Photothermal therapy-mediated autophagy in breast cancer treatment: Progress and trends.

Breast cancer (BC) has different clinical manifestations due to its diverse mechanism of action that has created many challenges to choosing appropriate treatment. Recent findings of the biology of breast cancer including the mechanisms of survival and metastasis, understanding the effective signaling pathways in tumor formation and modeling of cancer cell responses to the therapeutic approaches provided significant advances in BC treatment. In this regard, the use of phototherapy-based approaches such as photothermal therapy (PTT) would be an encouraging alternative for tumor suppression through activating autophagy or suppressing cell signaling that influences the cell cycle to induce cell death. Since autophagy has a dual opposite role consisting of pro-survival and growth inhibition in breast cancer microenvironments, the regulation of autophagy would be playing promising roles in the treatment of BC using PTT. This review updates the molecular mechanisms that PTT could evoke autophagic cell death in breast cancer. Moreover, this article provides insights into the biological effects of autophagy-targeted-PTT as a promising strategy for breast cancer therapy.

Recent advances and trends in nanoparticles based photothermal and photodynamic therapy.

Light-mediated therapies, including photodynamic therapy (PDT) and photothermal therapy (PTT) have been exploited as minimally invasive techniques for ablation of various tumors., Both modalities may eradicate tumors with minimal side effects to normal tissues and organs. Moreover, developments of light-mediated approaches using nanoparticles (NPs) and photosensitizer (PS) as diagnostic and therapeutic agents may have a crucial role in achieving successful cancer treatment. In recent years, novel nanoplatforms and strategies have been investigated to boost the therapeutic effect.. In this regard, gold, iron oxide, graphene oxide nanoparticles and hybrid nanocomposites have attracted attention.. Moreover, the combination of these materials with PS, in the form of hybrid NPs, reduces in vitro and in vivo normal tissue cytotoxicity, improves their solubility property in the biological environment and enhances the therapeutic effects. In this review, we look into the basic principles of PTT and PDT with their strengths and limitations to treat cancers. We also will discuss light-based nanoparticles and their PTT and PDT applications in the preclinical and clinical translation. Also, recent advances and trends in this field will be discussed along with the clinical challenges of PTT and PDT.

Osteogenic effects of the bioactive small molecules and minerals in the scaffold-based bone tissue engineering.

Reconstruction of the damaged bone is a striking challenge in the medical field. The bone grafts as a current treatment is associated with inherent limitations; hence, the bone tissue engineering as an alternative therapeutic approach has been considered in the recent decades. Bone tissue engineering aims at replacing the lost tissue and restoring its function by recapitulating the natural regeneration process. Concerted participation and combination of the biocompatible materials, osteoprogenitor/ stem cells and bioactive factors closely mimic the bone microenvironment. The bioactive factors regulate the cell behavior and they induce the stem cells to osteogenic differentiation by activating specific signaling cascades. Growth factors (GFs) are the most important bioactive molecules and mediators of the natural bone repair process. Although these soluble factors have approved applications in the bone regeneration, however, there are several limitations such as the instability, high dose requirements, and serious side effects which could restrict their clinical usage. Alternatively, a new generation of bioactive molecules with the osteogenic properties are used. The non-peptide organic or inorganic molecules are physiologically stable and non-immunogenic due to their small size. Many of them are obtained from the natural resources and some are synthesized through the chemical methods. As a result, these molecules have been introduced as the cost-effective osteogenic agents in the bone tissue regeneration. In this paper, three groups of these bioactive agents including the organic small molecules, minerals and metallic nanoparticles have been investigated, considering their function in accelerating the bone regeneration. We review the recent in vitro and in vivo studies that utilized the osteogenic molecules to promote the bone formation in the scaffold-based bone tissue engineering systems.