Femtosecond Time-Resolved Studies on the Reaction Pathways for the Generation of Reactive Oxygen Species in Photodynamic Therapy by Indocyanine Green

Luo, Ting

26 August 2008

Photodynamic therapy (PDT), which utilizes the combination of light and a photosensitizing drug to cause tissue damages, has emerged as a novel clinical approach for the treatment of numerous cancers, as well as some other non-malignant conditions. Although a few photosensitizers have been approved for clinical uses, the mechanism of drug action, especially the initial photochemical reactions that lead to the formation of the reactive oxygen species (ROS), is still not well understood. Moreover, the PDT efficiency of currently used drugs is limited due to the strong attenuation of light by tissues in the wavelength range of 630-690 nm, where these drugs are photo-activated. Photosensitizers which are sensitive to near infrared (NIR) light are believed to be able to overcome this limitation. In this thesis work, the molecular mechanism of action of indocyanine green (ICG), a potential NIR PDT drug, was investigated using our femtosecond time-resolved laser spectroscopy. Femtosecond time-resolved fluorescence decay profiles of ICG in water were obtained using the fluorescence up-conversion technique. The lifetime of ICG excited singlet state was determined to be about 150 ps, directly from the fluorescence decay kinetic traces. The excited triplet-state yield of ICG in water was found to be extremely low, according to the result of the ground-state bleaching recovery measurement. This observation is contrary to the conventional understanding that the ROS would be generated mainly from the excited triplet state of the photosensitizer and, therefore, suggests the existence of a new reaction pathway. Pump-probe transient absorption spectroscopy was applied to study the reaction between ICG and oxygen in more details. The results reveal that the formation of ICG and oxygen ground-state complexes ([ICG]_m:[O₂]_n) is a key step in the generation of the ROS. Electron transfer from the excited singlet state of ICG to oxygen has been proposed to be a possible pathway for the generation of ROS.

Photodynamic therapy

Femtosecond Time-Resolved

Reactive Oxygen Species

Indocyanine Green

Physics

Femtosecond Time-Resolved Studies on the Reaction Pathways for the Generation of Reactive Oxygen Species in Photodynamic Therapy by Indocyanine Green

Luo, Ting

26 August 2008

Photodynamic therapy (PDT), which utilizes the combination of light and a photosensitizing drug to cause tissue damages, has emerged as a novel clinical approach for the treatment of numerous cancers, as well as some other non-malignant conditions. Although a few photosensitizers have been approved for clinical uses, the mechanism of drug action, especially the initial photochemical reactions that lead to the formation of the reactive oxygen species (ROS), is still not well understood. Moreover, the PDT efficiency of currently used drugs is limited due to the strong attenuation of light by tissues in the wavelength range of 630-690 nm, where these drugs are photo-activated. Photosensitizers which are sensitive to near infrared (NIR) light are believed to be able to overcome this limitation. In this thesis work, the molecular mechanism of action of indocyanine green (ICG), a potential NIR PDT drug, was investigated using our femtosecond time-resolved laser spectroscopy. Femtosecond time-resolved fluorescence decay profiles of ICG in water were obtained using the fluorescence up-conversion technique. The lifetime of ICG excited singlet state was determined to be about 150 ps, directly from the fluorescence decay kinetic traces. The excited triplet-state yield of ICG in water was found to be extremely low, according to the result of the ground-state bleaching recovery measurement. This observation is contrary to the conventional understanding that the ROS would be generated mainly from the excited triplet state of the photosensitizer and, therefore, suggests the existence of a new reaction pathway. Pump-probe transient absorption spectroscopy was applied to study the reaction between ICG and oxygen in more details. The results reveal that the formation of ICG and oxygen ground-state complexes ([ICG]_m:[O₂]_n) is a key step in the generation of the ROS. Electron transfer from the excited singlet state of ICG to oxygen has been proposed to be a possible pathway for the generation of ROS.

