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382 DESIGN IN NATURE Evolution, as indicated, is naturally divided into an ancient and modern form, and comes into operation when- ever an attempt is made to obtain complex substances or beings from simple substances by an immeasurable series of slight modifications said to extend over practically unlimited periods. The ancient and modern theories of evolution are both faulty, and fail us at the most critical point, namely, where the simple substance is said to be converted into the complex one, and where differentiation is held first to make its appearance. There are two phases of development with which the ancient and modern doctrines of evolution are altogether inadequate to deal. They have completely failed to explain the existence of type and the persistence of type. Neither can they account for the general plan and design which everywhere obtain in nature. Those who are opposed to evolution in all its forms not unnaturally inquire. How can plants and animals which vary to quite an extraordinary extent in ultimate composition be produced from an ovum which is, in all its parts and particles, homogeneous and simple, that is, undifferentiated ? They say, and say truly, that complex plants and animals can only be produced from compound, heterogeneous substances ; in other words, from substances which are them- selves directly or indirectly multiple. The compound matter, according to them, is necessary to the production of the compound plant and animal at the outset, and at every stage of its career. The only question which now remains is as to whether the ovum is a microcosm, that is, a miniature structure where all the parts composing it are present at one and the same time ; or a conglomerate, consisting of many parts where only certain of them are in evidence at any particular period ; these forming the foundations and scaffolding for the others, which appear in succession at intervals in a given order, until the compound plant or animal is produced. In the one case, the plant and the animal are the outcome of one continuous set of changes or developments ; in the other, of several sets of consecutive changes or developments. According to the supporters of evolution in its most ancient and widest sense there is one long continuous act of development ; simple matter having impressed upon it at the outset certain tendencies which inevitably result in differentiation in a particular direction, and which finally produce the perfected plant and animal. Otherwise stated, the original ovum has in itself certain potentiahties which it has no power to resist, and which act in specific directions in the production of plants and animals according to types. Evolutionists seek to explain types for the most part by chance, and as apart from a First Cause, a pre-arranged plan, and design. To all such views, if the Deity be excluded, I am wholly opposed. These opinions are further discussed in other parts of the work, and the illustrations connected with them have an interest all their own, and should be carefully examined and studied. PLATE LXXXVI Plate Ixxxvi. shows various kinds of ova and the changes occurring in them before and after impregnation. Ovarian ovum of a mammal (A, B, C). A. Entire ovum seen under pressure, a, Zona pellucida or radiata ; h, yolk substance and protoplasm ; c, germinal vesicle witli germinal spot. B. a, Zona pellucida burst by pressure ; h, yolk substance and protoplasm escaped ; 1;, germinal vesicle set free. C. Germinal vesicle with thin coating of yolk substance (after Allan Thomson). D. Ovum of cat greatly magnified and semi-diagrammatic, a, Zona pellucida or radiata showing radiated structure ; b, yolk or vitellus invested with delicate membrane ; c, germinal vesicle ; d, germinal spot (after E. A. SchJifer). E. Diagram of a holoblastic (alecithal) ovum, h, c, Germinal vesicle and germinal speck. P. Ditto of a meroblastic (telolecithal) ovum. In these figures the nutritive part of the yolk appears as clear globules (6). At F, it is seen in excess unless in vicinity of germinal vesicle (c), where the protoplasm abounds (after E. A. Schafer). G. Ovum of rabbit from Fallopian tube twelve hours after impregnation. Shows formation of polar globules, a, Zona pellucida with spermatozoa (male elements) ; h, vitellus or yolk ; c, perivitelline space with spermatozoa : d, polar globules extruded from vitellus (after Bischoflf). H. Formation of first polar globule in egg of Ascaris megahceplwla. a, Zona pellucida; /(, yolk substance and protoplasm • f, germinal vesicle converted into spindle of achromatic fibrils with fibrils radiating into the protoplasm ; d, eight portions of chromatin ; e, head of spermatozoon becoming male pronucleus. I. Shows the eight chromatin particles separated into two sets, a, Zona pellucida ; h, yolk and protoplasm considerably shrunken ; d, the two sets of chromatin particles. J. Shows separation and extrusion into perivitelline space of halt of germinal vesicle (four outer chromatin particles) with portion of protoplasm to form polar globule, a, Zona pellucida ; h, yolk protoplasm ; d, half of germinal vesicle with four chromatic particles extruded into perivitelline space ; e, line of division (V. Genuchten). K. Formation of second polar globule in Ascaria meijalocephala. a, Zona pellucida; h, yolk substance and protoplasm- c position occupied by extruded first polar globule ; d, spindle of achromatic fibrils with four chromatin particles at equator formed by remaining half of germinal vesicle. L. a, Zona pellucida r, first ; polar globule d, ; y-shaped spindle of fibrils with chromatin particles approaching surface of ovum ; e, male pronucleus formed from spermatozoon. M. Extrusion of remaining half of germinal vesicle commenced, a, Zona pellucida ; c, first polar globule ; 7, partial extrusion of second polar globule.
