Evaluation of the cellular effects of two metallophthalocyanine compounds activated during photodynamic therapy (PDT) on an oesophageal cancer cell line
- Authors: Kresfelder, Tina Louise
- Date: 2009-05-19T06:40:30Z
- Subjects: Photochemotherapy , Esophagus , Cancer cells , Cancer treatment , Phthalcyanines , Photosensitizing compounds
- Type: Thesis
- Identifier: uj:8383 , http://hdl.handle.net/10210/2549
- Full Text:
- Authors: Kresfelder, Tina Louise
- Date: 2009-05-19T06:40:30Z
- Subjects: Photochemotherapy , Esophagus , Cancer cells , Cancer treatment , Phthalcyanines , Photosensitizing compounds
- Type: Thesis
- Identifier: uj:8383 , http://hdl.handle.net/10210/2549
- Full Text:
The effect of guided imagery and relaxation on patients receiving treatment for non-metastatic cancer
- Authors: Campbell-Gillies, Lynne
- Date: 2008-10-31T09:11:53Z
- Subjects: Cancer diagnosis , Cancer treatment , Cancer radiotherapy
- Type: Thesis
- Identifier: http://ujcontent.uj.ac.za8080/10210/367927 , uj:13916 , http://hdl.handle.net/10210/1426
- Description: D. Litt et Phil. , It is well known that high levels of anxiety and/or depression often accompany the diagnosis and treatment of cancer. Literature from various sources, but in particular from the fairly new field of research, Psychoneuroimmunology, also provides ample evidence that excessive anxiety and/or depression can be immunosuppressive. It makes sense, therefore, that any intervention restoring balance to the immuno-regulatory system, thereby allowing the body’s innate healing processes to focus on eliminating cancer, is highly desirable. In line with current thinking based on the mind-body connection as well as cognitive behavioural techniques utilised in many therapeutic settings, various psychological interventions have been found to help the patient gain a better sense of control over distressing symptoms and side-effects of cancer. Some of these include: basic cognitive restructuring, hypnotherapy, relaxation-meditation techniques, art and music therapy, and guided imagery. Substantial international research illustrates the beneficial effect that relaxation and/or guided imagery provides in such diverse settings including work, sport and health. In this regard, it was decided to run a pilot study to ascertain whether a customised tape recording with a relaxation and guided imagery dialogue aimed at helping patients manage and cope with negative symptoms of cancer, could significantly reduce anxiety levels in patients with cancer receiving radiotherapy. To operationalise the above, 30 men and women, aged between 20 and 80, with Stages 1, 2 or 3 breast, prostrate, gynaecological cancers, and head and neck cancers, who were about to commence radical (minimum 25 fractions) radiotherapy, were randomly selected to an experimental and a control group. A consecutive sample, pre-test post-test experimental design was applied to this study in which the experimental and control groups were subjected to pre- and post radiotherapy Hospital Anxiety & Depression (HAD) Scale, Institute for Personality Assessment and Training (IPAT) Anxiety Scale and blood pressure measurements during their 1st, 3rd, 6th week cycle of treatments, as well as a final measurement 12 weeks after commencement of therapy. The main hypothesis of this pilot study was that there would be statistically significant decreases in levels of anxiety as a result of the intervention of guided imagery tape recording in patients with non-metastatic cancer undergoing curative radiotherapy. For the intervention, each experimental participant was taught a relaxation technique and then following an interview a customised guided imagery dialogue developed for the participant’s sole use. The participant was requested to listen to this tape at least once a day. The control group had the same pre- and post tests as the experimental group, but did not receive any intervention. Statistical analysis of the data revealed that the experimental group showed a tendency towards decreased blood pressure and anxiety over the course of radiotherapy. The most significant change, however, was noted in terms of diastolic blood pressure, suggesting that the intervention corresponded to a physiological decrease in anxiety. There was not a statistically significant difference in terms of the measured psychological variables. A general conclusion to this pilot study suggests that whilst guided imagery may contribute to a lowering of anxiety, additional cognitive intervention would probably affect a more substantial and sustained change in the patient. Although this pilot study revealed some methodological weaknesses the results are sufficiently encouraging to warrant further in-depth research regarding the use of guided imagery as a cost-effective, easy method for individuals to learn and utilise as part of their integrative cancer treatment programme.
