Study on the development of nanotechnology in advanced countries and in Brazil

The study shows how nanotechnology evolves in developed countries and Brazil, raising aspects of private and governmental initiatives. The investigation was based in scientific literature, electronic articles and conference reports. Several sources of literature were used, including electronic databases and reference lists. By this study, it was observed that, although nanotechnology is in initial stage of development all over the world, the developed countries have had growing public and private investments in the area each year. In those countries, there is a concern toward both, the formation of specialists in nanotechnology and the transference of technology developed in universities and research institutes to industry. In Brazil, the study showed that despite the growing concern of investigators, national research centers and financial centers toward the development of the nanotechnology, there is still a need for more investment and formation of area specialists.O presente trabalho faz um estudo sobre o desenvolvimento da nanotecnologia, com enfoque na área de saúde, em países tecnologicamente mais avançados e no Brasil, levantando aspectos de iniciativas governamentais e privadas. A investigação foi baseada em literatura científica, artigos eletrônicos e relatórios de conferências. Foi observado que, apesar da nanotecnologia estar em estágio inicial no mundo inteiro, os países tecnologicamente mais avançados têm tido investimentos crescentes na área a cada ano, tanto públicos quanto privados. Há grande preocupação nesses países quanto à formação de profissionais especialistas na área e à transferência da tecnologia desenvolvida por universidades e institutos de pesquisa para a indústria. No Brasil, o estudo mostrou que apesar da crescente preocupação dos pesquisadores, centros de pesquisa e centros de financiamento com o desenvolvimento da nanotecnologia, ainda há necessidade de maiores investimentos e formação de profissionais especialistas na área

About the sterilization of chitosan hydrogel nanoparticles

In the last years, nanostructured biomaterials have raised a great interest as platforms for delivery of drugs, genes, imaging agents and for tissue engineering applications. In particular, hydrogel nanoparticles (HNP) associate the distinctive features of hydrogels (high water uptake capacity, biocompatibility) with the advantages of being possible to tailor its physicochemical properties at nano-scale to increase solubility, immunocompatibility and cellular uptake. In order to be safe, HNP for biomedical applications, such as injectable or ophthalmic formulations, must be sterile. Literature is very scarce with respect to sterilization effects on nanostructured systems, and even more in what concerns HNP. This work aims to evaluate the effect and effectiveness of different sterilization methods on chitosan (CS) hydrogel nanoparticles. In addition to conventional methods (steam autoclave and gamma irradiation), a recent ozone-based method of sterilization was also tested. A model chitosan-tripolyphosphate (TPP) hydrogel nanoparticles (CS-HNP), with a broad spectrum of possible applications was produced and sterilized in the absence and in the presence of protective sugars (glucose and mannitol). Properties like size, zeta potential, absorbance, morphology, chemical structure and cytotoxicity were evaluated. It was found that the CS-HNP degrade by autoclaving and that sugars have no protective effect. Concerning gamma irradiation, the formation of agglomerates was observed, compromising the suspension stability. However, the nanoparticles resistance increases considerably in the presence of the sugars. Ozone sterilization did not lead to significant physical adverse effects, however, slight toxicity signs were observed, contrarily to gamma irradiation where no detectable changes on cells were found. Ozonation in the presence of sugars avoided cytotoxicity. Nevertheless, some chemical alterations were observed in the nanoparticles.info:eu-repo/semantics/publishedVersio

