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  • TITLE
  • CERTIFICATE
  • DECLARATION
  • ACKNOWLEDGEMENT
  • CONTENTS
  • l. Introduction
  • Eryx conicus
  • Dryophis nasutus
  • Plate - I Fig.1 Eryx conicus; Fig 2. Dryophls; Fig.3. Dendrelaphis tristis
  • Dendrelaphis tristis
  • II. Materials and methods
  • Animals
  • Food-getting and feeding behaviour
  • Osteological elements
  • Quantitative analysis of the bony elements
  • Structure and disposition of muscles
  • TABLE 2: l: List of osteological characters
  • Quanatitative myology
  • The Force of Adduction
  • The Force of Abduction
  • Fig.2.1 Diagrammatic representation of the lever systems involving the opening and closing of the jaws. 2.1 (a) Adduction and abduction of the lower jaw. 2.1 (b) Protraction and retraction of the upper jaw and protraction of the lower jaw.
  • The Force of Protraction
  • The Force of Retraction
  • Morphological variables
  • Locomotor performance testing
  • Histochernical Observations
  • Fat
  • Glycogen
  • Lactic dehydrogenase (LDH)
  • Succinic dehydrogenase (SDH)
  • α - Glycerophosphate dehdrogenase (α GPDH)
  • Phosphorylase
  • ATPases
  • Acetyl Cholinesterase (AChE)
  • Fibre diameter and percent distribution
  • III. Food.getting and feeding behaviour
  • FIELD OBSERVATIONS
  • Table 3.1. The numerical percentage of prey items present in thestomach contents of Eryx conicus, Dryophis nasutus andDendrelaphis tristis.
  • TABLE 3.2. The volumetric percentage of prey items present in thestomach contents of Eryx conicus, Dryophis nasutus andDendrelaphis tristis.
  • TABLE: 3: 3 Index of Relative Importance values for prey item ofEryx conicus, Dryophis nasutus and Dendrelaphis tristis.
  • ANALYSIS OF STOMACH CONTENTS
  • IV. Osteology to the skull, vertebrae and the ligament associated
  • Cranium
  • Nasal and Orbital region.
  • Jaw apparatus
  • Eryx conicus
  • Fig. 4.1 Skull of Eryx conicus
  • Dryophis nasutus
  • Fig.4.2 Skull of Dryophis nasutus
  • Dendrelaphis tristis
  • Fig.4.3 Skull of Dendrelaphis tristis
  • Table 4.1. Measurements of osteological characters of Eryx conicus, Dryophis nasutus and Dendrelaphis tristis.
  • The ligaments associated with the skull
  • Vertebrae and ribs
  • Fig.4.4 (a) views of an intermediate vertebra of Eryx conicus, Dryophis nasutus, Dendrelaphis tristis
  • Fig.4.4 (d) Rib of Eryx conclus (d) Rib of Dryophis nasutus and Rib of Dendrelaphis tristis
  • V. Structure and disposition of the jaw-muscles and its operative efficiency
  • A. Structure and disposition
  • Jaw-muscles
  • I. Adductors of the lower jaw
  • Fig. 5.1 Jaw muscles of Eryx conicus
  • II. Abductors of the lower jaw
  • Fig.5.2 Jaw muscles of Dryophis nasutus
  • Ill. Protractors of the upper jaw
  • IV. Protractors of the lower jaw and retractors of the upper jaw
  • Fig.5.3 Jaw muscles of Dendrelaphis tristis
  • V. Retractors of the upper jaw
  • Hyoid and Tongue-muscles
  • Opperative efficiency of the feeding apparatus
  • Lever systems of the feeding apparatus
  • Quantitative myology
  • TABLE 5.1: EFFECTIVE FORCE OF ADDUCTION BY THE M. ADDUCTOR MANDIBULAE EXTERNUS SUPERFICIALIS
  • TABLE 5.2: EFFECTIVE FORCE OF ADDUCTION BY THE M.ADDUCTOR MANDIBULAE EXTERNUS MEDIALIS
  • TABLE 5.3: EFFECTIVE FORCE OF ADDUCTION BY THE M. ADDUCTOR MANDIBULAE EXTERNUS PROFUNDUS
  • TABLE 5.4: EFFECTIVE FORCE OF ADDUCTION BY THE M.ADDUCTOR MANDIBULAE POSTERIOR
  • TABLE 5.5: EFFECTIVE FORCE OF ADDUCTION BY THEM.PSEUDOTEMPORALIS
  • TABLE 5.6: EFFECTIVE FORCE OF ABDUCTION BY THE M. DEPRESSOR MANDIBULAE ANTERIOR
  • TABLE 5.7: EFFECTIVE FORCE OF ABDUCTION BY THE M. DEPRESSOR MANDIBULAE POSTERIOR
  • TABLE 5.8: EFFECTIVE FORCE OF PROTRACTION (UPPER JAW) BY THE M.PROTARACTOR PTERYGOIDEI
  • TABLE 5.9: EFFECTIVE FORCE OF PROTRACTION (UPPER JAW) BY THEM. LEVATOR PTERYGOlDEl
  • TABLE 5.10: EFFECTIVE FORCE OF PROTRACTION (UPPER JAW) BYTHE M.PROTRACTOR QUADRAT1
  • TABLE 5.11: EFFECTIVE FORCE OF PROTRACTION (LOWER JAW) BYTHE M.PTERYGOIDEUS
  • TABLE 5.12: EFFECTIVE FORCE OF PROTRACTION (LOWER JAW) BYTHE M.PTERYGOIDEUS ACCESSORIES
  • TABLE 5.13: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) BY THEM.PTERYGOIDEUS
  • TABLE 5.14: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) BY THEM.PTERYGOIDEUS ACCESSORIES.