- Full Text:
- Authors: Campbell-Gillies, Lynne
- Date: 2008-10-31T09:11:53Z
- Subjects: Cancer diagnosis , Cancer treatment , Cancer radiotherapy
- Type: Thesis
- Identifier: http://ujcontent.uj.ac.za8080/10210/367927 , uj:13916 , http://hdl.handle.net/10210/1426
- Description: D. Litt et Phil. , It is well known that high levels of anxiety and/or depression often accompany the diagnosis and treatment of cancer. Literature from various sources, but in particular from the fairly new field of research, Psychoneuroimmunology, also provides ample evidence that excessive anxiety and/or depression can be immunosuppressive. It makes sense, therefore, that any intervention restoring balance to the immuno-regulatory system, thereby allowing the body’s innate healing processes to focus on eliminating cancer, is highly desirable. In line with current thinking based on the mind-body connection as well as cognitive behavioural techniques utilised in many therapeutic settings, various psychological interventions have been found to help the patient gain a better sense of control over distressing symptoms and side-effects of cancer. Some of these include: basic cognitive restructuring, hypnotherapy, relaxation-meditation techniques, art and music therapy, and guided imagery. Substantial international research illustrates the beneficial effect that relaxation and/or guided imagery provides in such diverse settings including work, sport and health. In this regard, it was decided to run a pilot study to ascertain whether a customised tape recording with a relaxation and guided imagery dialogue aimed at helping patients manage and cope with negative symptoms of cancer, could significantly reduce anxiety levels in patients with cancer receiving radiotherapy. To operationalise the above, 30 men and women, aged between 20 and 80, with Stages 1, 2 or 3 breast, prostrate, gynaecological cancers, and head and neck cancers, who were about to commence radical (minimum 25 fractions) radiotherapy, were randomly selected to an experimental and a control group. A consecutive sample, pre-test post-test experimental design was applied to this study in which the experimental and control groups were subjected to pre- and post radiotherapy Hospital Anxiety & Depression (HAD) Scale, Institute for Personality Assessment and Training (IPAT) Anxiety Scale and blood pressure measurements during their 1st, 3rd, 6th week cycle of treatments, as well as a final measurement 12 weeks after commencement of therapy. The main hypothesis of this pilot study was that there would be statistically significant decreases in levels of anxiety as a result of the intervention of guided imagery tape recording in patients with non-metastatic cancer undergoing curative radiotherapy. For the intervention, each experimental participant was taught a relaxation technique and then following an interview a customised guided imagery dialogue developed for the participant’s sole use. The participant was requested to listen to this tape at least once a day. The control group had the same pre- and post tests as the experimental group, but did not receive any intervention. Statistical analysis of the data revealed that the experimental group showed a tendency towards decreased blood pressure and anxiety over the course of radiotherapy. The most significant change, however, was noted in terms of diastolic blood pressure, suggesting that the intervention corresponded to a physiological decrease in anxiety. There was not a statistically significant difference in terms of the measured psychological variables. A general conclusion to this pilot study suggests that whilst guided imagery may contribute to a lowering of anxiety, additional cognitive intervention would probably affect a more substantial and sustained change in the patient. Although this pilot study revealed some methodological weaknesses the results are sufficiently encouraging to warrant further in-depth research regarding the use of guided imagery as a cost-effective, easy method for individuals to learn and utilise as part of their integrative cancer treatment programme.
- Full Text:
Synthesis and evaluation of nitrogen-and phosphorus-donor platinum and gold complexes as anti-cancer agents
- Authors: Segapelo, Tebogo Vincent
- Date: 2010-03-16T07:30:49Z
- Subjects: Gold compounds , Platinum compounds , Gold - Therapeutic use , Platinum - Therapeutic use , Complex compounds synthesis , Cancer treatment
- Type: Thesis
- Identifier: uj:6682 , http://hdl.handle.net/10210/3086