Ozone gas as a benign sterilization treatment for PLGA nanofibre scaffolds

The use of electrospun nanofibers for tissue engineering and regenerative medicine applications is a growing trend as they provide improved support for cell proliferation and survival due, in part, to their morphology mimicking that of the extracellular matrix. Sterilization is a critical step in the fabrication process of implantable biomaterial scaffolds for clinical use, but many of the existing methods used to date can negatively affect scaffold properties and performance. Poly(lactic-co-glycolic acid) (PLGA) has been widely used as a biodegradable polymer for 3D scaffolds and can be significantly affected by current sterilization techniques. The aim of this study was to investigate pulsed ozone gas as an alternative method for sterilizing PLGA nanofibers. The morphology, mechanical properties, physicochemical properties, and response of cells to PLGA nanofiber scaffolds were assessed following different degrees of ozone gas sterilization. This treatment killed Geobacillus stearothermophilus spores, the most common biological indicator used for validation of sterilization processes. In addition, the method preserved all of the characteristics of nonsterilized PLGA nanofibers at all degrees of sterilization tested. These findings suggest that ozone gas can be applied as an alternative method for sterilizing electrospun PLGA nanofiber scaffolds without detrimental effects

Nanomedicine for drug delivery in South Africa: a protocol for systematic review

Background: The emergence of nanomedicine in the past decade has changed the landscape of disease diagnosis and treatment. Nanomedicine makes use of nanostructures for applications in different fields of medicine, including drug delivery, biosensors, neuro-electronic interfaces, in vivo imaging, and cell-specific molecular interactions. Despite its relative infancy, nanomedicine has generated a significant body of research as evidenced by peer reviewed literature and several patents. This proposed systematic review will focus specifically on drug delivery systems in which nanoparticles are used to enhance the pharmacological and therapeutic properties of drugs. The strength of nanoparticulate drug delivery systems is their ability to alter the pharmacokinetics and bio-distribution of drugs. Globally, the discourse on nanomedicine is dominated by research being done in the developed countries of Europe and in the United States of America. Less attention has been given to the applications of nanomedicine in developing countries, particularly Africa. There is dearth of information on the applications of nanomedicine in terms of drug delivery with particular reference to which diseases are being targeted generally in Africa. The review will describe the specific diseases that are being targeted and the progress being made in South Africa, with a view to determining whether the applications of nanomedicine are being appropriated to address the context-specific challenges in this country or if they mimic what is being done globally. Methods: Keywords related to nanomedicine and drug delivery will be combined to build a search strategy for each of the following databases: PubMed, Cochrane Library (including Cochrane Central Register of Controlled Trials (CENTRAL), Cochrane Database of Systematic Reviews, Cochrane Methodology Register), Google Scholar, NHS Health Technology Assessment Database and Web of Science. We will also check reference lists of included studies for other eligible reports and search unpublished data. To ensure that the search is comprehensive, grey literature will be searched extensively. Literature to be included will have nanomedicine in drug delivery as the primary application and report on the specific diseases that are targeted in South Africa. Two authors will independently screen the search output, select studies and extract data; discrepancies will be resolved by consensus and discussion. When no consensus is reached, the third author will be consulted. Discussion: The systematic review will inform the government, policy-makers, investors, health professionals, scientists, and engineers about the applications of nanomedicine in drug delivery. In particular, it will identify the diseases targeted by the application of nanomedicine for drug delivery and the progress being made in South Africa as the disease burden of this country differs from that of developed countries where nanomedicine has been widely used for drug delivery. Systematic review registration PROSPERO CRD4201705738

Ozone gas as sterilant for electrospun nanofibers for tissue engineering: safety and efficacy evaluation.