  • TABLE 5.15: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) BY THEM.RETRACTOR PTERYGOIDEI
  • TABLE 5.16: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) BY THEM.RETRACTOR VOMERIS
  • TABLE 5.17: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) BY THEM.CERVIC0-MANDIBULARIS
  • TABLE 5.18: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) BY THEM.NEUR0 - MANDIBULARIS
  • TABLE 5.19: EFFECTIVE FORCE OF ABDUCTION PER GRAM WEIGHTOF MUSCLE
  • TABLE 5.20: EFFECTIVE FORCE OF ADDUCTION PER GRAM WEIGHTOF MUSCLE
  • TABLE 5.21: EFFECTIVE FORCE OF PROTRACTION (UPPER JAW) PERGRAM WEIGHT OF MUSCLE
  • TABLE 5.22: EFFECTIVE FORCE OF PROTRACTION (LOWER JAW) PERGRAM WEIGHT OF MUSCLE
  • TABLE 5.23: EFFECTIVE FORCE OF RETRACTION (UPPER JAW) PERGRAM WEIGHT OF MUSCLE
  • TABLE 5.24: INDICES TO THE EFFECTIVE FORCES OF THE FUNCTIONALGROUPS OF MUSCLES PER GRAM WEIGHT OF MUSCLE
  • VI. Structure and disposition of the locomotory muscles
  • M. spinalis
  • M.semispinalis
  • M.longissirnus dorsi
  • M.multifidus
  • Fig. 6.1 Locomorory muscles of Eryx Conicus
  • M.interarticularis superior
  • M.interarticularis inferior
  • M.intervertebralis
  • M.retractor costae biceps
  • Fig. 6.2 Locomotory muscles of Dryophis nasutus
  • M.levator costae
  • M.tuberculocostalis
  • M.transversus dorsalis
  • M.costalis internus superior
  • Fig.6.3 Locomotort muscles of Dendrelaphis tristis
  • M.costalis internus inferior
  • M.costovertebrocostalis
  • M.intercostalis proprius
  • M.rectus abdominis
  • M.transversus abdominis
  • M.supracostalis dorsalis
  • M.costocutaneous superior
  • M. costocutaneous inferior
  • Muscle length and snout vent length ratio
  • TABLE VI. I. Length of muscle (ML) and snout vent length (SVL) percentage of Eryx conicus, Dryophis nasutus andDendrelaphis tristis.
  • VII. Locomotory performance and morphological variables
  • Morphological variables
  • Table 7.1 MORPHOLOGICAL VARIABLES OF ERYX CONICUS (Ec) DRYOPHIS NASUTUS (Dn) AND DENDRELAPHIS TRlSTlS (Dt)
  • Table 7.2. SKIN THICKNESS OF ERYX CONICUSDRYOPHIS NASUTUS AND DENDRELAPHIS TRlSTlS (in rnm)
  • Table 7.3. WEIGHT OF LONGITUDINAL STRIPS OF SKIN (10 x70 mrn) OFERYX CONICUS. DRYOPHIS NASUTUS AND DENDRELAPHIS TRlSTlS (in grn)
  • Table 7.4. DIMENSIONS OF SCALES OF ERYX CONICUSDRYOPHIS NASUTUS AND DENDRELAPHIS TRlSTlS (in mm)
  • Locomotor Performance
  • Table 7.5. LOCOMOTOR PERFORMANCE OF ERYX CONICUS DRYOPHlSNASUTUS & DENDRELAPHIS TRlSTlS
  • ANOVA OF TABLE 7.5
  • VIII. Histochemical studies on the metabolites some related enzymes and neuromuscular junctions of the jaw and locomotory muscles
  • A. Histochemical studies on the metabolities, some related enzymes and neuromuscular junctions of the jaw-muscles
  • Glycogen
  • TABLE 8A.1. The percentage distribution of glycogen in the jaw-muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.1
  • Fat
  • TABLE 8A.2. The percentage distribution of FAT in the Jaw-muscles of Eryxconicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.2
  • Succinic dehydrogenase (SDH)
  • TABLE 8B.3. (a) The percentage distribution of fibre types in the locomotory muscles of Eryx conicus.