- Description: Ph.D. , Chapter 1 presents a brief overview on the development of platinum, ruthenium and gold anti-cancer complexes. The clinical success of cisplatin has been a tremendous impetus for the design of metal-based antitumor drugs. Its mechanism of action is therefore briefly discussed, as well as the toxic side effects of its clinical use and the cellular resistance to the drug. It is its side effects and drug resistance that have stimulated the development of cisplatin analogues and other metal based anti-cancer agents. Compounds showing most promise are ruthenium complexes which are structurally different but have the same stability and show similar modes of binding to DNA. The last part of the introduction deals with the development of gold(I) and gold(III) complexes, the main topics of the research described in this thesis. Chapter 2 reports on the attempted preparation of dppf and dippf gold(III) complexes. However, the reaction of these diphosphines with H[AuCl4] and Na[AuCl4] all led to isolation of gold(I) complexes (dppf)Au2X2 (X = Cl (1), Br (3)) and (dippf)Au2X2 (X = Cl (2), Br (4)). In an attempt to oxidize the gold(I) complexes, (dppf)Au2Br2 (3) and (dippf)Au2Br2 (4) were reacted with excess bromine yielding two new complexes (C5H4Br3)(PR2)AuBr (R = Ph, 5; R = i-Pr, 6). This bromination reaction could be extended to the ligands and bromination of the free diphosphinoferrocene ligands produced the expected brominated cyclopentenes (C5H4Br3)(PR2) (R = Ph, 7; R = i-Pr, 8) in good yields. However, these could not be complexed to gold due to reduced basicity of 7 and 8. When the bromination was performed under wet aerobic conditions the oxidized pseudo-centrosymmetric product, [doppf][FeBr4] (9) {doppf = 1,1’-bis(oxodiphenylphosphino)ferrocene, was obtained as the major product. Solid-state structures of 1, 2, 4, 6, and 9 were established by means of single-crystal X-ray crystallography. Chapter 3 reports on the use of chiral Josiphos and Walphos diphosphine ligands to form palladium, platinum and gold complexes. The platinum complexes were prepared by reacting the ligands with [PtCl2(cod)] while the palladium complexes were prepared from [PdCl2(NCMe)2]. The complexes obtained had the general formula [MCl2(P-P)], where M = Pd, Pt, and P-P = Josiphos or Walphos ligand, and were obtained in good yields. The X-ray structures of a palladium(II) and a platinum(II) complex of the same Josiphos ligand were determined. The Josiphos complexes 12 and 14 show good solubility in common solvents. Furthermore, the complexes remained soluble and stable in a 40:60 water:DMSO mixture. The Walphos complexes 13 and 15 rapidly precipitated under the same conditions. In line with this limited solubility 13 and 15 showed minimal cytotoxic effects when compared to their Josiphos counterparts 12 and 14 whose cytotoxic effects (in terms of IC50 values ) were six to seven times less than cisplatin. Reaction of the Walphos ligand and H[AuCl4] in a 1:1 ratio gave a dinuclear gold(I) complex 18 while the same reaction with Josiphos gave a mixture of intractable materials. However a 1:1 reaction of the Josiphos with AuCl(tht) gave a mononuclear three-coordinate gold(I) complex 16. A P^N chiral ligand comprising of a diphenylphosphine and a pyrazole moiety was also prepared and was complexed with AuCl(tht) to give a phosphine bound gold(I) complex 19. The structure of this complex was determined by X-ray studies. From the studies it became evident that apart from increasing the basicity of compound the pyrazolyl moiety remains dangling and the complex shows bond parameters similar to those observed with monophosphine ferrocenyl complexes. Chapter 4 reports on the bidentate and monodentate gold(III) complexes based on the (pyrazolylmethyl)pyridine ligands together with their platinum(II) complexes. The denticity of the complexes depended on the position of the pyrazolyl moiety relative to the pyridine nitrogen. When ortho-substituted ligands were reacted in a 1:1 ratio with H[AuCl4] in a mixture of water and ethanol at room temperature, bidentate cationic complexes of the general formula [AuCl2(PyCH2R2pz)][X], where R = Me (20), X = AuCl4-; R = Ph (21), X = Cl-; t-Bu (22), X= Cl- and p-tol (23), X = AuCl4-, were obtained. When para-substituted ligands were used under same reaction conditions, neutral monodentate complexes [AuCl3(PyCH2R2pz)], where R = Me (24) and R = Ph (25), were obtained. Platinum(II) complexes were obtained using K2[PtCl4] in a mixture of water and ethanol under reflux, and affords neutral complexes of the type [PtCl2(PyCH2R2pz)], where R = Me (27), Ph (28), t-Bu (29) and p-tol (30). When acetone was used instead of ethanol monoacetonylplatinum(II) complex (29a) was formed and on prolonged heating formation of the diacetonyl complex (28b) was observed. Both the platinum and the gold complexes were evaluated for their anti-cancer potency. The gold(III) complexes were devoid of any activity while the platinum complex 30 showed activity 8 times lower than cisplatin. The structures of 23, 25, 28, 29 and 29a were determined from single-crystal X-ray diffraction studies. In Chapter 5, tridentate complexes based on bis(pyrazolylethyl)amine are reported. These were prepared with the aim of improving water-solubility and cytotoxicity of the resulting complexes. New synthetic methods for preparation of the ligands NH(CH2CH2pz)2 (R = Me (L7), H (L8), t-Bu (L9)) under mild reaction conditions were developed albeit the yields obtained were generally low. The reaction of these ligands with H[AuCl4] gave corresponding tridentate dicationic gold(III) complexes [NH(CH2CH2pz)2][X]2 (R = Me (31), H (32), X = AuCl4 , and R = t-Bu (33), X = Cl-). Despite the ligands stabilizing the gold(III) ion, they showed no solubility in water. In an attempt to make the ligand system water soluble, a thiocarbamate analogue with pyrazolyl groups replaced by hydroxyl groups was prepared. However the resulting gold(III) complex [Au{CS2N(CH2CH2OH)2}2][AuCl2] (34) was found to be only soluble in DMSO.
