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Full Screen- Title
- DECLARATION
- CERTIFICATE
- ACKNOWLEDGEMENT
- CONTENTS
- ABBREVIATIONS
- 1. Introduction and review of literature
- INTRODUCTION
- REVIEW OF LITERATURE
- I. Molecular biology of cancer
- A. Genes and Cancer
- 1. Proto-oncogenes
- 2. Tumor suppressor genes
- 3. Repair genes
- 4. Chromosomal aberrations
- B. Cancer and cell growth regulatory pathways
- 1. Growth factors (GPs)
- 2. Cell cycle check points.
- II. Etiology of Cancer
- A. Carcinogenesis
- 1) Physical insults (Radiation)
- a) Ultraviolet radiation
- b) Ionizing Radiation
- 2) Biological insults (Viral carcinogenesis)
- 3) Chemical insults (Chemical carcinogenesis)
- a) Organic carcinogens
- i) Alkylating agents
- ii) Aralkylating agents
- iii) Arylhydroxylamines
- b) Inorganic compounds
- (i) Tumor initiation
- ii) Tumor promotion
- iii) Tumor progression
- III. Free radicals, Antioxidants and Cancer
- IV. Cancer Therapy
- a) Surgery
- b) Radiation Therapy
- c) Chemotherapy
- Chemotherapeutic agents
- 1) Non-plant derived anticancer agents
- a) Alkylating agents
- b) Antimetabolites
- c) Antitumor antibiotics
- d) Enzymes
- f) Cisplatin
- g) Procarbazine
- h) Hydroxyurea
- i) Amsacrine
- 2) Plant Derived Anticancer Agents
- 1. Vinca alkaloids
- 2. Homoharringonin (BHT)
- 3. Podophyllotoxins
- 4. Maytansine
- 5. Taxanes
- 6. Camptothecin
- V. Production of anti-cancer secondary metabolites through tissue culture
- 2. Materials and methods
- 2.1. Materials
- 2.1.1. Plant Materials
- 2.1.2. Chemicals
- 2.1.3. Instruments
- 2.1.4. Cell lines
- 2.1.5. Animals
- 2.2. Methods
- 2.2.1. Explants and surface sterilization
- 2.2.2. Preparation of nutrient media
- 2.2.3. Culture Environment
- 2.2.4. Culture initiation and callus culture establishment
- 2.2.5. Callus growth measurement
- 2.2.6. Preparation of the plant extract
- 2.2.7. Preparation of the callus extracts
- 2.2.8 Preparation and application of spray reagents
- 2.2.9. Extraction of crude camptothecin (CPT)
- 2.2.10. Isolation of CPT
- 2.2.11. Crystallization of CPT
- 2.2.12. TLC analysis
- 2.2.13. Melting point
- 2.2.14. UV-visible absorption spectra
- 2.2.15. IR-spectra
- 2.2.16. High performance liquid chromatography (HPLC)
- 2.2.17. Electron Spray Mass Spectrometry (ESMS)
- 2.2.18. H-nuclear magnetic resonance
- 2.2.19. Maintenance of Experimental animals
- 2.2.20. Maintenance of tumour cells in mice
- 2.2.21. Maintenance of cell lines in tissue culture
- 2.3. Anti tumor studies
- 2.3.1 Short term in vitro cytotoxocity
- 2.3.2 Long term chemosensitivity
- 2.3.3 MTT assay
- 2.3.4 3H-thymidine incorporation assay
- 2.3.5 Ascites tumor model
- 2.3.6 Solid tumor model
- 2.4 Antioxidant property in vitro
- 2.4.1 Superoxide scavenging activity
- 2.4.2 Hydroxyl radical scavenging activity
- 2.4.3 Lipid peroxide inhibition activity
- 2.4.4 Anti-inflammatory activity
- 2.4.5 Evaluation of anti carcinogenic activity of the extracts
- 2.4.6. Histopathology
- 2.5. Statistical analysis
- 3. Isolation and quantification of camptothecin from.Nothapodytes foetida
- 3.1 Introduction
- 3.2 Materials and methods
- 3.2.1 Plant material
- 3.2.2 Preparation of the extract
- Fig: 3.1. Nothapodyes foetida (White) Slummer.