Photodynamic therapy

Femtosecond Time-Resolved

Reactive Oxygen Species

Indocyanine Green

Physics

Direct Observations of Scavenging Reactions of the Prehydrated Electron and OH Radicals by Femtosecond Time-Resolved Laser Spectroscopy

Ma, Yuhan

06 November 2014

Radiotherapy is the major curative therapy for carcinogesis. Identifying the effective species that induce DNA damage under ionizing radiation holds the key to improve and advance radiotherapy. In a cellular environment, most of the radiation energy is absorbed by water in the cell. Traditionally, the major radicals resulting from the radiolysis of water are thought to be the hydroxyl radical (OH) and the hydrated electron, whereas the (OH) radical is considered as the major contributor to radiation-induced DNA damage. With the birth of femtosecond time-resolved laser spectroscopy, the precursor to the hydrated electron, the so-called prehydrated electron, has been directly observed. The prehydrated electrons are the excited states of the well-known hydrated electron in nature. Very recently, it was pointed out that the prehydrated electron is a reactive species capable of causing lethal DNA double strand breaks. Thus the reductive DNA damage is proposed as a new molecular pathway for radiation-induced DNA damage. Therefore, the reaction dynamics of the prehydrated electron is of great interest to unravel the exact mechanism of radiation-induced DNA damage. In order to study the action of the prehydrated electron (epre???) in biologically relevant reactions, additional compounds need to be applied to regulate the prehydrated electrons. Such compounds are electron scavengers. In this thesis, the ultrafast electron transfer reaction of epre??? with an electron scavenger potassium nitrate was first investigated using our state-of-the-art femtosecond time-resolved pump-probe laser spectroscopy (fs-TRLS). Quantitative scavenging efficiency is successfully obtained by measuring the reaction rate constant, which is determined to be kpre = (0.75 ?? 0.5)??10^13 M^???1s^???1. This value is two-orders larger than the reaction rate constant of ehyd??? with potassium nitrate k =9.7??10^9 M^???1s^???1, confirming the high reactivity of epre???. Moreover, to comparing effectiveness of the reductive DNA damage induced by the prehydrated electron to the oxidative DNA damage induced by OH radicals, OH radical scavengers are used to quench OH radicals, leaving the prehydrated electron as the only active species. However, no studies have ever investigated the reactions between OH radical scavengers and the prehydrated electron. Here we performed the first quantitative study on the scavenging reactions of epre??? with the well-known OH radical scavengers, isopropanol and dimethyl sulfoxide (DMSO). We present the first evidence of such scavenging reactions and determine the reaction rate constants, which are measured to be k = 3.3 ?? 0.5??10^11 M^???1s^???1 and 8.7 ?? 0.5??10^11 M???1s???1 for isopropanol and DMSO in PBS buffer, respectively.These values are much higher than the reaction rate constants of isopropanol with OH radicals and DMSO with OH radicals (kisopropanol+OH = 2??10^9 M^???1s^???1 and kDMSO+OH = 7??10^9 M^???1s^???1). Furthermore, the OH radical is an important species produced from radiolysis of water. Knowing its reaction dynamics and kinetics can facilitate the comparison between the oxidative DNA damage induced by OH radicals and the reductive DNA damage by prehydrated electrons. By using an OH radical scavenger KSCN, we are able to directly observe the reaction dynamics of the OH radical. In addition, knowing the relative yield ratio of OH radicals and the epre??? (r = [OH]/[epre???]) is necessary for the comparison of the effectiveness of epre??? and OH radicals at inducing DNA damage. In our study, a quantitative analysis of the relative yield ratio r using an OH radical scavenger KSCN was obtained. The relative yield ratio is determined to be r = [OH]/[epre???] = 2.8 ?? 0.4. Incorporating this value into our recent studies on reductive DNA damage, we find that in terms of single-strand breaks and double-strand breaks yields per radical, an epre??? is nearly three times as effective as an OH at inducing DNA damage under irradiation. Overall, the results obtained from this thesis provide important information for future studies of epre??? action in biologically relevant reactions.

scavenging reactions

the prehydrated electron

OH radicals