Nanobiotechnology in Diagnosis, Drug Delivery and Treatment - Группа авторов

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obtained results the authors concluded that the liposome system has the potential for gastric drug delivery (Thamphiwatana et al. 2013).

Schematic illustration of mechanism of Helicobacter pylori inactivation in epithelium cells by chitosan nanoparticles loaded with antibiotic.

      The nanoparticles have been also conjugated with ligands such as mannose‐ or fucose‐specific lectins in order to target the carbohydrate receptors on H. pylori cells (Umamaheshwari and Jain 2003). H. pylori is able to change the rheological properties of the mucus layer due to urease secretion (Celli et al. 2009), resulting in an increase of the pH and subsequently in reduction of the viscosity of the surrounding environment. Therefore, mucoadhesiveness of the gastric mucosa is considered as a target in treatment of H. pylori infections. Changes in mucosa viscosity may improve the time of contact between the drug and bacterial cells, and consequently, the efficacy against these bacterial infections (Lopes et al. 2015).

      Colorectal cancer (CRC) is a severe health problem and has the third highest incidence of tumors in both males and females. The global incidence of CRC is about 1.3 million cases per year (Viswanath et al. 2016). However, according to estimates from the International Agency for Research on Cancer in 2018, globally, CRC constituted approximately 1.8 million new cases and 900 000 deaths annually (Keum and Giovannucci 2019). Thus, CRC is a common health problem due to its high prevalence and high mortality rate. Adjuvant and neo‐adjuvant strategies, chemotherapy, and radiotherapy alone or in combination, have substantially improved survival and local recurrence rates. Their effectiveness remains limited due to the intrinsic build‐up of resistance of cancer cells to chemotherapy drugs, dose‐limiting toxicities and other major side effects (Gholami and Engel 2018). Colon cancer occurs due to certain routine factors and increasing age, with only some cases resulting from fundamental genetic disorders (Gulbake et al. 2016). Over the last few years, nanotechnology has improved available and developed novel methods for the detection and treatment of CRCs that cannot be achieved using the existing conventional technologies (Laroui et al. 2013; Viswanath et al. 2016). Moreover, targeted nanostructures offer potential solutions against the restrictions of standard chemo‐ and radiotherapy that may cause damages to normal tissues in proximity to and distant from tumors and clinical toxicities (Viswanath et al. 2016). Nanomaterials of different shapes, size, and compositions are considered as promising and important novel tools for CRC diagnosis, staging, and therapeutics (Dong et al. 2015).

      Beyond diagnostics, targeted nanostructures offer opportunities to develop novel treatment approaches of tumor diseases (e.g. colorectal tumor). Indeed, nanostructures have been assembled with antibodies, proteins, and small‐molecule ligands targeted to specific tumor‐associated receptors to deliver chemotherapeutic agents. The targeted use of chemotherapeutics in animal tumor‐xenograft models showed greater pharmacological and clinical efficacy and decreased adverse events as antibody‐targeted liposomes effectively accumulate in CRC cells (Fortina et al. 2007). Nanogels containing 5‐fluorouracil (5‐FU) were assembled to be used as new colon‐targeting drug carrier systems. This delivery system was characterized by its excellent pH sensitive release property and effectively reduced toxicity (Ashwanikumar et al. 2012). Moreover, potential application of activated nucleoside analogs for the treatment of drug‐resistant tumors by oral delivery of nanogel drug was shown in studies of Senanayake et al. (2013).

      Targeted nanoparticles as a drug delivery system based on monoclonal antibodies are currently one of the main approaches for CRC therapy under preclinical development (Brennan et al. 2004; Weinberg et al. 2005).

      An enhanced antitumor activity of the photosensitizer meso‐Tetra(N‐methyl‐4‐pyridyl) porphine tetra tosylate (TMP) through encapsulation in antibody‐targeted chitosan/alginate nanoparticles was reported by Abdelghany et al. (2013). TMP is a photosensitizer that can be used in photodynamic therapy to induce cell death through generation of reactive oxygen species in targeted tumor cells. However, TMP is highly hydrophilic, and therefore, its ability to accumulate intracellularly is limited. Thus, its encapsulation in chitosan/alginate nanoparticles improved TMP uptake into human colorectal carcinoma HCT116 cells, unlike TMP or nanoparticles used alone. Moreover, these nanoparticles were further conjugated with antibodies targeting death receptor 5 (DR5), the cell surface apoptosis‐inducing receptor, upregulated in various types of cancer and found on HCT116 cells. This conjugation of nanoparticles had antibody‐enhanced uptake and cytotoxic potency of the generated nanoparticles (Abdelghany et al. 2013). Similarly, Fay et al. (2011) demonstrated the induction of apoptosis in colorectal HCT116 cancer cells using Poly(lactic‐co‐glycolic acid) (PLGA) nanoparticles coated with Conatumumab (AMG 655) death receptor 5‐specific antibodies (DR5‐NP). This conjugate preferentially targeted DR5‐expressing cells and presented a sufficient density of antibody paratopes to induce apoptosis via DR5, unlike free AMG 655 or non‐targeted control nanoparticles. They also demonstrated that DR5‐targeted nanoparticles encapsulating the cytotoxic drug camptothecin were effectively targeted to the tumor cells, affecting enhanced cytotoxicity through simultaneous drug delivery and apoptosis induction. The authors concluded that antibodies on nanoparticulate surfaces can be exploited for dual modes of action to enhance the therapeutic utility of the modality (Fay et al. 2011).

      Nanotechnology is a multidisciplinary research field that integrates a broad and diverse array of equipments derived from chemistry, engineering, biology, and medicine. Nanomaterials have a wider range of potential applications for the detection and treatment of various diseases, including GI disorders, due to the suitable physical and chemical properties of nanoparticles for in vivo applications.

      Nanostructures and nanotechnology‐based devices are still under active development of the design of diagnostic and therapeutic tools and devices. It is particularly important in case of cancer diseases as the effectiveness of traditional anticancer

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