents a system consisting of physical sensors and intelligent software for the automatic identification of the concentration of natural gas odorants and details the development of the sensor and pattern recognition systems. The sensor system uses spectroscopic technology and the pattern recognition system uses wavelet and artificial neural network technology. The aim is to determine the concentration of a natural gas odorant in the environment and associate this concentration with the benchmark index, which measures the degree of human perception to the presence of gas in the environment. Experiments were conducted comparing the performance of the system with human performance, which is normally used to deal with this problem. The proposed system demonstrated promising results.

Lectin functionalized quantum dots for recognition of mammary tumors

In this study we use CdS/Cd(OH)2 quantum dots functionalized with concanavalin-A (Con-A) lectin, specific to glucose/mannose residues, to investigate cell alterations regarding carbohydrate profile in human mammary tissues diagnosed as fibroadenoma (benign tumor). These particles were functionalized with glutaraldehyde and Con-A and incubated with tissue sections of normal and to Fibroadenoma, a benign type of mammary tumor. The tissue sections were deparafinized, hydrated in graded alcohol and treated with a solution of Evans Blue in order to avoid autofluorescence. The fluorescence intensity of QD-Con-A stained tissues showed different patterns, which reflect the carbohydrate expression of glucose/mannose in fibroadenoma when compared to the detection of the normal carbohydrate expression. The pattern of unspecific labeling of the tissues with glutaraldehyde functionalized CdS/Cd(OH)2 quantum dots is compared to the targeting driven by the Con-A lectin. The preliminary findings reported here support the use of CdS/Cd(OH)2 quantum dots as specific probes of cellular alterations and their use in diagnostics.

Monitoring activity of living cells marked with colloidal semiconductor quantum dots

Fluorescent semiconductor nanocrystals in quantum confinement regime (quantum dots) present several well known features which make them very useful tools for biological labeling purposes. Low photo-bleaching rates, high chemical stability, active surface allowing conjugation to living cells, explains the success of this labeling procedure over the commonly used fluorescent dyes. In this paper we report the results obtained with high fluorescent core-shell CdTe-CdS (diameter = 3-7 nm) colloidal nanocrystals synthesized in aqueous medium and conjugated to glucose molecules, incubated with living yeast cells, in order to investigate their glucose up-take activity.

High fluorescent and stable semiconductor quantum dots for red blood cells labeling

We present a simple and efficient method for marking living human red blood cells using CdS (Cadmium Sulfide) quantum dots (QDs). The nanocrystals were obtained via colloidal synthesis in aqueous medium with final pH=7 using sodium polyphosphate as the stabilizing agent. The methodology implementation is simple, do not requires additional capping layers nor narrow size QDs distribution. The synthesized nanoparticles were conjugated to monoclonal A anti-body. The resulting conjugates QDs/anti-A were incubated with human erythrocytes of blood groups A and O for 30 min at 37°C. The living cells in contact with the quantum dots maintained their properties for several days showing the low level of citotoxicity of the quantum dots. The conjugation of CdS QDs/anti-A show simultaneous red and green fluorescence when excited with 543 and 488 nm respectively. The efficiency of the conjugation QDs/anti-body to the erythrocytes, for each system, was monitored by confocal microscopy. The comparative analysis of the micrographs was done with the luminescence intensity maps of the samples obtained under constant capture conditions, such as, pinhole, filters, beam splitters and photomultiplier gain. The conjugates QDs/anti-A intensely marked group A erythrocytes and did not show any luminescence for group O erythrocytes, showing the sensitivity of the labeling procedure. In conclusion, we show the viability of the use of high luminescent and stable quantum dots as fluorescent labels for human erythrocytes with a methodology of simple implementation and the possibility to use them to distinguish different blood groups.

Synthesis and characterization of CdTe nanocrystals for applications as biolabels

Semiconductor nanocrystals composed by few hundred to a few thousand atoms also known as quantum dots have received substantial attention due to their size tunable narrow-emission spectra and several other advantages over organic molecules as fluorescent labels for biological applications, including resistence to photodegradation, improved brightness and only one laser excitation that enable the monitoring of several processes simultaneously. In this work we have synthesized and characterized thiol-capped CdTe and bioconjugated them to macrophages. We have mapped the fluoroscence intensity along the macrophages body in our set up consisting of an optical tweezer plus a non-linear micro-spectroscopy system to perform scanning microscopy and observe spectra using two photon excited luminescence.