ABSTRACT
Nanomaterials have been offering improvements in different areas due to their unique characteristics, but cytotoxicity associated with their use is still a topic that concerns researchers. Causing cell death, at first glance, may seem to be a problem and the studies regarding signaling pathways involved in this toxicity are still in their infancy. However, there are scenarios in which this feature is desirable, such as in cancer treatment. Anti-cancer therapies aim to eliminate the cells of malignant tumors as selectively as possible. From this perspective, titanium dioxide (TiO2) nanoparticles (NPs) deserve to be highlighted as important and efficient tools. Besides being able to induce cell death, these NPs can also be used to deliver anti-cancer therapeutics. These drugs can originate from natural sources, such as paclitaxel (an antitumoral molecule derived from a vegetal source). The present review aims to explore the recent knowledge of TiO2 NPs as nanocarriers (promoting the nanodelivery of paclitaxel) and as nanosensitizers to be used in phototherapies and/or sonodynamic therapy aiming to treat cancer. Signaling pathways triggered by this nanomaterial inside cells leading to apoptosis (a desirable fate when targeting tumor cells) and challenges related to the clinical translation of these NPs will also receive attention in the future.
ABSTRACT
The history of transgenesis is marked by milestones such as the development of cellular transdifferentiation, recombinant DNA, genetic modification of target cells, and finally, the generation of simpler genetically modified organisms (e.g. bacteria and mice). The first transgenic fish was developed in 1984, and since then, continuing technological advancements to improve gene transfer have led to more rapid, accurate, and efficient generation of transgenic animals. Among the established methods are microinjection, electroporation, lipofection, viral vectors, and gene targeting. Here, we review the history of animal transgenesis, with an emphasis on fish, in conjunction with major developments in genetic engineering over the past few decades. Importantly, spermatogonial stem cell modification and transplantation are two common techniques capable of revolutionizing the generation of transgenic fish. Furthermore, we discuss recent progress and future biotechnological prospects of fish transgenesis, which has strong applications for the aquaculture industry. Indeed, some transgenic fish are already available in the current market, validating continued efforts to improve economically important species with biotechnological advancements.