- Full Text:
- Authors: Segapelo, Tebogo Vincent
- Date: 2010-03-16T07:30:49Z
- Subjects: Gold compounds , Platinum compounds , Gold - Therapeutic use , Platinum - Therapeutic use , Complex compounds synthesis , Cancer treatment
- Type: Thesis
- Identifier: uj:6682 , http://hdl.handle.net/10210/3086
- Description: Ph.D. , Chapter 1 presents a brief overview on the development of platinum, ruthenium and gold anti-cancer complexes. The clinical success of cisplatin has been a tremendous impetus for the design of metal-based antitumor drugs. Its mechanism of action is therefore briefly discussed, as well as the toxic side effects of its clinical use and the cellular resistance to the drug. It is its side effects and drug resistance that have stimulated the development of cisplatin analogues and other metal based anti-cancer agents. Compounds showing most promise are ruthenium complexes which are structurally different but have the same stability and show similar modes of binding to DNA. The last part of the introduction deals with the development of gold(I) and gold(III) complexes, the main topics of the research described in this thesis. Chapter 2 reports on the attempted preparation of dppf and dippf gold(III) complexes. However, the reaction of these diphosphines with H[AuCl4] and Na[AuCl4] all led to isolation of gold(I) complexes (dppf)Au2X2 (X = Cl (1), Br (3)) and (dippf)Au2X2 (X = Cl (2), Br (4)). In an attempt to oxidize the gold(I) complexes, (dppf)Au2Br2 (3) and (dippf)Au2Br2 (4) were reacted with excess bromine yielding two new complexes (C5H4Br3)(PR2)AuBr (R = Ph, 5; R = i-Pr, 6). This bromination reaction could be extended to the ligands and bromination of the free diphosphinoferrocene ligands produced the expected brominated cyclopentenes (C5H4Br3)(PR2) (R = Ph, 7; R = i-Pr, 8) in good yields. However, these could not be complexed to gold due to reduced basicity of 7 and 8. When the bromination was performed under wet aerobic conditions the oxidized pseudo-centrosymmetric product, [doppf][FeBr4] (9) {doppf = 1,1’-bis(oxodiphenylphosphino)ferrocene, was obtained as the major product. Solid-state structures of 1, 2, 4, 6, and 9 were established by means of single-crystal X-ray crystallography. Chapter 3 reports on the use of chiral Josiphos and Walphos diphosphine ligands to form palladium, platinum and gold complexes. The platinum complexes were prepared by reacting the ligands with [PtCl2(cod)] while the palladium complexes were prepared from [PdCl2(NCMe)2]. The complexes obtained had the general formula [MCl2(P-P)], where M = Pd, Pt, and P-P = Josiphos or Walphos ligand, and were obtained in good yields. The X-ray structures of a palladium(II) and a platinum(II) complex of the same Josiphos ligand were determined. The Josiphos complexes 12 and 14 show good solubility in common solvents. Furthermore, the complexes remained soluble and stable in a 40:60 water:DMSO mixture. The Walphos complexes 13 and 15 rapidly precipitated under the same conditions. In line with this limited solubility 13 and 15 showed minimal cytotoxic effects when compared to their Josiphos counterparts 12 and 14 whose cytotoxic effects (in terms of IC50 values ) were six to seven times less than cisplatin. Reaction of the Walphos ligand and H[AuCl4] in a 1:1 ratio gave a dinuclear gold(I) complex 18 while the same reaction with Josiphos gave a mixture of intractable materials. However a 1:1 reaction of the Josiphos with AuCl(tht) gave a mononuclear three-coordinate gold(I) complex 16. A P^N chiral ligand comprising of a diphenylphosphine and a pyrazole moiety was also prepared and was complexed with AuCl(tht) to give a phosphine bound gold(I) complex 19. The structure of this complex was determined by X-ray studies. From the studies it became evident that apart from increasing the basicity of compound the pyrazolyl moiety remains dangling and the complex shows bond parameters similar to those observed with monophosphine ferrocenyl complexes. Chapter 4 reports on the bidentate and monodentate gold(III) complexes based on the (pyrazolylmethyl)pyridine ligands together with their platinum(II) complexes. The denticity of the complexes depended on the position of the pyrazolyl moiety relative to the pyridine nitrogen. When ortho-substituted ligands were reacted in a 1:1 ratio with H[AuCl4] in a mixture of water and ethanol at room temperature, bidentate cationic complexes of the general formula [AuCl2(PyCH2R2pz)][X], where R = Me (20), X = AuCl4-; R = Ph (21), X = Cl-; t-Bu (22), X= Cl- and p-tol (23), X = AuCl4-, were obtained. When para-substituted ligands were used under same reaction conditions, neutral monodentate complexes [AuCl3(PyCH2R2pz)], where R = Me (24) and R = Ph (25), were obtained. Platinum(II) complexes were obtained using K2[PtCl4] in a mixture of water and ethanol under reflux, and affords neutral complexes of the type [PtCl2(PyCH2R2pz)], where R = Me (27), Ph (28), t-Bu (29) and p-tol (30). When acetone was used instead of