Com o aumento da expectativa de vida e o envelhecimento da população, a medicina regenerativa vem ocupando um importante espaço visando manter a qualidade de vida da população. A engenharia de tecidos, apoiada nos avanços da biotecnologia e da nanotecnologia, vem se configurando como alternativa mais versátil e menos custosa ao reparo e transplante de tecidos e órgãos. Os arcabouços para engenharia tecidual constituídos de nanofibras têm o potencial para mimetizar a arquitetura nanométrica dos tecidos humanos, especialmente devido à grande área superficial e elevada porosidade. Para a fabricação de arcabouços de nanofibras, a técnica mais utilizada é a de eletrofiação, devido à sua alta versatilidade, e os materiais mais estudados são os polímeros biodegradáveis e biocompatíveis, que são os mais desejados para fins biomédicos. A esterilização é uma etapa crítica no processo de fabricação de produto médico implantável e pode ter impacto no desempenho dos arcabouços poliméricos. Desta forma, o objetivo deste estudo foi avaliar o impacto da esterilização por gás ozônio em arcabouços de nanofibras poliméricas eletrofiadas para engenharia de tecidos. A esterilização por ozônio foi eficaz na inativação do indicador biológico G. stearothermophilus, caracterizando eficácia na letalidade microbiana; igualmente, não se detectou crescimento microbiano no teste de esterilidade. Os arcabouços de nanofibras de poli(ácido láctico-co-ácido glicólico) tiveram suas propriedades físico-químicas, mecânicas e biológicas preservadas, mantendo o mesmo desempenho como suporte para o crescimento de fibroblastos NIH3T3 após a esterilização. Já os arcabouços de poli-caprolactona, tiveram suas propriedades alteradas e apresentaram um melhor desempenho na proliferação celular de fibroblastos L929 após a esterilização. Assim, o gás ozônio se mostrou como um método alternativo para a esterilização de nanofibras poliméricas para engenharia tecidual.Since world population is ageing, regenerative medicine has become a growing area in the medical field in order to maintain the life quality of population. With the advance of biotechnology and nanotechnology, tissue engineering has emerged as a more versatile and less costly alternative to tissue repair and transplantation. Nanofibers have the potential to mimic the human tissue architecture at the nanometer scale, especially due to their large surface area and high porosity. Electrospinning is the most applied technique to fabricate nanofibers scaffolds mainly because of its powerful and high versatility. Many polymers can be used on the fabrication of nanofibers scaffolds; however, the biodegradable and biocompatible polymers are the most desired ones for biomedical purposes. Sterilization is a critical step in the fabrication process and might impact the performance of polymeric scaffolds. Therefore, the aim of this study was to evaluate the impact of sterilization by ozone gas on polymeric electrospun nanofibers scaffolds for tissue engineering. Ozone gas sterilization was efficient in killing the G. stearothermophilus spores, a common biological indicator used for validation of sterilization processes. The sterilization method preserved the physico-chemical, mechanical, and biological properties of poly(lactic-co-glycolic) acid nanofibers, keeping the performance of NIH3T3 proliferation on the scaffolds. On the other hand, the same sterilization method altered some properties of poly-caprolactone electrospun scaffolds, what improved L929 fibroblasts proliferation on the scaffolds after sterilization. Therefore, ozone gas was found to be a benign sterilization method for polymeric electrospun scaffolds for tissue engineering

Pectin/casein aqueous mixtures: physical-chemical studies and potential use in periodontal disease treatment.

