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Computational Study of I-BODIPY as a Potential Triplet Photosensitizer for Singlet Oxygen Generation


核心概念
This study uses computational methods, primarily Time-Dependent Density Functional Theory (TD-DFT), to investigate the photophysical properties of I-BODIPY, an iodine-based photosensitizer, and its potential to generate singlet oxygen for photodynamic therapy applications.
摘要

Bibliographic Information

Baig, M. W., Pederzoli, M., Kývala, M., & Pittner, J. (2024). Quantum Chemical and Trajectory Surface Hopping Molecular Dynamics Study of Iodine-based BODIPY Photosensitizer. arXiv preprint arXiv:2411.10893.

Research Objective

This study aims to computationally investigate the photophysical properties of I-BODIPY, an iodine-substituted BODIPY derivative, and assess its potential as a triplet photosensitizer for singlet oxygen generation.

Methodology

The researchers employed a combination of quantum chemical calculations and trajectory surface hopping (TSH) molecular dynamics (MD) simulations. They benchmarked various TD-DFT functionals against higher-level methods like ADC(2) and CASPT2 to select the most appropriate functional for describing the excited-state properties of I-BODIPY. They then performed TSH MD simulations, incorporating nonadiabatic effects and spin-orbit couplings, to study the relaxation processes in I-BODIPY after photoexcitation.

Key Findings

  • The study identified two bright states in the visible spectrum of I-BODIPY, exhibiting a red shift compared to unsubstituted BODIPY due to the iodine substituents.
  • TSH MD simulations revealed that intersystem crossings in I-BODIPY occur on a timescale comparable to internal conversions.
  • After photoexcitation, the simulations showed a saturation point where the ratio of triplet to singlet populations reached approximately 4:1.
  • The calculated triplet quantum yield of 0.85 aligns qualitatively with the experimentally reported singlet oxygen generation yield of 0.99 ± 0.06.

Main Conclusions

The computational study confirms the high efficiency of I-BODIPY as a triplet photosensitizer, capable of generating singlet oxygen with a high quantum yield. The study highlights the importance of iodine substitution in enhancing intersystem crossing rates, leading to efficient triplet state population.

Significance

This research contributes to the understanding of the photophysical processes in iodine-substituted BODIPY derivatives, particularly their potential for photodynamic therapy. The findings provide valuable insights for designing and developing efficient photosensitizers for various applications.

Limitations and Future Research

The study primarily focuses on the gas-phase dynamics of I-BODIPY. Future research could explore the influence of solvent effects on the excited-state dynamics and singlet oxygen generation efficiency. Further investigations could also involve studying the interaction of I-BODIPY with biological targets to assess its efficacy in photodynamic therapy settings.

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统计
The calculated triplet quantum yield of I-BODIPY is 0.85. The experimentally reported singlet oxygen generation yield of I-BODIPY is 0.99 ± 0.06. The ADC(2) vertical excitation energy of the brightest state (S1) is 2.56 eV. The experimental value for the S1 excitation energy is 2.46 eV.
引用
"Iodinated BODIPY photosensitizers have an advantage over arylated or brominated BODIPY photosensitizers due to the more pronounced heavy atom effect of iodine compared to that of bromine, which results in much stronger SOC." "This specie has been reported as an efficient photosensitizer due to its high quantum yield of singlet oxygen (1O2) generation, which is essential for use in PDT."

更深入的查询

How would the presence of a biological environment, such as water or a lipid membrane, affect the photophysical properties and singlet oxygen generation efficiency of I-BODIPY?

The presence of a biological environment like water or a lipid membrane can significantly impact the photophysical properties and singlet oxygen generation efficiency of I-BODIPY through a variety of mechanisms: 1. Solvent Effects on Energy Levels: Polarity: Water, being highly polar, can interact differently with the ground and excited states of I-BODIPY compared to a non-polar solvent. This can lead to shifts in absorption and emission spectra (e.g., solvatochromism) and alter the relative energy gaps between singlet and triplet states. Hydrogen Bonding: Water molecules can form hydrogen bonds with the nitrogen or fluorine atoms in I-BODIPY. This can influence the molecule's geometry and electronic structure, potentially affecting non-radiative decay pathways and ISC rates. 2. Environmental Quenching: Collisional Quenching: Increased collisions with solvent molecules in a condensed phase can facilitate non-radiative energy transfer from the excited state of I-BODIPY, reducing its excited-state lifetime and the probability of ISC. Oxygen Accessibility: The local concentration and diffusion rate of oxygen in the biological environment will directly impact the efficiency of singlet oxygen generation. Lipid membranes, for instance, can have different oxygen permeability compared to aqueous solutions. 3. Molecular Interactions: Aggregation: I-BODIPY molecules might aggregate in aqueous environments or within lipid membranes, leading to self-quenching of fluorescence and potentially altering ISC rates. Protein Binding: Interactions with proteins, such as albumin, can influence the molecule's conformation, accessibility to oxygen, and its photophysical properties. 4. Impact on Singlet Oxygen Generation: The overall singlet oxygen generation efficiency will be a complex interplay of all the factors mentioned above. For example, while a polar environment might enhance ISC, it could also lead to increased collisional quenching, reducing the overall singlet oxygen yield. Studying Environmental Effects: To accurately predict the behavior of I-BODIPY in a biological setting, computational studies should incorporate solvent models (e.g., implicit or explicit solvation) or molecular dynamics simulations that mimic the biological environment. Experimental studies should be conducted in relevant solvents or biological media to complement theoretical predictions.