ethanol monoacetonylplatinum(II) complex (29a) was formed and on prolonged heating formation of the diacetonyl complex (28b) was observed. Both the platinum and the gold complexes were evaluated for their anti-cancer potency. The gold(III) complexes were devoid of any activity while the platinum complex 30 showed activity 8 times lower than cisplatin. The structures of 23, 25, 28, 29 and 29a were determined from single-crystal X-ray diffraction studies. In Chapter 5, tridentate complexes based on bis(pyrazolylethyl)amine are reported. These were prepared with the aim of improving water-solubility and cytotoxicity of the resulting complexes. New synthetic methods for preparation of the ligands NH(CH2CH2pz)2 (R = Me (L7), H (L8), t-Bu (L9)) under mild reaction conditions were developed albeit the yields obtained were generally low. The reaction of these ligands with H[AuCl4] gave corresponding tridentate dicationic gold(III) complexes [NH(CH2CH2pz)2][X]2 (R = Me (31), H (32), X = AuCl4 , and R = t-Bu (33), X = Cl-). Despite the ligands stabilizing the gold(III) ion, they showed no solubility in water. In an attempt to make the ligand system water soluble, a thiocarbamate analogue with pyrazolyl groups replaced by hydroxyl groups was prepared. However the resulting gold(III) complex [Au{CS2N(CH2CH2OH)2}2][AuCl2] (34) was found to be only soluble in DMSO.
- Full Text:
The effect of a zinc sulphophthalocyanine used during photodynamic therapy on an oesophageal cancer cell line
- Authors: Yiannakis, Nicole
- Date: 2009-04-30T09:21:46Z
- Subjects: Photochemotherapy , Oesophagus , Cancer treatment , Cancer cells , Photosensitizing compounds
- Type: Thesis
- Identifier: uj:8319 , http://hdl.handle.net/10210/2447
- Description: M.Sc. , The ideal cancer treatment modality should not only cause tumour regression and eradication but also induce a systemic antitumour response, which is essential for the control of metastatic tumours and long-term tumour resistance. Photodynamic Therapy (PDT) is a current approach in the treatment of various cancers. It involves the administration of a tumour-localizing photoreactive compound, which is activated at a specific wavelength of light. This therapy results in a sequence of photochemical and photobiological processes that cause irreversible photodamage to tumour tissues. Eradication is achieved by anti-tumour effects induced in the parenchyma and tumour vascular network. PDT can lead to a rapid cell death response in malignant cells, which has provided insight into the mechanisms behind photokilling. Oesophageal cancer is the seventh leading cause of cancer death worldwide, and in South Africa remains a problem of epidemic proportions affecting predominantly black males. The appearance of a number of new photosensitizers being developed will not only extend the number of choices for treating specific cancers, but also aid in the effective destruction of various tumour tissues. PDT has been an experimental clinical modality for the past two xii decades and has been shown to be successful for the treatment of advanced oesophageal cancer where other options have failed. The full potential of PDT as a treatment modality has not been clearly evaluated, which is one of the objectives of this study. Overall, PDT has the potential of being a promising therapeutic option in the effective treatment of oesophageal cancer, and through this study and the elucidation of the mechanisms of PDT action, it will provide a better future for those suffering from oesophageal cancer. A new photosensitizer known as Zinc Sulphophthalo-cyanine (ZnPcSmix) was studied on an oesophageal SNO cancer cell line in order to determine treatment-induced cell viability, cytotoxicity and the pathway followed to cell death. The major observations of this study revealed that PDT using ZnPcSmix resulted in a decrease in cell viability and proliferation, resulting in a cytotoxic response experienced by the cell. The outcome of this study revealed that the SNO cells experience a necrotic mode of cell death after using ZnPcSmix to induce photodamage. This was examined by light microscopy and confirmed by the lack of DNA fragmentation and decreased caspase-3 and caspase-7 expression levels. Hsp70 levels decreased resulting in lowered cytokine TNF-α release from necrotic cells. Hoechst nuclear staining revealed a disorganized nuclear pattern characteristic of necrotic release of cellular contents. The major findings of this study revealed the efficacy of ZnPcSmix as a new photosensitizing drug used during PDT to treat oesophageal cancer resulting in a decrease in cell viability and proliferation. Necrosis was the primary mechanism by which cells pursued death, which was dependent on the photosensitizer dose, cell type and irradiation fluence. ZnPcSmix–induced photodamage seen during PDT offers a new treatment option for patients suffering from oesophageal cancer and shows great promise in effectively treating early-stage oesophageal cancer.