Misturas aquosas de polissacarídeos e proteínas são normalmente instáveis e separam-se em fases devido às interações repulsivas ou atrativas existentes entre os polímeros. O efeito da temperatura, do pH e da concentração polimérica no comportamento de misturas de pectina/caseína foi estudado nesse trabalho. Um diagrama de fases construído em pH 7 revelou que a mistura é estável apenas em baixas concentrações. Concentrações mais elevadas levam à incompatibilidade termodinâmica, governada por forças puramente entrópicas, e ao aparecimento de duas fases: uma rica em caseína (inferior) e outra rica em pectina (superior). A decomposição espinodal pôde ser visualizada nos estágios iniciais da separação de fases e, nos estágios intermediários, observou-se a formação de emulsões água/água. Quando o pH dessas emulsões é reduzido para abaixo de 6, a pectina é atraída para a fase de caseína, resultando na formação de partículas de complexo pectina/caseína que não coalescem e são resistentes à adição de sal (NaCl 100 mM), apresentando um diâmetro médio aproximado de 4 m. As micropartículas de pectina/caseína produzidas por este método demonstraram ser capazes de encapsular com alta eficiência tanto substâncias hidrofóbicas quanto hidrofílicas, possibilitando sua aplicação na encapsulação de compostos variados para fins diversos. Neste trabalho, as micropartículas foram utilizadas para encapsular cristais de metronidazol e sua utilização na obtenção de filmes de aplicação intra-bolsa periodontal foi avaliada in vitro. As dispersões de pectina/caseína contendo as micropartículas carregadas foram submetidas à secagem para a obtenção dos filmes. Estes, reticulados ou não com cálcio, sustentaram a liberação in vitro do fármaco por pelo menos 7 dias in vitro. A reticulação foi importante para reduzir a desintegração dos filmes, contribuindo para aumentar o tempo de permanência deles no local de aplicação e para melhorar suas propriedades mecânicas, facilitando seu manuseio e inserção na bolsa periodontal. Com esses resultados, conclui-se que os filmes de micropartículas de complexo pectina/caseína contendo metronidazol desenvolvidos neste trabalho são excelentes candidatos a sistemas de liberação local para o tratamento da doença periodontal.Aqueous mixtures of polysaccharides and proteins are usually unstable and phase-separate either because of repulsive or attractive interactions. The effect of temperature, pH, and biopolymer concentration on the phase behavior of pectin/casein mixtures was investigated. A phase diagram built at pH 7 revealed that the mixture is stable at low polymer concentrations. Higher concentrations lead to thermodynamic incompatibility, driven purely by entropic forces, and to the appearance of two phases: one enriched with casein (lower) and the other, with pectin (upper). Spinodal decomposition was visualized in the early stages of phase separation. In the intermediate stages, water-in-water emulsions were observed. When the pH of these emulsions was lowered below 6, pectin was attracted by casein-rich phase, resulting in the formation of particles (diameter ~ 4 m) of pectin/casein complex, which do not coalesce and are insensitive to salt addition (100 mM NaCl). Pectin/casein microparticles obtained by this method were able to encapsulate with high efficiency either hydrophobic or hydrophilic substances and, due to that, could be applied in the encapsulation of a great variety of compounds for different purposes. In this work, the pectin/casein microparticles were used to encapsulate metronidazole crystals and the preparation of intra-periodontal pocket films with them was evaluated. Therefore, dispersions of loaded pectin/casein microparticles were dried in an oven. Films cross-linked or not with calcium sustained the in vitro drug release at least for 7 days. The cross-linking with calcium was important to reduce film disintegration, accounting for its permanence in the applied region, and to improve the mechanical properties, which facilitates manipulation and insertion into the periodontal pocket. With these results we conclude that the films formed by microparticles of pectin/casein complex loaded with metronidazole are excellent candidates for local drug delivery systems for the treatment of periodontal disease

Thermodynamic Incompatibility and Complex Formation in Pectin/Caseinate Mixtures

The instability of polysaccharide/protein mixtures occurs because of either thermodynamic incompatibility or complexation. We studied which instability mechanism dominated given the external conditions. Therefore the effect of temperature, pH, and biopolymer concentration on the phase separation of pectin/caseinate mixtures was investigated. At pH > 6, thermodynamic incompatibility with spinodal decomposition was observed in pectin/caseinate mixtures resulting in the formation of water-in-water emulsions in intermediate stages of the phase separation process. The demixing rate of these emulsions and appearance of two macroscopic phases (lower phase enriched with caseinate and upper phase with pectin) was retarded when the pectin concentration increased or when the storage temperature decreased due to a higher viscosity of the mixtures at those conditions. As the pH of the mixture was lowered below 6, pectin accumulated in the caseinate-rich phase. Complexation of pectin and caseinate led to the formation of microparticles (approximately 3 microm), whose shape depends on the biopolymer concentration ratio and rate of acidification. These pectin/caseinate particles do not coalesce and are insensitive to salt addition