FERTILISATION OF THE OVUM PLATE LXXXVI M N R S PLATE LXXXVI (continued) N, Separation of second polar globule (i), with two chromatin particles from the ovum ; the other two with remains of germinal vesicle (d) forming the female pronucleus ; e, male pronucleus ; c, first polar globule (Carnoy). 0. Fertilisation of the ovum of an echinoderm. u, Zona pellucida; h, spermatozoon perforating vitelline membrane; c, protoplasm of vitellus. P. a, Zona pellucida ; ft, entrance of spermatozoon into protoplasm of vitellus (c), with radiating and concentric arrangement of its granules. Q. a, Zona pellucida ; 6, head of spermatozoon enlarging to form male pronucleus ; d, female pronucleus. The radiating and concentric arrangement of protoplasmic yolk granules is well marked in this figure. R, S. Blending of the male (b, b) and female (d, d) pronuclei (Selenka). PLATE LXXXVII Plate Ixxxvii. illustrates different stages of karyokinesis in the epithelium cells of the larva of the salamander. These cells are hardened in chromic acid and stained with hajmatoxyhn. Highly magnified (Flemming). A. Resting cell, displaying the nuclear network. B. First stage of division, the chromoplasm being converted into a skein of closely contorted filaments. 0. Second stage of division, filaments increased in size and less closely arranged. (In this and all the other figures, Fig. A excepted, the nuclear matrix is clear.) D. Filaments slightly more magnified than in the other figures ; these showing a looped arrangement, better seen at E, where they are rosette-shaped and enclose a central clear space. F. Filaments converging towards the centre. G. Stellate phase or aster. H. Completion of longitudinal splitting already begun at P and G. 1. Filaments beginning to separate into two groups (metakinesis). J. Further separation into two sets. K. Separation further advanced. L. Stellate phase of daughter nuclei (diaster). M. Commencing convolution of filaments. N. Filaments more contorted. 0, P. Gradual passage of daughter nuclei into condition of rest as seen at network Q. Note.—The division of the protoplasm begins at the stage (M) and is rapidly completed at (N). Q 383
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A..2^ BOUGHT WITH THE INCOME FROM T
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Tracing from nature of a mesial lin
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TABLE OF CONTENTS VOLUME ONE PREFAC
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§ 36. The Travelling Organs in Rel
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CONTENTS xi Rhythmic Movements—An
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CONTENTS xiii THE MOVEMENTS AND FUN
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§§ . CONTENTS XV INTELLIGENCE OF
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CONTENTS xvii THE OSSEOUS AND MUSCU
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§ 420. The Flight of Birds divisib
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PREFACE The present work has attain
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INTRODUCTION The present work natur
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INTRODUCTION xxv cules being so arr
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INTRODUCTION xxvii is the ancient w
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INTRODUCTION xxix ments met with in
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INTRODUCTION xxxi organisms there i
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DESIGN IN NATURE INORGANIC AND ORGA
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STRAIGHT-LINE AND OTHER FORMATIONS
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ARRANGEMENTS COMMON TO CRYSTALS, PL
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PREVALENCE OF SPIRAL ARRANGEMENTS 1
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PREVALENCE OF SPIRAL ARRANGEMENTS P
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PREVALENCE OF SPIRAL ARRANGEMENTS P
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VOL. I PREVALENCE OF SPIRAL ARRANGE
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ORIGIN OF SPIRAL STRUCTURES 19 and
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SPIRAL ARRANGEMENTS IN PLANTS 21 |3
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SPIRAL ARRANGEMENTS IN PLANTS 23 PL
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SPIRAL ARRANGEMENTS IN PLANTS PLATE
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Fig. 3. SPIRAL ARR'ANGEMENTS IN ANI
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SPIRAL ARRANGEMENTS IN ANIMALS 29 P
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SPIRAL ARRANGEMENTS IN ANIMALS PLAT
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SPIRAL ARRANGEMENTS IN ANIMALS 33 P
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SPIRAL ARRANGEMENTS IN ANIMALS Fir.