- 3.2.3 Crystallization of CPT
- 3.2.4 Determination of CPT melting point
- 3.2.5 uv-visible spectrum
- 3.2.6 HPLC analysis and quantification
- 3.3 Results and discussion
- Fig 3.2 Schematic representation tor the isolation of CPT from plantparts of Nothapodytes foetida
- 4. Camptothecin from callus cultures of Nothapodytes foetida
- 4.1 Introduction
- 4.2 Materials and methods
- 4.2.1 Explants
- 4.2.2 Surface sterilization
- 4.2.3 Callus subculture
- 4.2.4 Callus growth measurement
- 4.2.5 Extraction of CPT and HPLC analysis
- 4.2.6 Purification and characterization of CPT
- Fig 4.1 Camptothecin extraction from callus
- 4.2.7 Long term Cytotoxicity of the isolated CPT
- 4.3 Results
- 4.3.1 Callus induction and callus growth
- Fig 4.2
- (A) An Immature embryo of N.foietida
- (B) 90 day old callus shows leafy out growth in the modified MS medium supplemented with NAA 2mg/I and KN 0.5 mg/I
- (C, D, E) Plantlets grown in the MS medium supplemented with NAA 2 mg/I and BA 0.5 mg/I
- 4.3.2 Thin layer chromatography
- 4.3.3 uv absorption
- 4.3.4 HPLC analysis
- 4.3.5 IR spectra of purified CPT
- 4.3.6 Mass spectra
- 4.3.7 H-NMR NMR spectra
- 4.3.8 Cytotoxicity
- 4.4 Discussion
- 5. Camptothecin from tissue cultures of Ervatamia heyneana
- 5.1 Introduction
- 5.2 Materials and Methods
- 5.2.1 Plants
- 5.2.2 Surface sterilization of the explant and culture
- 5.2.3 Callus growth measurement
- 5.2.4 Callus subculture
- 5.2.5 Callus extract preparation
- 5.2.6 Determination of chemosensitivity of the extract on L929 cells
- 5.2.7 Anti-tumor activity of iu vitro derived root extract
- 5.2.8 TLC analysis
- 5.2.9 uv visible absorption spectra
- 5.2.10 HPLC analysis
- 5.3 Results
- 5.3.1 Surface sterilization
- 5.3.2 Culture initiation
- 5.3.3 Influence of auxins
- 5.3.4 Influence of auxins and cytokinins
- Fig: 5.1 Ervatamia heyneana (Wall) Cook
- Fig 5.2
- (A) Internode-derived callus in MS medium containing 2, 4-D2 mg/l and KN 0.5 mg/l.
- (B) Rhizogenesis in seed embryo cultured in MS medium Supplemented with NAA 4 mg/l and KN 0.5m g/l
- (C) Plantlets in seed internode callus cultured tn NAA 2mg/l and BA 0.5 mg/l
- (D) Plantlets and rhizognesis in MS medium supplemented with NAA 2mg/l and BA 0.5 mg/l
- (E) Rhizognesis in seed embryo cultured in MS liquid medium Supplemented with NAA 4mg/l and KN 0.5 mg/I
- (F) Somatic embryoids in seed embryo cultured in MS medium containing 2, 4-D 3 mg/l and KN 0.5 mg/l
- Fig 5.3 Leaf disc explant after 30 dav culture in MS medium supplemented with 2, 4-D 2mg/I & BN 0.5 mg/I
- 5.3.5 Callus growth
- 5.3.6 Anticancer activity of the extracts on L929 cells
- 5.3.7 in vivo anti-tumor propeq of the extract
- 5.3.8 TLC analysis
- 5.3.9 uv-visible absorption spectra
- 5.3.10 HPLC analysis
- 5.4 Discussion
- 6. Study on antioxidant and anticancer activity of Emilia sonchifolia
- 6.1 Introduction
- 6.2 Materials and methods
- 6.2.1 Preparation of crude extract from plant
- 6.2.3 Animals
- 6.2.4 Superoxide scavenging activity
- 6.2.5 Hydroxyl radical scavenging activity
- 6.2.6 Anti-inflammatory activity
- 6.2.7 In vitro cytotoxicity of the extract
- 6.2.8 Effect of methanollic extract on ascites tumor in mice
- 6.2.9 Effect of methanolic extract on solid tumor development
- 6.2.10 Effect of methanolic extract on DNA synthesis
- 6.2.11 Partial purification of E.sonchifolia extract by XAD amberlite column
- 6.2.12 Phytochemical analysis of the active fraction
- 6.2.13 uv visible absorption of the active fraction
- 6.3 Results
- 6.3.1 Antioxidant and anti-inflammatory activity of the methanolic extract of E. sonchifolia
- 6.3.2 Cytotoxic and antitumor property
- 6.3.3 Effect of methanolic extract on DNA synthesis
- 6.3.4 Antioxidant and anticarcinogenic activity of partially purified extract
- 6.4 Discussion
- 7. In vitro antioxidant and cytotoxic Properties of Callus and plantlet cultures of Emilia sonchifolia
- 7.1 Introduction
- 7.2 Materials and methods
- 7.2.1 Surface sterilization and culture medium
- 7.2.2 Callus culture
- 7.2.3 Rooting of regenerated shoots
- 7.2.4 Establishment of regenerated plantlets
- 7.2.5 Preparation of the extracts
- 7.3 Antioxidant property
- 7.3.1 Superoxide scavenging activity
- 7.3.2 Hydroxyl radical scavenging activity
- 7.3.3 Lipid peroxidation inhibition
- 7.4 In vitro cytotoxicity of the extracts.
- 7.5 TLC analysis of the extracts
- 7.6 Results
- Fig 7.1 Shoot multiplication in E.sonchifolia cultured in MS medium supplemented with IAA 2 mg/l and BA mg/l
- Fig 7.2 Leaf disc derived callus in MS medium supplemented with 2, 4-D 2 mg/l and KN 0.5 mg/l
- DISCUSSION
- 8. Summary and Conclusion
- APPENDIX
- References
- Papers published