Light-tissue interactions for developing portable and wearable optoelectronic devices for sensing of tissue condition, diagnostics and treatment in photodynamic therapy (PDT)

Kulyk, Olena

January 2016

This thesis presents the development and in-vivo applications of wearable and portable devices for the investigation of light interaction with tissue involved in Photodynamic therapy (PDT) and during contraction of muscles. A hand-held device and a clinical method were developed for time course in-vivo imaging of the fluorescence of the photosensitizer Protoporphyrin IX (PpIX) in healthy and diseased skin with the aim to guide improvement of PDT protocols. The device was used in a small clinical study on 11 healthy volunteers and 13 patients diagnosed with non-melanoma skin cancer (NMSC). Two types of PpIX precursors were administered: Ameluz gel and Metvix® cream. The fluorescence was imaged with a 10 minute time step over three hours which was the recommended metabolism time before commencing PDT treatment at Ninewells Hospital, Dundee. The fluorescence time course was calculated by integrating the areas with the highest intensity. The fluorescence continued to grow in all subjects during the three hours. The time course varied between individuals. There was no statistical significance between either healthy volunteers or patients in Ameluz vs Metvix® groups; nor was there statistical difference between the three lesions groups (Actinic keratosis (AK) Ameluz vs AK Metvix® vs Basal cell carcinoma (BCC) Metvix®). The p-value was larger than 0.05 in a two sample t-test with unequal variances for all the groups. However, there was strong body site dependence between the head & neck compared to the lower leg & feet, or the trunk & hands body site groups (p-value < 0.01). One of the possible explanations for this was temperature and vasculature variation in skin at different body sites: the temperature is higher and the vasculature structure is denser at the head and the neck compared to the lower leg or the trunk. The temperature was not measured during the study. So in order to support this hypothesis, typical skin temperatures at the lesion sites were taken from the IR thermal images of healthy skin available in literature. PpIX fluorescence had a positive correlation to temperature. If this hypothesis is true, it will be highly important to PDT treatment. Increasing the temperature could speed up the metabolism and reduce the waiting time before starting the treatment; ambient temperature should be taken into account for daylight PDT; cooling air as pain management should be administered with caution. Potential improvements for wearable PDT light sources were investigated by modelling light transport in skin for the current LED-based Ambulight PDT device, a commercial OLED for future devices and a directional OLED developed in the group. The optical models were implemented in commercial optical software (with intrinsic Monte Carlo ray tracing and Henyey-Greenstein scattering approximation) which was validated on diffuse reflectance and transmittance measurements using in-house made tissue phantoms. The modelling was applied to investigate the benefits from diffusive and forward scattering properties of skin on light transmission in treatment light sources. 1 mm thick skin can only compensate approximately 10% of non-uniform irradiance. It means that uniform illumination is crucial for the treatment light sources. Forward scattering in skin showed a 10% improved light transmission from a collimated emission compared to a wide angle Lambertian emission. However, depth-dependent transmission measurements of directional vs Lambertian emission from organic light emitting films (a nano-imprinted grating was fabricated to provide directional emission in one of the films), collimated vs diffused HeNe laser light through fresh porcine skin did not show the expected improvement. This could be explained by skin roughness which was previously found to change the optical properties and may also affect light coupling. The modelling was applied to guide an optical design of another wearable device – a muscle contraction sensor. Muscle is fibrous and because of that scatters light differently in different directions. The sensor detects the change in backscattered light in parallel and perpendicular directions with respect to muscle fibres. The sensor was implemented on a wearable bandage on fully flexible substrate with flexible OLED and organic photodiodes. The major advantages of organic optoelectronic sensing compared to conventional electromyography (EMG) sensors are the ability to distinguish two types of contractions (isotonic and isometric), insensitivity to electromagnetic interference and the absence of an immune response due to non-invasive electrode-free sensing. Optical modelling was performed to understand the operation of the sensor. A 3D anisotropic optical model of scattering in muscle was created by geometrical manipulations with the standard Henyey-Greenstein scattering volumes. The penetration depth from the Super Yellow OLED was found to be 20-25 mm; the optimal separation between the source and the detector was found to be 20 mm. This distance provided a still detectable signal along with the best discrimination between the two backscatterings. When a 2 mm thick layer of skin and a 2 mm thick layer of adipose tissue were added to the model, the signal was hugely diffused. The discrimination between the two backscatterings decreased by three orders of magnitude, the penetration depth in muscle was reduced, and the intensity of the signal dropped down but was still detectable. With 5 mm thick adipose tissue and 2 mm thick skin the signal was too diffused and interacted with very shallow layers of muscle which approached the limits of the optical sensing of muscle activity.