- Full Text:
- Authors: Yiannakis, Nicole
- Date: 2009-04-30T09:21:46Z
- Subjects: Photochemotherapy , Oesophagus , Cancer treatment , Cancer cells , Photosensitizing compounds
- Type: Thesis
- Identifier: uj:8319 , http://hdl.handle.net/10210/2447
- Description: M.Sc. , The ideal cancer treatment modality should not only cause tumour regression and eradication but also induce a systemic antitumour response, which is essential for the control of metastatic tumours and long-term tumour resistance. Photodynamic Therapy (PDT) is a current approach in the treatment of various cancers. It involves the administration of a tumour-localizing photoreactive compound, which is activated at a specific wavelength of light. This therapy results in a sequence of photochemical and photobiological processes that cause irreversible photodamage to tumour tissues. Eradication is achieved by anti-tumour effects induced in the parenchyma and tumour vascular network. PDT can lead to a rapid cell death response in malignant cells, which has provided insight into the mechanisms behind photokilling. Oesophageal cancer is the seventh leading cause of cancer death worldwide, and in South Africa remains a problem of epidemic proportions affecting predominantly black males. The appearance of a number of new photosensitizers being developed will not only extend the number of choices for treating specific cancers, but also aid in the effective destruction of various tumour tissues. PDT has been an experimental clinical modality for the past two xii decades and has been shown to be successful for the treatment of advanced oesophageal cancer where other options have failed. The full potential of PDT as a treatment modality has not been clearly evaluated, which is one of the objectives of this study. Overall, PDT has the potential of being a promising therapeutic option in the effective treatment of oesophageal cancer, and through this study and the elucidation of the mechanisms of PDT action, it will provide a better future for those suffering from oesophageal cancer. A new photosensitizer known as Zinc Sulphophthalo-cyanine (ZnPcSmix) was studied on an oesophageal SNO cancer cell line in order to determine treatment-induced cell viability, cytotoxicity and the pathway followed to cell death. The major observations of this study revealed that PDT using ZnPcSmix resulted in a decrease in cell viability and proliferation, resulting in a cytotoxic response experienced by the cell. The outcome of this study revealed that the SNO cells experience a necrotic mode of cell death after using ZnPcSmix to induce photodamage. This was examined by light microscopy and confirmed by the lack of DNA fragmentation and decreased caspase-3 and caspase-7 expression levels. Hsp70 levels decreased resulting in lowered cytokine TNF-α release from necrotic cells. Hoechst nuclear staining revealed a disorganized nuclear pattern characteristic of necrotic release of cellular contents. The major findings of this study revealed the efficacy of ZnPcSmix as a new photosensitizing drug used during PDT to treat oesophageal cancer resulting in a decrease in cell viability and proliferation. Necrosis was the primary mechanism by which cells pursued death, which was dependent on the photosensitizer dose, cell type and irradiation fluence. ZnPcSmix–induced photodamage seen during PDT offers a new treatment option for patients suffering from oesophageal cancer and shows great promise in effectively treating early-stage oesophageal cancer.
