Your search keyword '"Curnow, Alison"' showing total 152 results

1. Experimental investigation of a combinational iron chelating protoporphyrin IX prodrug for fluorescence detection and photodynamic therapy

Author

Magnussen, Anette, Reburn, Charlotte, Perry, Alexis, Wood, Mark, and Curnow, Alison

Published

2022

2. Improving in vitro photodynamic therapy through the development of a novel iron chelating aminolaevulinic acid prodrug

Author

Curnow, Alison, Perry, Alexis, and Wood, Mark

Published

2019

3. Novel Iron-Chelating Prodrug Significantly Enhanced Fluorescence-Mediated Detection of Glioma Cells Experimentally In Vitro

Author

Reburn, Charlotte, primary, Gawthorpe, George, additional, Perry, Alexis, additional, Wood, Mark, additional, and Curnow, Alison, additional

Published

2023

4. Altered cellular redox homeostasis and redox responses under standard oxygen cell culture conditions versus physioxia

Author

Ferguson, Daniel C.J., Smerdon, Gary R., Harries, Lorna W., Dodd, Nicholas J.F., Murphy, Michael P., Curnow, Alison, and Winyard, Paul G.

Published

2018

5. Photodynamic therapy with 5-aminolaevulinic acid : techniques for enhancement

Author

Curnow, Alison

Subjects

571.45, Radiobiology & radiation biology

Abstract

Photodynamic therapy (PDT) is a non-thermal technique which can be used to create localised tissue damage. It requires the activation of a pre-administered photosensitiser (in the presence of molecular oxygen) with light of a specific wavelength to form a cytotoxic species. 5-Aminolaevulinic acid (ALA) is an attractive photosensitising agent for PDT as its photoreactive derivative protoporphyrin IX (PPIX), is metabolised within one to two days, eliminating prolonged skin photosensitivity (the major side effect of other clinically used photosensitisers). However, at the maximum dose patients tolerate by mouth (60 mg/kg) only superficial effects are seen. A need exists for the outcome of this treatment modality to be enhanced without increasing the administered dose of ALA. ALA PDT manipulates the haem biosynthesis pathway to create an accumulation of PPIX. By chelating iron (using a hydroxypyridinone iron chelator), this thesis shows that it is possible to amplify this PPIX accumulation and thus significantly enhance the effect of ALA PDT. This is demonstrated in normal and malignant rat colon, normal rat skin and normal rabbit uterus, using several routes of administration. Various light dose fractionation regimes were also investigated in this thesis. A single 150 second interruption to the illumination, when placed appropriately, was found to significantly enhance ALA PDT in normal and malignant rat colon. The reasons for this are unclear but marked differences in tissue oxygenation were observed during continuous and fractionated treatments. Additionally, relocalisation of PPIX during the dark interval was detected and the inhibition of reperfusion injury was found to prevent the tissue damage normally produced in this model. This thesis has investigated two different methods of ALA PDT enhancement and found that the addition of a hydroxypyridinone iron chelator and the technique of light dose fractionation can both be used successfully in vivo, to significantly enhance ALA induced PDT.

Published

1999

6. The hydroxypyridinone iron chelator CP94 increases methyl-aminolevulinate-based photodynamic cell killing by increasing the generation of reactive oxygen species

Author

Dogra, Yuktee, Ferguson, Daniel C.J., Dodd, Nicholas J.F., Smerdon, Gary R., Curnow, Alison, and Winyard, Paul G.

Published

2016

7. The effects of protoporphyrin IX-induced photodynamic therapy with and without iron chelation on human squamous carcinoma cells cultured under normoxic, hypoxic and hyperoxic conditions

Author

Blake, Emma, Allen, James, and Curnow, Alison

Published

2013

8. Stress and Unusual Events Exacerbate Symptoms in Menièreʼs Disease: A Longitudinal Study

Author

Yeo, Nicola L., White, Mathew P., Ronan, Natalie, Whinney, David J., Curnow, Alison, and Tyrrell, Jessica

Published

2018

9. Radon and Skin Cancer in Southwest England: An Ecologic Study

Author

Wheeler, Benedict W., Allen, James, Depledge, Michael H., and Curnow, Alison

Published

2012

10. Monitoring the accumulation and dissipation of the photosensitizer protoporphyrin IX during standard dermatological methyl-aminolevulinate photodynamic therapy utilizing non-invasive fluorescence imaging and quantification

Author

Tyrrell, Jessica, Campbell, Sandra M., and Curnow, Alison

Published

2011

11. Protoporphyrin IX photobleaching during the light irradiation phase of standard dermatological methyl-aminolevulinate photodynamic therapy

