Factors controlling the reactivity of divalent metal ions towards pheophytin a

Orzeł, Łukasz; Waś, Joanna; Kania, Agnieszka; Susz, Anna; Rutkowska‐Zbik, Dorota; Staroń, Jakub; Witko, Małgorzata; Stochel, Grażyna; Fiedor, Leszek

doi:10.1007/s00775-017-1472-1

Cited by 15 publications

(4 citation statements)

References 69 publications

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“…For instance, the complexation enthalpies of chloride complexes are in the range 49-173 and 883-1011 kJ/mol in aqueous solution and gas phase respectively. This drastic reduction in complexation enthalpies due to the solvation process previously illustrated by Orzel et al [33] is due to the metal-counterion-solvent interaction. The negligible values (Table 2) in comparison to the complexation enthalpies ( ) values exhibit the fact that these the complexation enthalpies are the dominant driving factors of complexation in solution.…”

Section: Complex Stabilitymentioning

confidence: 65%

Influence of Multiplicity on Properties of Ndx (X= 6, 7 and 8) Halide Transition Metal(Ii) Complexes of Glyoxime Ligand in Gas Phase and Aqueous Solution: Computational Assessment

LEONIE

JEAN

IDRICE

et al. 2023

Preprint

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The present paper has been focused on the ability of the glyoxime ligand to chelate to the [MX2] inorganic moieties in which M and X refer respectively to ndx transition metal(x = 6,7 and 8) and halogenated ligand(X =Br or Cl). The geometry optimizations at B3LYP/GEN level(LanL2DZ and 6-311+G (d,p) respectively for ndx transition metals (as well as halogen atoms) and for others atoms) have integrated the alteration of the multiplicity in each study media (gas phase and water). The passage from the fourth period transition metals to the sixth period ones enhances the reactivity of the complexes obtained regardless in gas phase. The metal-nitrogen bonds within higher multiplicity ndx (x=7,8) transition metal complexes are most unstable in both media. The [glyoxime ligand] ….[MX2] interaction strength increases in the following order: Fe2+< Co2+< Ni2+(3d series); Pd2+< Rh2+< Ru2+ (4d series) and Pt2+< Ir2+< Os2+ (5d series). For lower multiplicity bromide complexes exclusively, the enhancement of the donor character of the organic glyoxime ligand is promoted by its solvation except for nd6 transition metal complexes.

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Section: Complex Stabilitymentioning

confidence: 65%

Influence of Multiplicity on Properties of Ndx (X= 6, 7 and 8) Halide Transition Metal(Ii) Complexes of Glyoxime Ligand in Gas Phase and Aqueous Solution: Computational Assessment

LEONIE

JEAN

IDRICE

et al. 2023

Preprint

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“…As mentioned earlier, there are many factors that can influence the outcome of computational calculations, which must also be taken into consideration. The main thing that must be considered is, of course, the molecule to be investigated [86], but apart from that, there are several other factors, such as the presence of other molecules in the system like co-pigments, pH [78,86], temperature [87,88], and also the solvent effect [89,90]. Solvents are capable of causing the occurrence of spectral shifts and, as explained earlier, the wavelength of the complex formed becomes a direct parameter that can be studied in the development of metal detectors from natural pigments.…”

Section: Computational Methods For Studying Metal-pigment Interaction...mentioning

confidence: 99%

An Update in Computational Methods for Environmental Monitoring: Theoretical Evaluation of the Molecular and Electronic Structures of Natural Pigment–Metal Complexes

Maranata,

Megantara,

Hasanah

2024

Molecules

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Metals are beneficial to life, but the presence of these elements in excessive amounts can harm both organisms and the environment; therefore, detecting the presence of metals is essential. Currently, metal detection methods employ powerful instrumental techniques that require a lot of time and money. Hence, the development of efficient and effective metal indicators is essential. Several synthetic metal detectors have been made, but due to their risk of harm, the use of natural pigments is considered a potential alternative. Experiments are needed for their development, but they are expensive and time-consuming. This review explores various computational methods and approaches that can be used to investigate metal–pigment interactions because choosing the right methods and approaches will affect the reliability of the results. The results show that quantum mechanical methods (ab initio, density functional theory, and semiempirical approaches) and molecular dynamics simulations have been used. Among the available methods, the density functional theory approach with the B3LYP functional and the LANL2DZ ECP and basis set is the most promising combination due to its good accuracy and cost-effectiveness. Various experimental studies were also in good agreement with the results of computational methods. However, deeper analysis still needs to be carried out to find the best combination of functions and basis sets.

