RESUMO
BACKGROUND: Cancer is, at present, among the leading causes of morbidity globally. Despite advances in treatment regimens for cancer, patients suffer from poor prognoses. In this context, the availability of vast natural resources seems to alleviate the shortcomings of cancer chemotherapy. The last decade has seen a breakthrough in the investigations related to the anticancer potential of dietary phytoconstituents. Interestingly, a handsome number of bioactive principles, ranging from phenolic acids, phenylpropanoids, flavonoids, stilbenes, and terpenoids to organosulphur compounds have been screened for their anticancer properties. Among the phenylpropanoids currently under clinical studies for anticancer activity, eugenol is a promising candidate. Eugenol is effective against cancers like breast, cervical, lung, prostate, melanomas, leukemias, osteosarcomas, gliomas, etc., as evident from preclinical investigations. OBJECTIVE: The review aims to focus on cellular and molecular mechanisms of eugenol for cancer prevention and therapy. METHODS: Based on predetermined criteria, various scholarly repositories, including PubMed, Scopus, and Science Direct were analyzed for anticancer activities of eugenol. RESULTS: Different biochemical investigations reveal eugenol inducing cytotoxicity, inhibiting phases of the cell cycles, programmed cell death, and auto-phagocytosis in studied cancer lines; thus, portraying eugenol as a promising anticancer molecule. A survey of current literature has unveiled the molecular mechanisms intervened by eugenol in exercising its anticancer role. CONCLUSION: Based on the critical analysis of the literature, eugenol exhibits vivid signaling pathways to combat cancers of different origins. The reports also depict the advancement of novel nano-drug delivery approaches upgrading the therapeutic profile of eugenol. Therefore, eugenol nanoformulations may have enormous potential for both the treatment and prevention of cancer.
RESUMO
INTRODUCTION: Since decades, cancer is a major public health problem worldwide. The increasing knowledge of molecular and tumor biology has significantly changed the cancer treatment paradigms during the past few years. AREA COVERED: Conventionally, the first-line treatment of solid tumors is their surgical removal followed by chemotherapy and/or radiation treatment. Unfortunately, these approaches often fail, and the patient may discontinue the treatment before the complete eradication of tumors due to therapeutic and toxicological limitations. In this regard, the nucleic acid-based treatment therapy has been widely used in the management of cancer. However, nucleic acid delivery to the target sites is highly challenging because of their molecular size, difficulties to pass cellular membranes, and susceptibility toward enzymatic and/or chemical degradation. EXPERT OPINION: Researchers have now overcome many problems associated with delivering nucleic acids to the target tissues by preventing them from off-target side effects and overcoming rapid degradation and clearance in the bloodstream using the lipid-polymer hybrid nanoparticles (LPHNs). The present review, therefore, aims to provide an overview account on LPNHs, their preparation, characterization, application with special emphasis on intracellular delivery/transfection of nucleic acids in the management of cancer, and key aspects of challenges in its delivery and clinical transition.