Author

Tyrrell, Jessica, Campbell, Sandra, and Curnow, Alison

Published

2010

12. Validation of a non-invasive fluorescence imaging system to monitor dermatological PDT

Author

Tyrrell, Jessica, Campbell, Sandra, and Curnow, Alison

Published

2010

13. Using natural dietary sources of antioxidants to protect against ultraviolet and visible radiation-induced DNA damage: An investigation of human green tea ingestion

Author

Malhomme de la Roche, Helena, Seagrove, Susan, Mehta, Anisha, Divekar, Preshita, Campbell, Sandra, and Curnow, Alison

Published

2010

14. An investigation into the awareness and understanding of the ultraviolet index forecasts in the South West of England

Author

Morris, Jenny, Laing-Morton, Tish, Marno, Penny, and Curnow, Alison

Published

2011

15. Enhancement of methyl-aminolevulinate photodynamic therapy by iron chelation with CP94: an in vitro investigation and clinical dose-escalating safety study for the treatment of nodular basal cell carcinoma

Author

Pye, Andrew, Campbell, Sandra, and Curnow, Alison

Published

2008

16. Experimental investigation of a combinational iron chelating protoporphyrin IX prodrug for fluorescence detection and photodynamic therapy

Author

Magnussen, Anette, primary, Reburn, Charlotte, additional, Perry, Alexis, additional, Wood, Mark, additional, and Curnow, Alison, additional

Published

2021

17. The Relationship Between Protoporphyrin IX Photobleaching During Real-Time Dermatological Methyl-Aminolevulinate Photodynamic Therapy (MAL-PDT) and Subsequent Clinical Outcome†

Author

Tyrrell, Jessica S., Campbell, Sandra M., and Curnow, Alison

Published

2010

18. Comparing and Combining Light Dose Fractionation and Iron Chelation to Enhance Experimental Photodynamic Therapy With Aminolevulinic Acid

Author

Curnow, Alison, MacRobert, Alexander J., and Bown, Stephen G.

Published

2006

19. The green tea polyphenol (−)-epigallocatechin gallate and green tea can protect human cellular DNA from ultraviolet and visible radiation-induced damage

Author

Morley, Nick, Clifford, Tim, Salter, Leo, Campbell, Sandra, Gould, David, and Curnow, Alison

Published

2005

20. The use of comet assay data with a simple reaction mechanism to evaluate the relative effectiveness of free radical scavenging by quercetin, epigallocatechin gallate and N-acetylcysteine in UV-irradiated MRC5 lung fibroblasts

Author

Salter, Leo, Clifford, Tim, Morley, Nick, Gould, David, Campbell, Sandra, and Curnow, Alison

Published

2004

21. Paracetamol can exacerbate irradiation-induced DNA damage

Author

Curnow, Alison, Salter, Leo, Morley, Nick, Campbell, Sandra, and Gould, David

Published

2002

22. Regression Analysis of Protoporphyrin IX Measurements Obtained during Dermatological Photodynamic Therapy

Author

Tyrrell, Jessica, Paterson, Cheryl, and Curnow, Alison

Subjects

Ameluz), methyl aminolevulinate (MAL, imaging, non-melanoma skin cancer (NMSC), photobleaching, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, lcsh:RC254-282, Article, photodynamic therapy (PDT), dermatology, Metvix), aminolevulinic acid (ALA, fluorescence, protoporphyrin IX (PpIX)

Abstract

Photodynamic therapy (PDT) is a light activated drug therapy that can be used to treat a number of dermatological cancers and precancers. Improvement of efficacy is required to widen its application. Clinical protoporphyrin IX (PpIX) fluorescence data were obtained using a pre-validated, non-invasive imaging system during routine methyl aminolevulinate (MAL)-PDT treatment of 172 patients with licensed dermatological indications (37.2% actinic keratosis, 27.3% superficial basal cell carcinoma and 35.5% Bowen’s disease). Linear and logistic regressions were employed to model any relationships between variables that may have affected PpIX accumulation and/or PpIX photobleaching during irradiation and thus clinical outcome at three months. Patient age was found to be associated with lower PpIX accumulation/photobleaching, however only a reduction in PpIX photobleaching appeared to consistently adversely affect treatment efficacy. Clinical clearance was reduced in lesions located on the limbs, hands and feet with lower PpIX accumulation and subsequent photobleaching adversely affecting the outcome achieved. If air cooling pain relief was employed during light irradiation, PpIX photobleaching was lower and this resulted in an approximate three-fold reduction in the likelihood of achieving clinical clearance. PpIX photobleaching during the first treatment was concluded to be an excellent predictor of clinical outcome across all lesion types.

