Journal of Photochemistry and Photobiology C: Photochemistry Reviews最新文献

Cocrystallization has evolved as an attractive prospect to broaden the chemical landscape of a drug entity, expand its therapeutic scope, and address physicochemical deficiencies of an active pharmaceutical ingredient (API). The non-covalent approaches to address the solubility and bioavailability of BCS Class-II and Class-IV drugs is an archetypal example and is a prolific topic. The present review highlights various supramolecular methods employed in addressing the photoinstability in drugs, emphasizing crystal engineering approaches. Because a greater proportion of the drugs are formulated in the solid-state, the structural factors—crystal packing, intermolecular interactions, packing density—remain a critical determinant in the observed extent of stability. Comprehending and amending these structural determinants using crystal engineering concepts proposes to address the photoinstability in drugs. Also, we highlight the pros and cons of the different adopted strategies in terms of formulation and the underlying challenges and put in prospect. The review provides a correlative assessment of the structure-property relations that could further augment the foundations of factual knowledge in drug stability.

Perovskite solar cells (PSCs) fabricated with two-dimensional (2D) halide and 2D-3D mixed-halide materials are remarkable for their optoelectronic properties. The 2D perovskite structures are extremely stable but show limited charge transport and large bandgap for solar cell applications. To overcome these challenges, multidimensional 2D-3D perovskite materials are used to maintain simultaneously, a long-term stability, and high performance. In this review, we discuss the recent progress and the advantages of 2D and 2D-3D perovskite materials as absorber for solar cell applications. First, we discuss the structure and the unique properties of 2D and multidimensional 2D-3D perovskites materials. Second, the stability of 2D and 2D-3D mixed perovskites and the perspects of PSCs are hashed out.

Phthalocyanine (Pc) dyes are photoactive compounds that can absorb and emit light in a large range of the UV–vis spectrum, with recognized potential for medical applications. Considering the low solubility of Pc macrocycles in water, it is important to use cationic symptoms on their skeleton to improve their amphiphilicity for biomedical applications. The use of suitable pyridinium groups on Pc is a good strategy to solve this drawback and make them more eff ;ective to photoinactivate microorganisms via a photodynamic inactivation (PDI) approach. This review focuses the synthesis of quaternized Pc dyes, their photophysical and photochemical properties, and their antimicrobial photoinactivation efficiency. This innovative study compares, for the first time, different cationic moieties on Pc taking into account the efficiency of singlet oxygen (¹O₂), quantum yield (Φ_Δ) generation, fluorescence quantum yield (Φ_F), (photo)stability, light irradiation type (visible/white and/or red light), maximized overlapped absorption effect of Pc (S- and/or Q-band) vs light system irradiation type, and water solubility (n-octanol/water partition coefficient, P_o/w), when these parameters are determined and provided in the multidisciplinary reports. This approach is also relevant to conjugate free-base (H₂Pc) and metalated phthalocyanines (MPc, M = Zn²⁺, Mg²⁺, In³⁺, Ga³⁺, Ge³⁺, Si⁴⁺, etc.) with aromatic or aliphatic substituents linked by N, O or S atoms on the peripheral or axial positions of the Pc structures, such as e.g. (methoxy, oxy, or thio)pyridinium, ammonium, or benzimidazolium units, etc. Here, the influence of the structural peripheral (α- and/or β-position of Pc) or axial substituents type, number and positive charge position that can affect the PDI process will be analysed. These aspects are important to design versatile molecules that can interact with pathogenic microorganisms of variable size, subcellular architecture, biochemical composition, and susceptibility to externally added chemical agents. This review highlights the important developments of several modifications of cationic Pc dyes for the PDI of microorganisms, such as pathogenic bacteria, fungi, and virus.

