The present invention relates to a colorimetric method for the detection of specific nucleic acids sequences, including mutations or single nucleotide polymorphisms within nucleic acid sequences, through the aggregation of nanoparticles functionalized with modified oligonucleotides, induced by an increase of the medium's ionic strength. Another aspect of the present invention relates with the development of a kit based on the method of the present invention, allowing for a quick and easy detection of specific nucleic acids sequences, including mutations or single nucleotide polymorphisms within nucleic acid sequences.

The present invention relates to a colorimetric method for the detection of specific nucleic acids sequences, including mutations or single nucleotide polymorphisms within nucleic acid sequences, through the aggregation of nanoparticles functionalized with modified oligonucleotides, induced by an increase of the medium's ionic strength. Another aspect of the present invention relates with the development of a kit based on the method of the present invention, allowing for a quick and easy detection of specific nucleic acids sequences, including mutations or single nucleotide polymorphisms within nucleic acid sequences.

The present invention relates to a colorimetric method for the detection of specific nucleic acids sequences, including mutations or single nucleotide polymorphisms within nucleic acid sequences, through the aggregation of nanoparticles functionalized with modified oligonucleotides, induced by an increase of the medium's ionic strength. Another aspect of the present invention relates with the development of a kit based on the method of the present invention, allowing for a quick and easy detection of specific nucleic acids sequences, including mutations or single nucleotide polymorphisms within nucleic acid sequences.

The present invention relates to a system and process for detection and/or qualitative and quantitative identification of the biological material, such as specific sequences of nucleic acids or proteins as antibodies, present in biological samples. The system is composed by one or more light sources (1) combined with one or more integrated optical photo sensors, or not, and various electronic components (4), necessary for obtaining/ processing of the signal emitted by the metal nanoprobes functionalized with a solution of biological composite, as well as also a micro-controller and a microprocessor, fixed or portable. This photosensor structure is able to detect and to quantify the colour variations produced by metal nanoprobes, being this preferentially gold, functionalized by oligonucleotides complementary to specific DNA/RNA sequences, proteins, as for instance antibodies and/or antigens related with certain disease, or other sample or solution of biological composite, that are to be investigated. The detection and quantification process is based on the response of a photosensor, singular or integrated, based on thin film technology of amorphous, nanocrystalline or microcrystalline silicon and their alloys, as well as the new active ceramic semiconductors, amorphous and not amorphous.

The present invention relates to a system and process for detection and/or qualitative and quantitative identification of the biological material, such as specific sequences of nucleic acids or proteins as antibodies, present in biological samples. The system is composed by one or more light sources (1) combined with one or more integrated optical photo sensors, or not, and various electronic components (4), necessary for obtaining/ processing of the signal emitted by the metal nanoprobes functionalized with a solution of biological composite, as well as also a micro-controller and a microprocessor, fixed or portable. This photosensor structure is able to detect and to quantify the colour variations produced by metal nanoprobes, being this preferentially gold, functionalized by oligonucleotides complementary to specific DNA/RNA sequences, proteins, as for instance antibodies and/or antigens related with certain disease, or other sample or solution of biological composite, that are to be investigated. The detection and quantification process is based on the response of a photosensor, singular or integrated, based on thin film technology of amorphous, nanocrystalline or microcrystalline silicon and their alloys, as well as the new active ceramic semiconductors, amorphous and not amorphous.

The present invention relates to a system and process for detection and/or qualitative and quantitative identification of the biological material, such as specific sequences of nucleic acids or proteins as antibodies, present in biological samples. The system is composed by one or more light sources (1) combined with one or more integrated optical photo sensors, or not, and various electronic components (4), necessary for obtaining/processing of the signal emitted by the metal nanoprobes functionalized with a solution of biological composite, as well as also a micro-controller and a microprocessor, fixed or portable. This photosensor structure is able to detect and to quantify the colour variations produced by metal nanoprobes, being this preferentially gold, functionalized by oligonucleotides complementary to specific DNA/RNA sequences, proteins, as for instance antibodies and/or antigens related with certain disease, or other sample or solution of biological composite, that are to be investigated. The detection and quantification process is based on the response of a photosensor, singular or integrated, based on thin film technology of amorphous, nanocrystalline or microcrystalline silicon and their alloys, as well as the new active ceramic semiconductors, amorphous and not amorphous.

