Antimicrobial Activity of the Manganese Photoactivated Carbon Monoxide-Releasing Molecule [Mn(CO)3(tpa-κ3N)]+Against a PathogenicEscherichia colithat Causes Urinary Infections

Tinajero-Trejo, Mariana; Rana, Namrata; Nagel, Christoph; Jesse, Helen E.; Smith, Thomas W.; Wareham, Lauren K.; Hippler, Michael; Schatzschneider, Ulrich; Poole, Robert K.

doi:10.1089/ars.2015.6484

Cited by 59 publications

(55 citation statements)

References 73 publications

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“…For example, Nobre et al reported that the administration of CO gas into the growing cultures could cause significant impairment to the growth of Escherichia coli and Staphylococcus aureus . Recently, CORMs with the capacity of delivering CO directly to intracellular targets have been used as bactericides against a wide range of microorganisms, such as Pseudomonas aeruginosa , Mycobacterium tuberculosis , Helicobacter pylori , pathogenic Escherichia coli , and Neisseria gonorrhoeae . Importantly, CORMs were shown to be more potent bactericides than CO gas due to the accumulation of CORMs inside bacterial cells .…”

Section: The Application Of Co In Disease Therapymentioning

confidence: 99%

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Yan

Zhu

et al. 2019

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Carbon monoxide (CO) therapy has emerged as a hot topic under exploration in the field of gas therapy as it shows the promise of treating various diseases. Due to the gaseous property and the high affinity for human hemoglobin, the main challenges of administrating medicinal CO are the lack of target selectivity as well as the toxic profile at relatively high concentrations. Although abundant CO releasing molecules (CORMs) with the capacity to deliver CO in biological systems have been developed, several disadvantages related to CORMs, including random diffusion, poor solubility, potential toxicity, and lack of on‐demand CO release in deep tissue, still confine their practical use. Recently, the advent of versatile nanomedicine has provided a promising chance for improving the properties of naked CORMs and simultaneously realizing the therapeutic applications of CO. This review presents a brief summarization of the emerging delivery strategies of CO based on nanomaterials for therapeutic application. First, an introduction covering the therapeutic roles of CO and several frequently used CORMs is provided. Then, recent advancements in the synthesis and application of versatile CO releasing nanomaterials are elaborated. Finally, the current challenges and future directions of these important delivery strategies are proposed.

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Section: The Application Of Co In Disease Therapymentioning

confidence: 99%

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Yan

Zhu

et al. 2019

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“…as model systems for known manganese based metalloenzymes like Mn-catalase, arginase 8,9 or the OEC in PSII. 7,10 To probe this concept, we additionally investigated the light-triggered CO substitution for the Mn I -carbonyl complex 3, which is also already well investigated as photoCORM 11 and for its therapeutic use, 12 bearing the potentially tetradentate trispyridylmethylamin (tpa) ligand, for which µ-oxido bridged Mn III /Mn IV complexes of high catalase activity have already been reported. 13…”

Section: Introductionmentioning

confidence: 99%

Light- or oxidation-triggered CO release from [Mn^I(CO)₃(κ³-L)] complexes: reaction intermediates and a new synthetic route to [MnIII/IV2(μ-O)₂(L)₂] compounds

et al. 2016

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The reaction products and intermediates of the three CO-releasing manganese(i) coordination compounds [Mn(tpm)(CO)], [Mn(bpza)(CO)] and [Mn(tpa)(CO)] were analysed by combining IR-spectroscopy, electrochemical measurements and single-crystal XRD. The intermediate formation of manganese(i) biscarbonyl compounds and the rather facile oxidation of these species were identified as key reaction steps that accompany CO liberation. For the use of [Mn(CO)] complexes as light-triggered CO sources, the results indicate that in this case photo- and redox-chemistry seem to be strongly coupled which could be important and potentially even useful in the pharmacological context. Additionally, one has to be aware of the fact that [Mn(κ-L)(solv)] complexes, the primary reaction products after CO substitution, are able to bind to proteins, which was demonstrated using bovine serum albumin as a model. And finally it could be shown that the CO-release reactions can be used as a new synthetic route to prepare multinuclear μ-oxido-bridged manganese complexes: the mixed-valence compound [Mn(μ-O)(tpa)] could be prepared in a single step from [Mn(tpa)(CO)]via photo- or electrochemically induced CO substitution.

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“…Taken together, the results showed promising steps for the use of photoCORMs as drug templates for the treatment of breast cancer. Tinajero and coworkers reported an Mn-based photoactivated CORM which reduces growth and viability of Escherichia coli, only by light induction [56]. They demonstrated that CO binds to specific intracellular sites, namely, respiratory oxidases and a globin protein expressed in a particular strain, while the Mn metal center is not accumulated in the cells.…”

Section: Uv Light Photoactivated Cormsmentioning

confidence: 99%

Visible Light-Activated PhotoCORMs

Kottelat

Zobi

2017

Inorganics

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Despite its well-known toxicity, carbon monoxide (CO) is now recognized as a potential therapeutic agent. Its inherent toxicity, however, has limited clinical applications because uncontrolled inhalation of the gas leads to severe systemic derangements in higher organisms. In order to obviate life-threatening effects and administer the gas by bypassing the respiratory system, CO releasing molecules (CORMs) have emerged in the last decades as a plausible alternative to deliver controlled quantities of CO in cellular systems and tissues. As stable, solid-storage forms of CO, CORMs can be used to deliver the gas following activation by a stimulus. Light-activated CORMs, known as photoCORMs, are one such example. This class of molecules is particularly attractive because, for possible applications of CORMs, temporal and spatial control of CO delivery is highly desirable. However, systems triggered by visible light are rare. Most currently known photoCORMs are activated with UV light, but red light or even infrared photo-activation is required to ensure that structures deeper inside the body can be reached while minimizing photo-damage to healthy tissue. Thus, one of the most challenging chemical goals in the preparation of new photoCORMs is the reduction of radiation energy required for their activation, together with strategies to modulate the solubility, stability and nontoxicity of the organic or organometallic scaffolds. In this contribution, we review the latest advances in visible light-activated photoCORMs, and the first promising studies on near-infrared light activation of the same.

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Antimicrobial Activity of the Manganese Photoactivated Carbon Monoxide-Releasing Molecule [Mn(CO)₃(tpa-κ³N)]⁺Against a PathogenicEscherichia colithat Causes Urinary Infections

Cited by 59 publications

References 73 publications

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Light- or oxidation-triggered CO release from [Mn^I(CO)₃(κ³-L)] complexes: reaction intermediates and a new synthetic route to [MnIII/IV2(μ-O)₂(L)₂] compounds

Visible Light-Activated PhotoCORMs

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Antimicrobial Activity of the Manganese Photoactivated Carbon Monoxide-Releasing Molecule [Mn(CO)3(tpa-κ3N)]+Against a PathogenicEscherichia colithat Causes Urinary Infections

Cited by 59 publications

References 73 publications

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Light- or oxidation-triggered CO release from [MnI(CO)3(κ3-L)] complexes: reaction intermediates and a new synthetic route to [MnIII/IV2(μ-O)2(L)2] compounds

Visible Light-Activated PhotoCORMs

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Antimicrobial Activity of the Manganese Photoactivated Carbon Monoxide-Releasing Molecule [Mn(CO)₃(tpa-κ³N)]⁺Against a PathogenicEscherichia colithat Causes Urinary Infections

Light- or oxidation-triggered CO release from [Mn^I(CO)₃(κ³-L)] complexes: reaction intermediates and a new synthetic route to [MnIII/IV2(μ-O)₂(L)₂] compounds