- Full Text:
Palladium, platinum and gold complexes: a synthetic approach towards the discovery of anticancer agents
- Authors: Keter, Frankline Kiplangat
- Date: 2010-03-10T06:28:55Z
- Subjects: Palladium compounds , Platinum compounds , Gold compounds , Complex compounds synthesis , Cancer treatment , Palladium - Therapeutic use , Gold - Therapeutic use , Platinum - Therapeutic use
- Type: Thesis
- Identifier: uj:6669 , http://hdl.handle.net/10210/3074
- Description: Ph.D. , Ligands bis(pyrazolyl)acetic acid (L1) and bis(3,5-dimethylpyrazolyl)acetic acid (L2) were synthesised by reacting pyrazoles and dibromoacetic acid under phase transfer conditions, by using benzyltriethylammonium chloride as the catalyst. Ligands L1 and L2 were characterised by a combination of 1H, 13C{1H} NMR, IR spectroscopy and microanalysis. Esterification of L1 and L2 led to formation of bis(pyrazolyl)ethyl acetate (L3) and bis(3,5-dimethylpyrazolyl)ethyl acetate (L4). Ligands L3 and L4 were also characterised by a combination of 1H, 13C{1H} NMR, IR spectroscopy and microanalysis. Subsequently, new pyrazolyl palladium(II) and platinum(II) compounds, [PdCl2(L1)] (1), [PdCl2(L2)] (2), [PtCl2(L1)] (3a) and [PtCl2(L2)] (4) were prepared by reacting bis(pyrazolyl)acetic acid ligands (L1-L2) with K2[PdCl4] or K2[PtCl4] respectively. The structures of complex 1 and 2 reveal distorted square planar geometries. The bond angles of N-Pd-N, N-Pd-Cl, N-Pd-Cl, for 1 and 2 are between 85.8(3)o and 90.81(4)o). The platinum compound, K2[Pt4Cl8(L1)2(deprotonated-L1)2].2H2O (3b), crystallised from aqueous solutions containing 3a when such solutions were left to stand overnight. Each platinum coordination environment consists of two cis-Cl ligands and one K2-N^N(L1) unit (L1 = bis(pyrazolyl)acetic acid), with two ligand moieties in 3b that are deprotonated with two K+ counter ions. Reaction of bis(pyrazolyl)acetic acid ligands (L1-L2) with [HAuCl4].4H2O gave gold(III) complexes [AuCl2(L1)]Cl (5a) and [AuCl2(L2)]Cl (6a). The spectroscopic, mass spectroscopy and microanalysis data were used to confirm the formation of the desired complexes. However, attempts to crystallise 5a and 6a led to formation of [AuCl2(pz)(pzH)] (5b) and [AuCl2(3,5-Me2pz)(3,5-Me2pzH)] (6b). This was confirmed by the structural characterisation of 5b, which has a distorted square-planar geometry. When complexes 1-6a were screened for their anti-tumour activity against CHO-22 cells, they showed no appreciable biological activities against CHO-22 cells. Substitution reactions of complexes 1-6a with L-cysteine performed to probe any relationship between the observed antitumour activities and the rates of ligand substitution of these complexes were inconclusive. Dithiocarbamate ligands L5-L8 were synthesised as potassium salts by introducing a CS2 group in positions 1 of pyrazole, 3,5-dimethylpyrazole, indazole and imidazole. The reaction of L5-L8 with [AuCl(PPh3)], [Au2Cl2(dppe)], [Au2Cl2(dppp)] and [Au2Cl2(dpph)], led to isolation of complexes [Au(L)(PPh3)] (13-16), [Au2(L)2(dppe)] (17a-19), [Au2(L)2(dppp)] (20-22) and [Au2(L)2(dpph)] (23-25) (dppe = bis(diphenylphosphino)ethane, dppp = bis(diphenylphosphino)propane, dpph = bis(diphenylphosphino)hexane; L = anions of L5-L8). The mononuclear molecular structure of 15 features a near linear geometry with a P(1)-Au(1)-S(1) angle of 175.36(2) o. The binuclear gold(I) complexes 20-22 and 23-25 have two P-Au-S moieties as evident in the solid state structure of 25. Attempts to crystallise complex 17a led to the formation of a gold(I) cluster complex [Au18S8(dppe)6]2+ (17b) as confirmed by X-ray crystallography. Cluster 17b features weak Au···Au interactions (2.9263(7)-3.1395(7) Å). Complexes 13-16 and 20-25 were tested in vitro for anticancer activity on HeLa cells. The activities of gold(I) complexes 13-16 were comparable to that of cisplatin. Dinuclear gold(I) complexes 20-25 also showed appreciable antitumour activity against HeLa cells. However, the dpph gold(I) compounds (23-25) were highly active, with 24 showing the highest activity against HeLa cells (IC50 = 0.1 μM). The tumour specificity (TS) factors for 23 and 24 were 31.0 and 70.5, respectively.