O presente invento relaciona-se com um método colorimétrico de detec{\c c}ão de sequências específicas de ácidos nucleicos, incluindo muta{\c c}ões ou polimorfismos de nucleótido único em sequências de ácidos nucleicos, através da agrega{\c c}ão de nanopartículas funcionalizadas com oligonucleótidos modificados induzida por um aumento da for{\c c}a iónica do meio. Outro aspecto do presente invento relaciona-se com o desenvolvimento de um estojo que ao aplicar a metodologia objecto da presente inven{\c c}ão, permite a rápida e fácil detec{\c c}ão de sequências específicas de ácidos nucleicos, incluindo muta{\c c}ões ou polimorfismos de nucleótido único em sequências de ácidos nucleicos.

O presente invento relaciona-se com um método para controlo de reac{\c c}ões enzimáticas de síntese de ácidos nucleicos, recorrendo a nucleótidos funcionalizados com derivados de 4-metilcumarinas (1) protectores e fotolábeis. Quando ligado aos nucleótidos (2), o grupo cumarinico (3) impede que estes sejam utilizados como substrato por parte das enzimas, impossibilitando a ocorrência de reac{\c c}ão. Através de irradia{\c c}ão com radia{\c c}ão electromagnética, o grupo cumarinico é libertado, ficando o nucleótido disponível para a reac{\c c}ão. Desta forma, as reac{\c c}ões enzimáticas de síntese de ácidos nucleicos podem ser controladas através da luz.

Sistema para detección, identificación y cuantificación en material biológico, compuesto por una o más fuentes de luz (1) combinado con uno o más fotosensores ópticos (6 y 7) y diversos componentes electrónicos (4), necesarios para obtener/procesar la señal emitida caracterizado por: a) La fuente de luz (1), pulsada (2) o no, compuesta de láseres de estado sólido de baja energía o diodos emisores de luz, cuyo rango de longitud de onda está localizado entre 400 y 800 nm con una intensidad de luminosidad controlable que varía entre los valores de 0.01 mW/cm 2 y 100 mW/cm 2 ; b) El fotosensor, sencillo (6 y 7a) y (6 y 7b) o integrado (6, 4 y 7) compuesto de películas delgadas de silicio amorfo o nanocristalino o microcristalino y/o por semiconductores de cerámica tales como IGZO, IAgZO, SnZIO, GZIO, CuOIZ, GITO, entre otros, y basado en estructuras tipo pi'ii'n o MIS, que funciona en un rango de longitudes de onda desde el infrarrojo hasta el ultravioleta, y prové una información cualitativa y cuantitativa basada en la hibridización especifica y selectiva de sondas funcionalizadas con nanopartículas de metal; c) Siendo provista la eliminación del sistema a través de una fuente de energía convencional o a través de baterías fotovoltaicas, que dan portabilidad al sistema, siendo focalizada la luz emitida sobre la muestra, preferiblemente utilizando microlentes, siendo la muestra o muestras no fijadas físicamente al sensor o sensores, colocando la muestra biológica referida (5) sobre el lado opuesto (6) del sustrato donde se deposita el fotosensor (6 y 7).

O presente invento relaciona-se com um novo sistema e processo para detec{\c c}ão e/ou identifica{\c c}ão qualitativa e quantitativa de matéria biológica, tais como sequências específicas de ácidos nucleicos ou proteínas, como anticorpos, presentes em amostras biológicas. O sistema é constituído por uma ou mais fontes luminosas combinadas, com um ou mais fotossensores ópticos integrados, ou não, e componentes electrónicos vários, necessários para obten{\c c}ão/condicionamento do sinal emitido por nanossondas de metal funcionalizadas com a solu{\c c}ão de composto biológico, bem como ainda um micro-controlador e um microprocessador, portável ou fixo. Este fotossensor é capaz de detectar e quantificar as diferen{\c c}as colorimétricas produzidas por nanossondas de metal, sendo este preferencialmente o ouro, funcionalizadas por oligonucleotídeos complementares às sequências específicas de ADN/ARN, proteínas, como por exemplo anticorpos e/ou antigénios relacionados com determinada doen{\c c}a, ou outra amostra ou solu{\c c}ão de composto biológico, que se pretende pesquisar. O processo de detec{\c c}ão e quantifica{\c c}ão baseia-se na resposta de um fotossensor, singular ou integrado, baseado na tecnologia de filmes finos de sílicio amorfo, nanocristalino ou mícrocristalino, e suas ligas, e também nos novos cerâmicos semicondutores activos, amorfos e não morfos. O referido sistema e processo de detec{\c c}ão e/ou identifica{\c c}ão de matéria biológica tem aplica{\c c}ão na biotecnologia, incluindo a biomedicina.