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“…Transition metal coordination in chlorophyll analogues always gives interesting chemical and physical features. − Prominently, incorporating palladium (Pd) and platinum (Pt) enables strong spin–orbital coupling for the heavy atom effect and thus enhances the singlet–triplet intersystem crossing (ISC). For example, the palladium complexes of bacteriochlorin are the most prominent examples as NIR triplet state photosensitizers, , especially that one of them, under the trade name of Tookad, , has already been admitted in Europe for the clinical use in photodynamic therapy of cancer.…”

Section: Bioinspired Construction Of Library For Nir Photosensitizersmentioning

confidence: 99%

Porpholactone Chemistry: An Emerging Approach to Bioinspired Photosensitizers with Tunable Near-Infrared Photophysical Properties

2019

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CONSPECTUS: Chlorophylls, known as the key building blocks of natural light-harvesting antennae, are essential to utilize solar energy from visible to near-infrared (NIR) region during the photosynthesis process. The fundamental studies for the relationship between structure and photophysical properties of chlorophylls disclosed the importance of βperipheral modification and thus boosted the fast growth of NIR absorbing/emissive porphyrinoids via altering the extent of π-conjugation and the degree of distortion from the planarity of macrocycle. Despite the tremendous progress made in various porphyrin-based synthetic models, it still remains a challenge to precisely modulate photophysical properties through fine-tuning of β-peripheral structures in the way natural chlorophylls do. With this in mind, we initiated a program and focused on meso-C 6 F 5 -substituted porpholactone (F 20 TPPL), in which one βpyrrolic double bond was replaced by a lactone moiety, as an attractive platform to construct the bioinspired library of NIR porphyrinoids. In this Account, we summarize our recent contributions to the bioinspired design, synthesis, photophysical characterization, and applications of porpholactones and their derivatives. We have developed a general, convenient method to directly prepare porpholactones in large scale up to gram, which forms the chemical basis of porpholactone chemistry. By modulation of the saturation level and in particular regioisomerization of β-dilactone moieties, a synthetic library constituted by a series of porpholactones and their derivatives has been established. Thanks to the electron-withdrawing nature of lactone moiety, derivation of the saturation levels gives help to build stable models for chlorin, bacteriochlorin, and tunichlorin. It is worth noting that regioisomerization of dilactone moieties mimics the relative orientation of β-substituents in natural chlorophylls and hemes, which was considered as the key factor to tune NIR absorption and reactivity. Porpholactones can illustrate the capability of fine-tuning photophysical properties including the excited triplet states by subtle alteration of β-peripheral structures in the presence of transition metals and lanthanides (Ln). Furthermore, they can serve as efficient photosensitizers for singlet oxygen and NIR Ln, showing potential applications in cell imaging and photocytotoxicity studies. The high luminescence, tunable structures, high cellular uptake, and intense NIR absorption render them as promising and competitive candidates for theranostics in vitro and in vivo. Therefore, extending the studies of "porpholactone chemistry" not only tests the fundamental understanding of the structure−function relationship that governs NIR photophysical properties of natural tetrapyrrole cofactors such as chlorophylls but also provides the guiding principles for the bioinspired design of NIR luminescent molecular probes with various applications. Taken together, as a new synthetic porphyrin derivative, porpholactone chemistry shines light on...

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Factors controlling the reactivity of divalent metal ions towards pheophytin a

Cited by 15 publications

References 69 publications

Influence of Multiplicity on Properties of Ndx (X= 6, 7 and 8) Halide Transition Metal(Ii) Complexes of Glyoxime Ligand in Gas Phase and Aqueous Solution: Computational Assessment

Influence of Multiplicity on Properties of Ndx (X= 6, 7 and 8) Halide Transition Metal(Ii) Complexes of Glyoxime Ligand in Gas Phase and Aqueous Solution: Computational Assessment

An Update in Computational Methods for Environmental Monitoring: Theoretical Evaluation of the Molecular and Electronic Structures of Natural Pigment–Metal Complexes

Porpholactone Chemistry: An Emerging Approach to Bioinspired Photosensitizers with Tunable Near-Infrared Photophysical Properties

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