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CBERJtAU, SPIRAL ARRANGEMENTS IN AN
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RADIATING AND CONCENTRIC ARRANGEMEN
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1''IG. 1. RADIATING AND CONCENTRIC
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§ 9. Dendritic or Branching Moveme
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VOL. I, DENDRITIC OR BRANCHING ARRA
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DENDRITIC OR BRANCHING ARRANGEMENTS
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VOL. I. DENDRITIC OR BRANCHING ARRA
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BRANCHING AND RADIATING ARRANGEMENT
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BRANCHING AND RADIATING ARRANGEMENT
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HEXAGONAL STRUCTURES AND SEGMENTATI
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HEXAGONAL STRUCTURES 65 Fig. 20.—
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CLEAVAGE AND SEGMENTATION 67 PLATE
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LONGITUDINAL AND TRANSVERSE CLEAVAG
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CONVOLUTIONS IN HARD AND SOFT PARTS
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RADIATING AND BRANCHING ARRANGEMENT
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LONGITUDINAL AND TRANSVERSE CLEAVAG
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LONGITUDINAL, RADIATING, AND TRANSV
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VOL. I. LONGITUDINAL AND RADIATING
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TRAVELLING ORGANS FOR LAND, WATER,
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j^-«i Fig, S. FiG. Fig. 10. FIGURE
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vol.. I, RECAPITULATION 89 PLATE LI
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RECAPITULATION 91 The same thing, w
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ATOMS AND MOLECULES 93 some anthrop
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CONSERVATION OF ENERGY 95 secretion
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THE REPRODUCTIVE ELEMENTS OF PLANTS
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SPIRAL STRUCTURES AND MOVEMENTS IN
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ATOMS AND MOLECULES IN DEAD AND LIV
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UNITY OF PLAN IN NATURE 103 arrange
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force is so feeble that the chain o
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FIG. nG.4 FIG. 5 m^0'^i^ FIG. 6 FIG
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•'•'•;.v':^Hv'i4t^ ''•',>;'
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THE BAR-MAGNET iii number as polar
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THE COMPASS 113 of gelatine and pla
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MAGNETISM, ELECTRICITY, LIGHT, HEAT
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MAGNETISM, ELECTRICITY, LIGHT, HEAT
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ATMOSPHERIC AND OTHER ELECTRICITY 1
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ATMOSPHERIC AND OTHER ELECTRICITY 1
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ANIMAL MAGNETISM 123 the electric o
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LINES OF COMMUNICATION AND FORCE 12
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A BEGINNINGS OF NERVOUS SYSTEM Fig.
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BEGINNINGS OF NERVOUS SYSTEM 135 So
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VOL I. ATOMS, MOLECULES, AND CELLS
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ATOMS, MOLECULES, AND CELLS AS FACT
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a' ATOMS, MOLECULES, AND CELLS AS F
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EVIDENCES OF DESIGN IN REPRODUCTIVE
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EVIDENCES OF DESIGN IN. REPRODUCTIV
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ADVANCE IN LOWER PLANT AND ANIMAL F
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THE VISIBLE AND INVISIBLE WORLD i8i
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THE VISIBLE AND INVISIBLE WORLD 183
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NEW THEORY OF MATTER 185 " To obtai
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NEW THEORY OF MATTER 187 in action
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NEW THEORY OF MATTER 189 the outset
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INTERACTION BETWEEN MENTAL AND MATE
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MATTER AND FORCE IN INORGANIC AND O
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Molybdenum THE ELEMENTS AND THEIR C
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HAECKEL'S BELIEF IN THE OMNIPOTENCE
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HAECKEL'S BELIEF IN THE OMNIPOTENCE
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MECHANICAL VIEWS OF KANT AND LAPLAC
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PROFESSOR HUXLEY'S VIEWS ON EVOLUTI
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THE TRAVELLING ORGANS OF ANIMALS 21