- Full Text:
- Authors: Keter, Frankline Kiplangat
- Date: 2010-03-10T06:28:55Z
- Subjects: Palladium compounds , Platinum compounds , Gold compounds , Complex compounds synthesis , Cancer treatment , Palladium - Therapeutic use , Gold - Therapeutic use , Platinum - Therapeutic use
- Type: Thesis
- Identifier: uj:6669 , http://hdl.handle.net/10210/3074
- Description: Ph.D. , Ligands bis(pyrazolyl)acetic acid (L1) and bis(3,5-dimethylpyrazolyl)acetic acid (L2) were synthesised by reacting pyrazoles and dibromoacetic acid under phase transfer conditions, by using benzyltriethylammonium chloride as the catalyst. Ligands L1 and L2 were characterised by a combination of 1H, 13C{1H} NMR, IR spectroscopy and microanalysis. Esterification of L1 and L2 led to formation of bis(pyrazolyl)ethyl acetate (L3) and bis(3,5-dimethylpyrazolyl)ethyl acetate (L4). Ligands L3 and L4 were also characterised by a combination of 1H, 13C{1H} NMR, IR spectroscopy and microanalysis. Subsequently, new pyrazolyl palladium(II) and platinum(II) compounds, [PdCl2(L1)] (1), [PdCl2(L2)] (2), [PtCl2(L1)] (3a) and [PtCl2(L2)] (4) were prepared by reacting bis(pyrazolyl)acetic acid ligands (L1-L2) with K2[PdCl4] or K2[PtCl4] respectively. The structures of complex 1 and 2 reveal distorted square planar geometries. The bond angles of N-Pd-N, N-Pd-Cl, N-Pd-Cl, for 1 and 2 are between 85.8(3)o and 90.81(4)o). The platinum compound, K2[Pt4Cl8(L1)2(deprotonated-L1)2].2H2O (3b), crystallised from aqueous solutions containing 3a when such solutions were left to stand overnight. Each platinum coordination environment consists of two cis-Cl ligands and one K2-N^N(L1) unit (L1 = bis(pyrazolyl)acetic acid), with two ligand moieties in 3b that are deprotonated with two K+ counter ions. Reaction of bis(pyrazolyl)acetic acid ligands (L1-L2) with [HAuCl4].4H2O gave gold(III) complexes [AuCl2(L1)]Cl (5a) and [AuCl2(L2)]Cl (6a). The spectroscopic, mass spectroscopy and microanalysis data were used to confirm the formation of the desired complexes. However, attempts to crystallise 5a and 6a led to formation of [AuCl2(pz)(pzH)] (5b) and [AuCl2(3,5-Me2pz)(3,5-Me2pzH)] (6b). This was confirmed by the structural characterisation of 5b, which has a distorted square-planar geometry. When complexes 1-6a were screened for their anti-tumour activity against CHO-22 cells, they showed no appreciable biological activities against CHO-22 cells. Substitution reactions of complexes 1-6a with L-cysteine performed to probe any relationship between the observed antitumour activities and the rates of ligand substitution of these complexes were inconclusive. Dithiocarbamate ligands L5-L8 were synthesised as potassium salts by introducing a CS2 group in positions 1 of pyrazole, 3,5-dimethylpyrazole, indazole and imidazole. The reaction of L5-L8 with [AuCl(PPh3)], [Au2Cl2(dppe)], [Au2Cl2(dppp)] and [Au2Cl2(dpph)], led to isolation of complexes [Au(L)(PPh3)] (13-16), [Au2(L)2(dppe)] (17a-19), [Au2(L)2(dppp)] (20-22) and [Au2(L)2(dpph)] (23-25) (dppe = bis(diphenylphosphino)ethane, dppp = bis(diphenylphosphino)propane, dpph = bis(diphenylphosphino)hexane; L = anions of L5-L8). The mononuclear molecular structure of 15 features a near linear geometry with a P(1)-Au(1)-S(1) angle of 175.36(2) o. The binuclear gold(I) complexes 20-22 and 23-25 have two P-Au-S moieties as evident in the solid state structure of 25. Attempts to crystallise complex 17a led to the formation of a gold(I) cluster complex [Au18S8(dppe)6]2+ (17b) as confirmed by X-ray crystallography. Cluster 17b features weak Au···Au interactions (2.9263(7)-3.1395(7) Å). Complexes 13-16 and 20-25 were tested in vitro for anticancer activity on HeLa cells. The activities of gold(I) complexes 13-16 were comparable to that of cisplatin. Dinuclear gold(I) complexes 20-25 also showed appreciable antitumour activity against HeLa cells. However, the dpph gold(I) compounds (23-25) were highly active, with 24 showing the highest activity against HeLa cells (IC50 = 0.1 μM). The tumour specificity (TS) factors for 23 and 24 were 31.0 and 70.5, respectively.
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