Triggering physiological responses with a light switch has become a reality with the development of smart molecular probes such as photolabile protecting groups (PPGs), able to “uncage” biological ligands on demand. To make the light switch virtually harmless and confine the excitation to the single-cell level, the caged ligands can be released using two-photon (2P) absorption and 2P microscopy using red/infrared light. This exceptional level of precision however comes at the cost of a reduced photosensitivity and a poor compatibility of early PPGs with 2P excitation. This review aims to provide a tutorial guidebook to the design of 2P-sensitive PPGs suitable for optobiology by discussing challenges, strategies and progress in uncaging of bioactive compounds. To do so, we first recall the photo-physical principles governing 2P absorption, and the resulting ground rules in the design of efficient 2P absorbing organic dyes. We then detail how following these guidelines has led to tremendous progress in the development of a new generation of caged compounds, and the implications in the fields of biophotonics, from neurology to targeted therapy.

The consensus on the effects of excessive sun exposure on human health has long emphasized the negative effects of solar UV radiation. Nevertheless, although UV radiation has been demonized, less is known about the consequences of sun exposure while using sunscreen, which can lead to high visible light exposure. UV and visible light play key roles in vitamin D synthesis, reduction of blood pressure, among other beneficial effects. In this review, we aim to provide a comprehensive view of the wide range of responses of the human skin to sunlight by revisiting data on the beneficial and harmful effects of UV and visible light. We start by exploring the interaction of photons in the skin at several levels including physical (depth of photon penetration), chemical (light absorption and subsequent photochemical events), and biological (how cells and tissues respond). Skin responses to sun exposure can only be comprehensively understood through a consideration of the light-absorbing molecules present in the skin, especially the light-sensing proteins called opsins. Indeed, many of the cellular responses to sun exposure are modulated by opsins, which act as the “eyes of the skin”.

Ammonia is the most necessitate and second largely produces chemical reagent worldwide to address the need of the fertilizer industry, as a precursor for many value-added chemicals and a competing source (17.6 wt% H₂) for the blooming hydrogen economy. Although N₂ constitutes 78.09 % of the earth's atmosphere, however, its conversion to ammonia is strenuous because of its non-polar and triple bond character. To address the burgeoning demand, ammonia is typically synthesized via the conventional energy and capital intensive Haber-Bosch technique utilizing natural gas and releasing tons of (CO₂) to the environment. On this basis, cost-effective photon-driven dinitrogen reduction reaction (NRR) is aroused thriving attention as a sustainable and eco-friendly process for ammonia production under ambient conditions. Yet, the photocatalytic ammonia production is not up to the mark for industrial application due to low conversion rate, less catalytic selectivity, ambiguous mechanism, and limited faradic or solar-to-chemical efficiency. Further, the NRR activity of a catalyst essentially depends upon its electronic and surface texture; hence the fabrication of advanced materials is of paramount interest to enhance the performance. The present review covers the underlying mechanism of N₂ photoreduction, prevailing theories, different catalytic engineering techniques, various detection methods, and critical challenges encountered in the theme of photofixation of dinitrogen to ammonia. Additionally, the overarching goal of this review is to bestow an outline of recent research articles in earmarking high-caliber photocatalytic systems and hence planting a strong foundation to ensure the succeeding improvement in this promising and hastily stretching field of dinitrogen photofixation research.

Photovoltaic technology provides a promising approach for solar energy conversion. One significant factor limiting the efficiency is the poor light harvesting of solar energy, which is related to the mismatch between the energy distribution of photons and the absorption of semiconductor materials or dye. Light-conversion phosphors have been explored as spectral converters to improve the light-harvesting ability in sensitized solar cells. Many progressive studies have been conducted to expand the family of light-conversion phosphors and exploit their application in sensitized solar cells, bringing emerging opportunities to develop commercial sensitized solar cells. In this review, we survey the development of light-conversion phosphors in sensitized solar cells. First, the application and conversion mechanism of light-conversion phosphors, including up-conversion phosphors, down-conversion phosphors, up/down conversion phosphors, and long-lasting phosphors, are summarized in detail. After that, the challenging problems and possible solutions of applying light-conversion phosphors to sensitized solar cells are discussed. The review also highlights some new ideas in the development of sensitized solar cells and the application of light-conversion phosphors in other solar technology.