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THE TRAVELLING ORGANS OF ANIMALS 21
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TRAVELLING ORGANS IN RELATION TO EN
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KANT'S AND SPENCER'S VIEWS OF MATTE
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KANT'S AND SPENCER'S VIEWS OF MATTE
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SCRIPTURAL ACCOUNT OF CREATION 227
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GEOLOGY AS BEARING ON CREATION 229
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SIMPLE AND COMPLEX PLANTS AND ANIMA
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PLANTS AND ANIMALS IMPROVABLE UP TO
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EVERYTHING CONTROLLED AND UNDER SUP
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THE UNIVERSE AS A WORKING SYSTEM 23
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THE UNIVERSE AS A WORKING SYSTEM 23
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ENVIRONMENT 241 To take other examp
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INSTINCT 243 advance in plants and
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INSTINCT AND INTELLIGENCE 245 custo
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EFFECT OF COSMIC CHANGES ON PLANTS
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RHYTHMIC MOVEMENTS IN PLANTS AND AN
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RHYTHMIC MOVEMENTS IN PLANTS AND AN
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THE MUSCULAR MOVEMENTS 253 the invo
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THE MUSCULAR MOVEMENTS 255 From the
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THE MUSCULAR MOVEMENTS 257 performe
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NERVE REFLEXES IN ANIMALS 259 perfo
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NERVE REFLEXES IN ANIMALS 261 movem
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NERVE REFLEXES IN ANIMALS 263 forci
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NERVE REFLEXES IN ANIMALS 265 and t
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NERVE REFLEXES IN ANIMALS 267 taneo
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RHYTHMIC MUSCLES 269 their parts, u
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RHYTHMIC MUSCLES 271 That nerves in
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RESPIRATORY RHYTHMIC MOVEMENTS IN A
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RESPIRATORY ORGANS IN ANIMALS AND I
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NEW VIEW OF THE MECHANISM OF RESPIR
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NEW VIEW OF THE MECHANISN OF RESPIR
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THE MYCETOZOA 305 great variety ; i
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Pig. 62 (continued)— B. Gonooocci
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THE MYCETOZOA H PLATE LXXX Fifi. 1.
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Fig. 5, THE MYCETOZOA PLATE LXXXI F
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PROTOPLASMIC, AMCEBIC, AND OTHER MO
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PROTOPLASMIC, AMOEBIC, AND OTHER MO
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PROTOPLASMIC, AMGEBIC, AND OTHER MO
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MUSCULAR ACTION (VOLUNTARY AND INVO
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MUSCULAR ACTION (VOLUNTARY AND INVO
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Page 371 and 372: AMCEBA PROTEUS 333 The amcsba draws
Page 373 and 374: PARAMECIUM CAUDATUM 335 movements a
Page 375 and 376: GROMIA 337 spicules, &c. Similar va
Page 377 and 378: GROMIA 339 the very border line as
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Page 381 and 382: GROMIA 343 The barramunda is credit
Page 383 and 384: ANIMALS ADAPTED FOR AIR AND WATER B
Page 385 and 386: A CREATOR AND DESIGNER NECESSARY TO
Page 391 and 392: DIVISION OF LABOUR IN RELATION TO D
Page 397 and 398: DESIGN A PROMINENT FACTOR IN NATURE
Page 405 and 406: DESIGN IN THE REPRODUCTION AND GROW
Page 415 and 416: COMPOSITION OF THE HUMAN OVUM -i^jj
Page 417 and 418: § 74. Fertilisation of the Ovum. F
Page 419: FERTILISATION OF THE OVUM 381 (d) T
Page 423 and 424: FERTILISATION OF THE OVUM 385 PLATE
Page 425 and 426: DIVISION OF THE IMPREGNATED OVUM 3^
Page 427 and 428: DEVELOPMENT OF EMBRYONIC MEMBRANES
Page 429 and 430: DEVELOPMENT OF THE HUMAN EMBRYO AND
Page 431 and 432: DEVELOPMENT OF THE HUMAN EMBRYO AND
Page 433 and 434: DEVELOPMENT OF THE BRAIN AND VESSEL
Page 435 and 436: PLACENTAL AND FCETAL CIRCULATION 39
Page 437 and 438: SUCCESSIVE CHANGES WITNESSED IN THE
Page 439 and 440: TRANSITION LINKS IN RELATION TO TYP
Page 441 and 442: TRANSITION LINKS IN RELATION TO TYP
Page 443 and 444: CHANGES IN, AND PECULIARITIES OF, T
Page 445 and 446: CHANGES IN, AND PECULIARITIES OF, T
Page 447 and 448: DEVELOPMENT OF BLOOD, &c., IN MAN A
Page 453 and 454: DESIGN IN MIGRATION OF BIRDS AND OT
Page 455 and 456: DESIGN IN THE PRODUCTION AND DISTRI
Page 457 and 458: DESIGN AS WITNESSED IN WINGED SEEDS
Page 459 and 460: RESEMBLANCES BETWEEN WINGED SEEDS A
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