sistema de dete{\c c}ão e quantifica{\c c}ão de matéria biológica constituído por um ou mais sensores óticos e uma ou mais fontes luminosas, processo associado e aplica{\c c}ões relacionadas a inven{\c c}ão atual relaciona- se a um sistema e a um processo para a dete{\c c}ão e/ou a identifica{\c c}ão qualitativa e quantitativa do material biológico, tal como seqüências específicas de ácidos nucleicos ou de proteínas como anticorpos, presente em amostras biológicas. o sistema é composto por uma ou mais fontes luminosas ( 1) combinadas com um ou mais fotosensores óticos integrados, ou não, e vários componentes eletrônicos ( 4) , necessários para obter/processar o sinal emitido pelas nanosondas de metal funcionalizadas com uma solu{\c c}ão de compósi to biológico, assim como igualmente um microcontrolador e um microprocessador, reparados ou portátil. esta estrutura do fotosensor pode detectar e determinar as varia{\c c}ões da cor produzidas por nanosondas do metal, sendo este preferencialmente ouro, funcionalizado pelos oligonucleotídeos complementares às seqüências específicas, as proteínas de dna/rna, como por exemplo os anticorpos e/ou os antígenos relativos a determinada doen{\c c}a, ou a outra amostra ou solu{\c c}ão de composto biológico, que devem ser investigada. a dete{\c c}ão e o processo da quantifica{\c c}ão são baseados na resposta de um fotosensor, singular ou integrados, baseado na tecnologia da película fina de silicones amorfos, nanocristalinos ou microcristalino e suas ligas, assim como os semicondutores cerâmicos ativos novos, amorfos e não amorfos.

RNAi has always captivated scientists due to its tremendous power to modulate the phenotype of living organisms. This natural and powerful biological mechanism can now be harnessed to downregulate specific gene expression in diseased cells, opening up endless opportunities. Since most of the conventional siRNA delivery methods are limited by a narrow therapeutic index and significant side and off-target effects, we are now in the dawn of a new age in gene therapy driven by nanotechnology vehicles for RNAi therapeutics. Here, we outlook the {"}do's and dont's{"} of the inorganic RNAi nanomaterials developed in the last 15 years and the different strategies employed are compared and scrutinized, offering important suggestions for the next 15. (C) 2015 Elsevier Ltd. All rights reserved.

The aggregation process of a series of mono- and dinuclear gold(I) complexes containing a 4-ethynylaniline ligand and a phosphane at the second coordination position (PR3-Au-CCC6H4-NH2, complexes 1-5, and (diphos)(Au-CCC6H4-NH2)2, complexes 6-8), whose biological activity was previously studied by us, has been carefully analyzed through absorption, emission, and NMR spectroscopy, together with dynamic light scattering and small-angle X-ray scattering. These experiments allow us to retrieve information about how the compounds enter the cells. It was observed that all compounds present aggregation in fresh solutions, before biological treatment, and thus they must be entering the cells as aggregates. Inductively coupled plasma atomic emission spectrometry measurements showed that mononuclear complexes are mainly found in the cytosolic fraction; the dinuclear complexes are mainly found in a subsequent fraction composed of nuclei and cytoskeleton. Additionally, dinuclear complex 8 affects the actin aggregation to a larger extent, suggesting a cooperative effect of dinuclear compounds.