  • TABLE 8A.3. (b) The percentage distribution of fibre types in the jaw muscles of Dryophis nasutus
  • TABLE 8A.3. (c) The percentage distribution of fibre types in the Jawmuscles of Dendrelaphis tristis.
  • Phosphorylase
  • TABLE 8A.4. The percentage distribution of phosphorylase in thejaw-muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.4.
  • Lactic dehydrogenase (LDH)
  • TABLE 8A.5. The percentage distribution of LDH in the jaw-muscles of Elyxconicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.5
  • α-Glycerphosphate dehydrogenase (αGPDH)
  • TABLE 8A.6. The percentage distribution of ClGPDH in the Jaw-muscles ofEryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.6.
  • ATP ase
  • TABLE 8A.7. The percentage distribution of ATPase (acid-stabile) in theJaw-muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.7
  • ATP ase
  • TABLE 8A.8. The percentage distribution of ATPase (alkali-stabile) in theJaw-muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8A.8.
  • Acetylcholinestrase (AChE)
  • TABLE 8A. 9. The distance between the neurornuscular junctions (in p) of thejaw - muscles of Eryx conicus, Dryophis nasufus and Dendrelaphis tristis.
  • TABLE 8A.lO. (a) The fibre diameter (in kt) of the jaw-muscles ofEryx conicus
  • TABLE B.A.lO. (b) The fibre diameter (in p) of the jaw-muscles ofDryophis nasutus
  • TABLE 8A.l0. (c) The fibre diameter (in p) of the jaw-muscles ofDendrelaphis tristis
  • Dimensions of fibre types
  • Glycogen
  • TABLE 8B.1. The percentage distribution of Glycogen in the locomotorymuscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendralephis tristis (Dt)
  • ANOVA OF TABLE 8B.1
  • Fat
  • TABLE 8B.2. The percentage distribution of FAT in the locornotory musclesof Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8B.2
  • Succinic dehydrogenase (SDH)
  • TABLE 8B.3 (a) The percentage distribution of tibre types in theiocomotory muscles of Eryx conicus.
  • TABLE 8B.3. (b) The percentage distribution of fibre types in thelocomotory muscles of Dryophis nasutus.
  • TABLE 8B.3. (C) The percentage distribution of fibre types in thelocornotory muscles of - Dendrelaphis tristis
  • Phosphorylase
  • TABLE 8B.4. The percentage distribution of phosphorylase in thelocomotory muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8B.4
  • Lactic dehydrogenase (LDH)
  • α Glycerphosphate dehydrogenase (αGPDH)
  • TABLE 8B.5. The percentage distribution of LDH in the locomotory musclesof Eryx conicus (Ec) Dryophis nosutus (Dn) and Dendrelophis tristis (Dt)
  • ANOVA OF TABLE 8B.5
  • TABLE 8B.6. The percentage distribution of aGPDH in the locomotorymuscles of Eryx conicus (Ec) Dryophis nasutus (Dn) andDendrelaphis trisfis (Of)
  • ANOVA OF TABLE 8B.6
  • TABLE 8B.7. The percentage distribution of ATP ase (acid-stabile) in the locomotory muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) and Dendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8B.7
  • TABLE 8B.8. The percentage distribution of ATP ase (alkali stabile) In thelocornotory muscles of Eryx conicus (Ec) Dryophis nasutus (Dn) andDendrelaphis tristis (Dt)
  • ANOVA OF TABLE 8B.8
  • ATPase (alkali-stabile)
  • Acetyl-cholinestrase. AChE
  • TABLE 8B. 9. The distance between the neuromusculor junctions (in 11) of the locomotory muscles of Eryx conicus, Dryophis nasutus and - Dendrelaphis tristis.
  • Dimensions of fibre types
  • TABLE 8B.10. (a) The fibre diameter (in μ) of the locomotorymuscles of Eryx conicus.
  • TABLE 8.B.10. (b) The fibre diameter (in μ) of the locomotory muscles of Dryophis nasutus.
  • TABLE 8B.10. (c) The fibre diameter (in μ) of the locomotory muscles Dendrelaphis tristis.