Interação de pontos quânticos com fotossensibilizadores orgânicos na presença de estruturas nano-organizadas / Interaction of quantum dots with organic photosensitizers in the presence of nano-organized structures

Gustavo Gimenez Parra

19 January 2015

O sucesso de tratamento de câncer depende do seu diagnóstico e tratamento nas etapas iniciais da doença. Isso estimula a busca de novos métodos de diagnóstico e de tratamento sensíveis e tecnicamente simples. Entre esses métodos, o diagnóstico por fluorescência (DPF) e a fotoquimioterapia (FQT) atraem uma atenção especial, sendo não invasivos, sensíveis e fácil de usar. Os fotossensibilizadores (FS) atualmente utilizados em DPF e FQT são corantes orgânicos, os quais possuem algumas desvantagens, tais como instabilidade fotoquímica e baixa seletividade. Os pontos quânticos (PQ) são candidatos promissores para substituírem os FS clássicos por serem fotoestáveis, apresentarem amplo e intenso espectro de absorção óptica e luminescência com alto rendimento quântico. Contudo a iteração entre FS clássicos e os PQ pode aumentar a eficiência de ambos devido a transferência de energia entre eles. O objetivo geral deste trabalho foi estudar os processos da interação de FS orgânicos (as porfirinas PPh, TMPyP e TPPS4) com PQs (CdTe e CdSe/ZnS), funcionalizados com diferentes grupos, em solução aquosa e na presença de modelos nano-organizados de estruturas biológicas com a finalidade de avaliar seu potencial para aplicação em Fotoquimioterapia e Diagnóstico por Fluorescência. Dedicamos especial atenção aos processos de transferência de energia e de carga entre os PQs e os FS. Os PQs interagem efetivamente com as PPh, cuja interação se manifesta pelas mudanças da intensidade e do perfil dos espectros e das curvas de decaimento da luminescência de PQ e da porfirina, do tamanho das partículas espalhadoras na solução, do potencial zeta dentre outros parâmetros espectroscópicos e físico-químicos. Dentro das soluções aquosas homogêneas, o PQ e as PPh podem formar agregados mistos (PQ&PPh&PQ) ou simples (PQ&PPh) e a interação entre eles realiza-se através de mecanismos de curto e/ou longo alcance, dependendo do grupo funcional do PQ. Entretanto, a interação eletrostática repulsiva entre o PQ e outro composto pode estimular a desagregação dos PQs induzindo o aumento na intensidade da sua luminescência e do seu tempo de vida, provocando um aumento na contribuição dos tempos longos do decaimento da luminescência associados com a superfície do PQ. Essas relações entre o tipo de interação do PQ e da PPh podem ser extrapoladas aos sistemas que contêm PQ na presença de estruturas nano-organizadas. / The success of cancer treatment depends on the diagnosis and treatment in the early stages of the disease. This stimulates the research for new methods of sensitive diagnosis and technically simple treatment. Among these methods, the Optical Bioimaging by fluorescence (OBI) and Photochemotherapy (PCT) attract special attention, being non-invasive, sensitive and friendly use. The photosensitizers (PS) currently used in the OBI-PCT are organic dyes, which have some drawbacks such as photochemical instability and low selectivity. Quantum Dots (QD) are promising candidates to replace the classic PS being photostable, present broad and intensive spectrum of optical absorption and luminescence and, high quantum yield. Therefore the interaction between QDPS and the classic PS can increase the efficiency of both due to energy transfer between them. The aim of this work was to study the processes of organic PS interaction (porphyrins PPh, TMPyP and TPPS4) with QDs (CdTe and CdSe/ZnS), functionalized with different groups in aqueous solution and in the presence of nano-organized models of biological structures with order to evaluate its potential for use in Photochemotherapy and Optical Bioimaging. We devote special attention to energy transfer processes and cargo between the QDs and PS. The QDs effectively interact with PPh, whose interaction is manifested by changes in the intensity and profile of spectra and luminescence decay curves of QD and the porphyrin, the linear size of the scattering particles in the solution, the zeta potential among other spectroscopic and physical chemistry parameters. Within the homogeneous aqueous solutions, QD and Pph can form mixed aggregates (QD&PPh&QD) or simple (QD&PPh) and the interaction between them is carried out through short mechanisms and/or long range, depending on the functional group of the QD. However, the repulsive electrostatic interaction between the QD and another compound may stimulate the breakdown of QDs inducing the increase in the intensity of their luminescence and its lifetime, causing an increase in the contribution of long time decay of the luminescence associated with the surface of QD. These relationships between the type of interaction of the QD and PPh can be extrapolated to systems containing QD in the presence of nano-organized structures.

Fotossensibilizador orgânico

Ponto quântico

Sistema biomimético nano-organizado

Transferência de carga

Transferência de energia

Charge transfer

Energy transfer

Nano-organized system

Photochemotherapy and Optical bioimaging

Photosensitizer

Quantum Dots

Applying Fundamental Photochemistry to Drive Drug Development: The Photo-Dynamics and Reactions of Sulfur-Substituted Nucleic Acids

Pollum, Marvin

08 February 2017

No description available.

Chemistry

Molecules

Pharmaceuticals

Physical Chemistry

Quantum Physics

Analytical Chemistry

Biochemistry

Experiments

sulfur-substituted nucleobases

thiobases

photosensitizer

excited-state dynamics

femtosecond

intersystem crossing

triplet state

triplet yield

reactive oxygen species

singlet oxygen

photocrosslinking

photochemotherapy

photodynamic therapy