Due to their relevance as disease biomarkers and for diagnostics, screening of single nucleotide polymorphism (SNPs) requires simple and straightforward strategies capable to provide results in medium throughput settings. Suitable approaches relying on isothermal amplification techniques have been evolving to substitute the cumbersome and highly specialized PCR amplification detection schemes. Nonetheless, identification of an individual's genotype still requires sophisticated equipment and laborious methods. Here, we present a low-cost and reliable approach based on the allele specific loop-mediated isothermal amplification (AS-LAMP) coupled to ssDNA functionalized gold nanoparticle (Au-nanoprobe) colorimetric sequence discrimination. The Au-nanoprobe integration allows for the colorimetric detection of AS-LAMP amplification product that can be easily interpreted in less than 15 min. We targeted a clinical relevant SNP responsible for lactose intolerance (-13910C/T dbSNP rs#: 4988235) to demonstrate its proof of concept and full potential of this novel approach.

Amorphous/nanocrystalline silicon pi'ii'n devices fabricated on micromachined glass substrates are integrated with oligonucleotide-derivatized gold nanoparticles for a colorimetric detection method. The method enables the specific detection and quantification of unamplified nucleic acid sequences (DNA and RNA) without the need to functionalize the glass surface, allowing for resolution of single nucleotide differences between DNA and RNA sequences-single nucleotide polymorphism and mutation detection. The detector's substrate is glass and the sample is directly applied on the back side of the biosensor, ensuring a direct optical coupling of the assays with a concomitant maximum photon capture and the possibility to reuse the sensor. (c) 2007 American Institute of Physics.

Gold nanoparticles have been appointed as cutting-edge platforms for combined diagnostic and therapeutic approaches due to their exquisite physicochemical and optical properties. In particular, their potential benefits in cancer settings are enormous, as they can serve as targeted vehicles for controlled drug release, photothermal therapy and gene therapy, as well as contrast imaging agents to allow for real-time monitoring of both disease and therapeutic progression. These theranostic platforms represent powerful image-guided therapeutics, tailored to maximize individual patient benefit and with the ability to significantly minimize toxic side effects. Here the authors review some of the recent advances on the development of gold nanoparticle conjugates for combined diagnostics and therapy, while reflecting on the obstacles toward translational research.

Lung cancer remains the top killing cancer worldwide despite advances in treatment. Seven ethanolic plant extracts were selected and evaluated for their antiproliferative activity against the two main types of lung cancers: non-small cell (A549) and small cell lung cancer cells (SHP-77). An ethanolic extract of Helichrysum odoratissimum Sweet (HO) showed significant antiproliferative activity against lung cancer, with a fifty percent inhibitory concentration (IC50) of 83.43 ± 1.60 µg/mL (A549), 49.46 ± 0.48 µg/mL (SHP-77) and 50.71 ± 2.27 µg/mL, against normal lung epithelial cells (MRC-5), resulting in a selectivity index (SI) value of 0.61 on A549 cells and 1.03 on SHP-77 cells, which was compared to the positive drug control, actinomycin D where the SI values were found to be 2 and 0.25 against A549 and SHP-77 cells, respectively. Against murine macrophages (RAW 264.7) and hepatocytes (HepG2), the HO ethanolic extract showed IC50 values of 60.15 ± 1.98 µg/mL and 23.61 ± 1.06 µg/mL, respectively. Microscopy showed that the HO ethanolic extract induced apoptosis in the A549 and HepG2 cells at 50 µg/mL and 300 µg/mL, respectively. The HO ethanolic extract, furthermore, inhibited the pro-inflammatory enzymes, cyclooxygenase 2 (COX-2) and 5-lipoxygenase (5-LOX) with IC50 values of 7.94 ± 3.84 µg/mL and 2.08 ± 1.35 µg/mL, respectively, whereas the positive controls Ibuprofen (COX-2) and Zileuton (5-LOX) showed IC50 values of 0.85 ± 0.14 µg/mL and 0.06 ± 0.05 µg/mL, respectively. The activity of NAD(P)H quinone oxidoreductase-1 (NQO1), which is a direct target of nuclear factor erythroid-2-related factor-2 (NRF2), was significantly inhibited in the A549 cells by the HO ethanolic extract (at 125 µg/mL) when compared to the positive control, brusatol (at 500 nM). Using the ex ovo yolk sac membrane (YSM) assay, the HO ethanolic extract (at 18.5 µg/egg) showed a 31.65 ± 12.80% inhibition of blood vessel formation. This is the first report of the noteworthy antiproliferative activity of the HO ethanolic extract on lung cancer cells including its potential to target several enzymes associated with inflammation and therefore, should be considered for further analysis.