  • TABLE 8.11 (a) Correlation matrix (Pearsons r) of speed with glycogen, fat, SDH, phosphorylase, LDH, α GPDH and ATP ase (acid and alkalistabile) of the locornotory muscles of Eryx conicus
  • TABLE 8B. 11 (b) Correlation rnatirx (Pearsons r) of speed with glycogen, fat, SDH, phyosphorylase, LDH, α GPDH and ATPase (acid and alkalistabile) of the locornotory muscles of Dryophis nasutus.
  • TABLE II (c) Correlation matrix (Pearsons r) of speed with glycogen, fat, SDH, phosphorylase, LDH, α GPDH and ATPase (acid and alkali stabile) ofthe locomotory muscles of Dendrelaphis tristis.
  • PLATE -II T. S. of the jaw and locomotory muscles of Eryx conicus stained for glycogen.
  • PLATE - III T. S. of the jaw and locomotory muscles of Dryophis nasutus stained for glycogen.
  • PLATE -IV T.S. of the jaw and locomotory muscles of Dendrelaphis tristis stained for glycogen.
  • PLATE -V T. S. of the jaw and locomotory muscles of Eryx conicus stained for fat.The jaw-muscles.
  • PLATE VI T.S. of the jaw and locomotory muscles of Dryophis nasutus stained for fat.
  • PLATE -VII T. S. of the jaw and locomotory muscles of Dendrelaphis tristis stained for fat
  • PLATE - VIII T. S. of the jaw and locomotory muscles of Eryx conicus stained for SDH activity
  • PLATE - IX T. S. of the jaw and locornotory muscles of Dryophis nasutus stained for SDH activity.
  • PLATE - X T. S. of the jaw and locomotory muscles of Dendrelaphis tristis stained for SDH activity.
  • PLATE - XI T. S. of the jaw and locomotory muscles of Eryx conicus stained for phosphorylase
  • PLATE - XII T.S. of the jaw and locomotory muscles of Dryophis nasutus stained phosphorylase
  • PLATE -XIII T. S. of the jaw and locomotory muscles of Dendrelaphis tristis stained for phosphorylase
  • PLATE -XIV T. S. of the jaw and locomotory muscles of Eryx conicus stained for LDH
  • PLATE -XV T.S. of the jaw and locomotory muscles of Dryophis nasutus stained for LDH
  • PLATE - XVI T.S. of the jaw and locomotery muscles of Dendrelaphis tristis stained for LDH
  • PLATE - XVII T.S. of the jaw and locomotory muscles of Eryx conicus stained for α GPDH
  • PLATE - XVIII T.S. of the jaw and locornotory muscles of Dryophis nasutus stained for αGPDH
  • PLATE - XIX T.S. of the jaw and locomotory muscles of Denderlaphis tristis stained for αGPDH
  • PLATE - XX T.S. of the jaw and locomotory muscles of Eryx conicus stained for acid - stablile ATP ase.
  • PLATE - XXI T.S. of the jaw and locomotory muscles of Dryophis nasutus stainedfor acid - stabile ATP ase.
  • PLATE - XXII T.S. of the jaw and locomotory muscles of Dendrelaphis tristis stained for acid - stabile ATP ase.
  • PLATE - XXIII T.S. of the jaw and locomotory muscles of Eryx conicus stained for alkaline - stabile ATP ase.
  • PLATE - XXIV T.S. of the jaw and locomotory muscles of Dryophis nasutus stained for alkali - stabile ATP ase
  • PLATE - XXV T.S. of the jaw and locomotory muscles of Dendrelaphis tristis stained for alkali - stable ATP ase.
  • PLATE - XXVI The jaw and locomotory muscles of Eryx conicus showing the localization of AChE at the neuromuscular junctions.
  • PLATE - XXVII The jaw and locomotory muscles of Dryophis nasutus showing the localization of AChEaat the neurornuscular junctions.
  • PLATE - XXVIII The jaw and locomotery muscles of Dendrephis tristis showing the localization of AChE at the neuro muscular junctions.
  • IX. Discussion
  • Food-getting and feeding behaviour
  • Osteology of the skull and the ligaments associated
  • Ligaments of the skull
  • The Body vertebrae
  • Muscles of the feeding apparatus and its operative efficiency
  • Hyoid-muscles and tongue-muscles
  • Operative efficiency
  • STRUCTURE AND DISPOSITION OF THELOCOMOTORY MUSCLES
  • Locomotor performance and morphological variables
  • Histochemical studies on the metabolites, some relatedenzymes and neuromuscular junctions of the locomotorymuscles
  • X Summary and conclusions
  • Works cited