Published

2019

23. Altered cellular redox homeostasis and redox responses under standard oxygen cell culture conditions versus physioxia

Author

Ferguson, Daniel CJ, Smerdon, Gary R, Harries, Lorna W, Dodd, Nicholas JF, Murphy, Michael P, Curnow, Alison, Winyard, Paul G, Murphy, Mike [0000-0003-1115-9618], and Apollo - University of Cambridge Repository

Subjects

Oxygen, Photochemotherapy, Cell Culture Techniques, Animals, Homeostasis, Humans, Hyperoxia, Reactive Oxygen Species, Oxidation-Reduction, Metabolic Networks and Pathways, Mitochondria

Abstract

In vivo, mammalian cells reside in an environment of 0.5-10% O2 (depending on the tissue location within the body), whilst standard in vitro cell culture is carried out under room air. Little is known about the effects of this hyperoxic environment on treatment-induced oxidative stress, relative to a physiological oxygen environment. In the present study we investigated the effects of long-term culture under hyperoxia (air) on photodynamic treatment. Upon photodynamic irradiation, cells which had been cultured long-term under hyperoxia generated higher concentrations of mitochondrial reactive oxygen species, compared with cells in a physioxic (2% O2) environment. However, there was no significant difference in viability between hyperoxic and physioxic cells. The expression of genes encoding key redox homeostasis proteins and the activity of key antioxidant enzymes was significantly higher after the long-term culture of hyperoxic cells compared with physioxic cells. The induction of antioxidant genes and increased antioxidant enzyme activity appear to contribute to the development of a phenotype that is resistant to oxidative stress-induced cellular damage and death when using standard cell culture conditions. The results from experiments using selective inhibitors suggested that the thioredoxin antioxidant system contributes to this phenotype. To avoid artefactual results, in vitro cellular responses should be studied in mammalian cells that have been cultured under physioxia. This investigation provides new insights into the effects of physioxic cell culture on a model of a clinically relevant photodynamic treatment and the associated cellular pathways.

Published

2018

24. Insights gained from regression analysis of PpIX fluorescence imaging undertaken during routine dermatological photodynamic therapy

Author

Tyrrell, Jess, primary, Paterson, Cheryl, additional, and Curnow, Alison, additional

Published

2019

25. Experimental findings utilising a new iron chelating ALA prodrug to enhance protoporphyrin IX-induced photodynamic therapy

Author

Reburn, Charlotte, primary, Anayo, Lizette, additional, Magnussen, Anette, additional, Perry, Alexis, additional, Wood, Mark, additional, and Curnow, Alison, additional

Published

2019

26. Monte Carlo Simulations of Heat Deposition During Photothermal Skin Cancer Therapy Using Nanoparticles

Author

Jeynes, J. Charles G., primary, Wordingham, Freddy, additional, Moran, Laura J., additional, Curnow, Alison, additional, and Harries, Tim J., additional

Published

2019

27. An experimental investigation of a novel iron chelating protoporphyrin IX prodrug for the enhancement of photodynamic therapy

Author

Anayo, Lizette, primary, Magnussen, Anette, additional, Perry, Alexis, additional, Wood, Mark, additional, and Curnow, Alison, additional

Published

2018

28. Insights gained from regression analysis of PpIX fluorescence imaging undertaken during routine dermatological photodynamic therapy.

Author

Tyrrell, Jess, Paterson, Cheryl, and Curnow, Alison

Published

2019

29. Experimental findings utilising a new iron chelating ALA prodrug to enhance protoporphyrin IX-induced photodynamic therapy.

Author

Reburn, Charlotte, Anayo, Lizette, Magnussen, Anette, Perry, Alexis, Wood, Mark, and Curnow, Alison

Published

2019

30. Experimental findings utilising a new iron chelating ALA prodrug to enhance protoporphyrin IX-induced photodynamic therapy

Author

Hasan, Tayyaba, Reburn, Charlotte, Anayo, Lizette, Magnussen, Anette, Perry, Alexis, Wood, Mark, and Curnow, Alison

Published

2019

31. Insights gained from regression analysis of PpIX fluorescence imaging undertaken during routine dermatological photodynamic therapy

Author

Hasan, Tayyaba, Tyrrell, Jess, Paterson, Cheryl, and Curnow, Alison

Published

2019

32. An Evaluation of Root Phytochemicals Derived fromAlthea officinalis(Marshmallow) andAstragalus membranaceusas Potential Natural Components of UV Protecting Dermatological Formulations