Rheumatoid arthritis (RA) is a systemic autoimmune disease characterized by chronic joint inflammation and one of the main causes of chronic disability worldwide with high prevalence in the ageing population. RA is characterized by autoantibody production, synovial inflammation and bone destruction, and the most accepted biomarker is rheumatoid factor (RF) autoantibodies. In this work, we developed a low-cost approach for the detection and quantification of the RF marker. This colorimetric immunosensor is based on gold nanoprobe crosslinking that results in extensive aggregation in the presence of the pentameric IgM RF. Aggregation of the nanoconjugates yields a color change from red to purple that can be easily observed by the naked eye. The interaction between nanoconjugates and the specific target was confirmed via dynamic light scattering (DLS), Raman spectroscopy and atomic force microscopy (AFM) imaging. This conceptual system shows a LOD of 4.15 UA mL-1 IgM RF (clinical threshold is set for 20 IU mL-1). The one-step biosensor strategy herein proposed is much faster than conventional detection techniques, without the need for secondary antibodies, additional complex washing or signal amplification protocols. To the best of our knowledge this is the first report on target induced aggregation of gold nanoprobes for quantitative colorimetric autoantibody detection.

Inspired by the ability of SERS nanoantennas to provide an integrated platform to enhance disease targeting in vivo, we developed a highly sensitive probe for in vivo tumour recognition with the capacity to target specific cancer biomarkers such as epidermal growth factor receptors (EGFR) on human cancer cells and xenograft tumour models. Here, we used   90 nm gold nanoparticles capped by a Raman reporter, encapsulated and entrapped by larger polymers and a FDA antibody-drug conjugate - Cetuximab (Erbitux®) - that specifically targets EGFR and turns off a main signalling cascade for cancer cells to proliferate and survive. These drug/SERS gold nanoantennas present a high Raman signal both in cancer cells and in mice bearing xenograft tumours. Moreover, the Raman detection signal is accomplished simultaneously by extensive tumour growth inhibition in mice, making these gold nanoantennas ideal for cancer nanotheranostics, i.e. tumour detection and tumour cell inhibition at the same time.

A series of Cu(diimine)(X-sal)(NO3) complexes, where the diimine is either 2,2′-bipyridine (bpy) or 1,10-phenanthroline (phen) and X-sal is a monoanionic halogenated salicylaldehyde (X = Cl, Br, I, or H), have been synthesized and characterized by elemental analysis and X-ray crystallography. Penta-coordinate geometries copper(II) were observed for all cases. The influence of the diimine coligands and different halogen atoms on the antiproliferative activities toward human cancer cell lines have been investigated. All Cu(II) complexes were able to induce a loss of A2780 ovarian carcinoma cell viability, with phen derivatives more active than bpy derivatives. In contrast, no in vitro antiproliferative effects were observed against the HCT116 colorectal cancer cell line. These cytotoxicity differences were not due to a different intracellular concentration of the complexes determined by inductively coupled plasma atomic emission spectroscopy. A small effect of different halogen substituents on the phenolic ring was observed, with X = Cl being the most highly active toward A2780 cells among the phen derivatives, while X = Br presented the lowest IC50 in A2780 cells for bpy analogs. Importantly, no reduction in normal primary fibroblasts cell viability was observed in the presence of bpy derivatives (IC50 > 40 μM). Mechanistically, complex 1 seems to induce a stronger apoptotic response with a higher increase in mitochondrial membrane depolarization and an increased level of intracellular reactive oxygen species (ROS) compared to complex 3. Together, these data and the low IC50 compared to cisplatin in A2780 ovarian carcinoma cell line demonstrate the potential of these bpy derivatives for further in vivo studies.