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Nanoparticles possess unique optical and physic-chemical properties that may potentiate applications in biomedicine, in particular in diagnostics, therapy and imaging. Advances on biomolecular diagnostics strategies have greatly focused on single molecule detection and characterization of DNA, RNA or proteins through improved nanoparticle-based platforms. Nanoparticles improve analytical capability when compared to traditional techniques with high resolution and medium-high throughput. Also, particular interest has been directed at SNP detection, gene expression profiles and biomarker characterization through colorimetric, spectrometric or electrochemical strategies.
Molecular imaging has also benefited from the introduction of nanoparticles in standard techniques towards non-invasive imaging procedures that can be used to highlight regions of interest, allowing the characterization of biological processes at the cellular and/or molecular level. Several imaging modalities are associated with low sensitivity, an issue that can be tackled by the use of probes, e.g. contrast agents for X-ray and magnetic resonance imaging, radiolabelled molecules for nuclear medicine. Furthermore, nanoparticles can be used as vehicles that deliver specifically these contrast agents, leading to overcome the limitations of conventional modalities.
This chapter will discuss the use of nanoparticles in biomolecular recognition and imaging applications, focusing those already being translated into clinical settings. Current knowledge will be addressed as well as its evolution towards the future of nanoparticle-based biomedical applications.

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The majority of heterocycle compounds and typically common heterocycle fragments present in most pharmaceuticals currently marketed, alongside with their intrinsic versatility and unique physicochemical properties, have poised them as true cornerstones of medicinal chemistry. Apart from the already marketed drugs, there are many other being investigated for their promising activity against several malignancies. In particular, anticancer research has been capitalizing on the intrinsic versatility and dynamic core scaffold of these compounds. Nevertheless, as for any other promising anticancer drugs, heterocyclic compounds do not come without shortcomings. In this review, we provide for a concise overview of heterocyclic active compounds and families and their main applications in medicine. We shall focus on those suitable for cancer therapy while simultaneously addressing main biochemical modes of action, biological targets, structure-activity relationships as well as intrinsic limitation issues in the use of these compounds. Finally, considering the advent of nanotechnology for effective selective targeting of drugs, we shall discuss fundamental aspects and considerations on nanovectorization of such compounds that may improve pharmacokinetic/pharmacodynamic properties of heterocycles.

Traditional methods of drug delivery present several drawbacks, mainly due to off-target effects that may originate severe side and toxic effect to healthy tissues. Parallel to the development of novel more effective drugs, particular effort has been dedicated to develop and optimize drug delivery vehicles capable of specifically targeting the required tissue/organ and to deliver the cargo only where and when it is needed. New drug delivery systems based on nanoscale devices showing new and improved pharmacokinetic and pharmacodynamics properties like enhanced bioavailability, high drug loading or systemic stability have surged in the past decade as promising solutions to the required therapeutic efficacy. Amongst these nanoscale vectors, nanoparticles for drug delivery, such as polymeric, lipidbased, ceramic or metallic nanoparticles, have been at the forefront of pharmaceutical development. The interest in nanomedicine for treatment and diagnosis is clearly reflected on the increasing number of publications and issued patents every year. Here, we provide a broad overview of novel nanoparticle based drug delivery systems, ranging from polymeric systems to metal nanoparticles, while simultaneously listing the most relevant related patents.

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Over the past few years, modern medicinal chemistry has evolved towards providing us new and alternative chemotherapeutic compounds with high cytotoxicity towards tumor cells, alongside with reduced side effects in cancer patients. Organometallic compounds and their unique physic-chemical properties typically used in homogenous catalysis are now being translated as potential candidates for medical purposes. Their structural diversity, ligand exchange, redox and catalytic properties make them promising drug candidates for cancer therapy. Over the last decade this area has witnessed a steady growth and a few organometallic compounds have in fact already entered clinical trials, emphasizing its increasing importance and clinical relevance. Here we intend to stress out the different applications of organometallic compounds in medicine with emphasis on cancer therapy, as well as address setbacks regarding formulation issues, systemic toxicity and off-target effects. Advantages over classical coordination metal complexes, their nanovectorisation and specific molecular targets are also discussed.