Could other heavy atoms besides iodine, such as bromine or astatine, be used to enhance intersystem crossing rates in BODIPY derivatives, and what would be the potential advantages or disadvantages compared to iodine?

Yes, other heavy atoms like bromine (Br) and astatine (At) can indeed be used to enhance ISC rates in BODIPY derivatives due to the heavy atom effect. However, each element comes with its own set of advantages and disadvantages: Bromine (Br): Advantages: Significant Heavy Atom Effect: Bromine is significantly heavier than carbon and exhibits a noticeable heavy atom effect, leading to enhanced ISC rates compared to unsubstituted BODIPY. Synthetic Accessibility: Brominated BODIPY derivatives are relatively easier to synthesize and modify compared to astatine analogs. Disadvantages: Weaker Effect than Iodine: The heavy atom effect of bromine is weaker than that of iodine, resulting in potentially lower ISC rates and singlet oxygen quantum yields compared to iodinated BODIPY. Astatine (At): Advantages: Strongest Heavy Atom Effect: Astatine, being the heaviest halogen, is expected to exhibit the most pronounced heavy atom effect, potentially leading to very fast ISC and high singlet oxygen yields. Disadvantages: Radioactivity: Astatine is a radioactive element, making its handling and applications challenging due to safety concerns and the need for specialized facilities. Limited Synthetic Accessibility: Astatine is extremely rare and synthetically challenging to incorporate into BODIPY structures. Stability: Astatine-carbon bonds are relatively weak, potentially leading to stability issues for astatinated BODIPY derivatives. In Summary: The choice of the heavy atom depends on the specific application and the trade-off between ISC efficiency, synthetic feasibility, stability, and safety considerations. While astatine offers the strongest heavy atom effect, its radioactivity and synthetic challenges limit its practical use. Bromine provides a balance between a noticeable heavy atom effect and synthetic accessibility, making it a viable alternative to iodine in certain cases.

Considering the potential applications of singlet oxygen in various fields, how can the insights gained from studying I-BODIPY's photophysics be translated to develop novel photosensitizers for applications beyond photodynamic therapy, such as photocatalysis or materials science?

The insights gained from studying I-BODIPY's photophysics can be leveraged to design novel photosensitizers for applications beyond PDT, such as photocatalysis and materials science: 1. Tuning Absorption and ISC: Red-shifted Absorption: By modifying the BODIPY core structure or introducing different substituents, the absorption wavelength can be shifted to the near-infrared (NIR) region. This is desirable for applications like photocatalysis and biological imaging where deeper tissue penetration is required. Heavy Atom Selection: The choice of heavy atom (e.g., Br, I, or even heavier elements) can be tailored to fine-tune the ISC rate and singlet oxygen quantum yield based on the specific application requirements. 2. Enhancing Stability and Solubility: Structural Modifications: Introducing bulky or charged groups can improve the stability of the photosensitizer and prevent aggregation in different environments. Polymer Conjugation: Conjugating the photosensitizer to polymers can enhance its solubility in aqueous solutions or organic solvents, making it suitable for a wider range of applications. 3. Targeted Delivery and Applications: Photocatalysis: BODIPY-based photosensitizers can be incorporated into heterogeneous catalytic systems or immobilized on solid supports for applications in organic synthesis, environmental remediation, and energy production. Materials Science: Singlet oxygen generated by BODIPY derivatives can be utilized for controlled oxidation reactions in polymer chemistry, surface modification, and the development of new materials with tailored properties. Theranostics: Combining the photosensitizing properties of BODIPY with imaging modalities (e.g., fluorescence) can lead to the development of theranostic agents for simultaneous diagnosis and treatment. Computational Design and Screening: Structure-Property Relationships: Computational studies can be employed to establish structure-property relationships and predict the photophysical properties of novel BODIPY derivatives. Virtual Screening: High-throughput computational screening can be used to identify promising candidates with desired absorption wavelengths, ISC rates, and singlet oxygen generation efficiencies. By combining computational design, targeted synthesis, and thorough characterization, the knowledge gained from I-BODIPY can pave the way for the development of a new generation of photosensitizers with tailored properties for a wide range of applications beyond PDT.
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