Author

Curnow, Alison, primary and Owen, Sara J., additional

Published

2016

33. The importance of iron chelation and iron availability during PpIX-induced photodynamic therapy

Author

Curnow, Alison, primary and Pye, Andrew, additional

Published

2015

34. Photodynamic Therapy with Aminolevulinic Acid and Iron Chelators: A Clinical Example of Redox Signaling

Author

Pye, Andrew, primary, Dogra, Yuktee, additional, Tyrrell, Jessica, additional, Winyard, Paul G., additional, and Curnow, Alison, additional

35. The Cellular and Molecular Carcinogenic Effects of Radon Exposure: A Review

Author

Robertson, Aaron, primary, Allen, James, additional, Laney, Robin, additional, and Curnow, Alison, additional

Published

2013

36. An Evaluation of Root Phytochemicals Derived from Althea officinalis (Marshmallow) and Astragalus membranaceus as Potential Natural Components of UV Protecting Dermatological Formulations.

Author

Curnow, Alison and Owen, Sara J.

Published

2016

37. An In Vitro Comparison of the Effects of the Iron‐Chelating Agents, CP94 and Dexrazoxane, on Protoporphyrin IX Accumulation for Photodynamic Therapy and/or Fluorescence Guided Resection

Author

Blake, Emma, primary, Allen, James, additional, and Curnow, Alison, additional

Published

2011

38. The Hydroxypyridinone Iron Chelator CP94 Can Enhance PpIX-induced PDT of Cultured Human Glioma Cells

Author

Blake, Emma, primary and Curnow, Alison, additional

Published

2010

39. The utilization of a non-invasive fluorescence imaging system to follow clinical dermatological MAL-PDT

Author

Tyrrell, Jessica, primary, Campbell, Sandra, additional, and Curnow, Alison, additional

Published

2009

40. Enhancing protoporphyrin IX-induced PDT

Author

Curnow, Alison, primary, Pye, Andrew, additional, and Campbell, Sandra, additional

Published

2009

41. Using iron chelating agents to enhance dermatological PDT

Author

Curnow, Alison, primary, Dogra, Yuktee, additional, Winyard, Paul, additional, and Campbell, Sandra, additional

Published

2009

42. 12th World Congress of the International Photodynamic Association (IPA), 11–15th June 2009, Seattle, USA

Author

Curnow, Alison, primary

Published

2009

43. Direct Comparison of δ-Aminolevulinic Acid and Methyl-Aminolevulinate-Derived Protoporphyrin IX Accumulations Potentiated by Desferrioxamine or the Novel Hydroxypyridinone Iron Chelator CP94 in Cultured Human Cells

Author

Pye, Andrew, primary and Curnow, Alison, additional

Published

2007

44. Biochemical Manipulation via Iron Chelation to Enhance Porphyrin Production from Porphyrin Precursors

Author

Pye, Andrew, primary and Curnow, Alison, additional

Published

2007

45. A Clinical Investigation to Determine the Effect of Pressure Injection on the Penetration of Topical Methyl Aminolevulinate into Nodular Basal Cell Carcinoma of the Skin

Author

Campbell, S. M., primary, Pye, Andrew, additional, Horton, S., additional, Matthew, J., additional, Helliwell, P., additional, and Curnow, Alison, additional

Published

2007

46. Hg(II) Exposure Exacerbates UV-Induced DNA Damage in MRC5 Fibroblasts: A Comet Assay Study

Author

BRADFIELD, WENDY, primary, PYE, ANDREW, additional, CLIFFORD, TIM, additional, SALTER, LEO, additional, GOULD, DAVID, additional, CAMPBELL, SANDRA, additional, and CURNOW, ALISON, additional

Published

2006

47. Comparing and combining light dose fractionation and iron chelation to enhance experimental photodynamic therapy with aminolevulinic acid

Author

Curnow, Alison, primary, MacRobert, Alexander J., additional, and Bown, Stephen G., additional

Published

2006

48. The green tea polyphenol (-)-epigallocatechin gallate and green tea can protect human cellular DNA from ultraviolet and visible radiation-induced damage

Author

Morley, Nick, primary, Clifford, Tim, additional, Salter, Leo, additional, Campbell, Sandra, additional, Gould, David, additional, and Curnow, Alison, additional

Published

2005

49. Topical photodynamic therapy with the iron chelator, CP94, for nodular basal cell carcinoma

Author

Morton, Colin A., primary, Campbell, Sandra, additional, Gould, David, additional, and Curnow, Alison, additional

Published

2004

50. The utilization of a non-invasive fluorescence imaging system to follow clinical dermatological MAL-PDT.

Author

Tyrrell, Jessica, Campbell, Sandra, and Curnow, Alison

Published

2009