Nicht aus der Schweiz? Besuchen Sie lehmanns.de
Dissection of Vertebrates -  Gerardo De Iuliis,  Dino Pulera

Dissection of Vertebrates (eBook)

eBook Download: PDF | EPUB
2006 | 2. Auflage
352 Seiten
Elsevier Science (Verlag)
978-0-12-378593-0 (ISBN)
Systemvoraussetzungen
Systemvoraussetzungen
36,99 inkl. MwSt
(CHF 36,10)
Der eBook-Verkauf erfolgt durch die Lehmanns Media GmbH (Berlin) zum Preis in Euro inkl. MwSt.
  • Download sofort lieferbar
  • Zahlungsarten anzeigen
The Dissection of Vertebrates, Second Edition, provides students with a manual that combines pedalogical effective text with high-quality, accurate, and attractive visual references. Using a systemic approach within a systematic framework for each vertebrate, this book covers several animals commonly used in providing an anatomical transition sequence. Seven animals are covered: lamprey, shark, perch, mudpuppy, frog, pigeon, and cat. This updated version include a revised systemic section of the introductory chapter; corrections to several parts of the existing text and images; new comparative skull sections included as part of the existing vertebrates; and a companion site with image bank. This text is designed for 2nd or 3rd year university level comparative vertebrate anatomy courses. Such courses are usually two-semester courses, and may either be a required course or an elective. It is typically a required course for Biology and Zoology majors, as well as for some Forensics and Criminology programs, and offered as an elective for many other non-zoology science majors. - Winner of the NYSM Jury award for the Rock Dove Air Sacs, Lateral and Ventral Views illustration - Expertly rendered award-winning illustrations accompany the detailed, clear dissection direction - Organized by individual organism to facilitate classroom presentation - Offers coverage of a wide range of vertebrates - Full-color, strong pedagogical aids in a convenient lay-flat presentation - Expanded and updated features on phylogenic coverage, mudpuppy musculature and comparative mammalian skulls

Gerardo De Iuliis, PhD, received his doctorate from the Department of Zoology, University of Toronto, in 1996, with specialization in Vertebrate Paleontology and Comparative Vertebrate Anatomy. He currently teaches two courses, Comparative Vertebrate Anatomy and Vertebrate Paleontology: Major Transitions in Vertebrate History, at the Department of Ecology and Evolutionary Biology, University of Toronto, and Human Anatomy and Physiology at George Brown College (Toronto), and is a Research Associate at the Royal Ontario Museum (Toronto). His primary research interests include the systematics and paleobiology of xenarthrans, particularly of fossil sloths. He has published numerous articles on fossil sloths, as well as on fossil cingulates and lungfish, among other vertebrate groups.
The Dissection of Vertebrates, Second Edition, provides students with a manual that combines pedalogical effective text with high-quality, accurate, and attractive visual references. Using a systemic approach within a systematic framework for each vertebrate, this book covers several animals commonly used in providing an anatomical transition sequence. Seven animals are covered: lamprey, shark, perch, mudpuppy, frog, pigeon, and cat. This updated version include a revised systemic section of the introductory chapter; corrections to several parts of the existing text and images; new comparative skull sections included as part of the existing vertebrates; and a companion site with image bank. This text is designed for 2nd or 3rd year university level comparative vertebrate anatomy courses. Such courses are usually two-semester courses, and may either be a required course or an elective. It is typically a required course for Biology and Zoology majors, as well as for some Forensics and Criminology programs, and offered as an elective for many other non-zoology science majors. - Winner of the NYSM Jury award for the Rock Dove Air Sacs, Lateral and Ventral Views illustration- Expertly rendered award-winning illustrations accompany the detailed, clear dissection direction- Organized by individual organism to facilitate classroom presentation- Offers coverage of a wide range of vertebrates- Full-color, strong pedagogical aids in a convenient lay-flat presentation- Expanded and updated features on phylogenic coverage, mudpuppy musculature and comparative mammalian skulls

Front cover 1
Dissection of Vertebrates 2
Copyright page 3
Dedication 4
Table of contents 6
Preface 12
Acknowledgments 16
Introduction 18
Directional Terminology and Planes of Section 18
Chapter 1: Craniata and Vertebrata 22
Phylogeny and Classification 22
Vertebrate Relatives 25
Craniates and Vertebrates 28
Early Stages in Vertebrate Evolution 29
Vertebrata 29
Amniote Skulls and Classification 37
Chapter 2: The Lamprey 40
Introduction 40
Section I: Skeleton 40
Section II: External Anatomy 41
Section III: Pleuroperitoneal Cavity and Viscera 42
Section IV: Sagittal Section 43
Chapter 3: The Shark 48
Introduction 48
Section I: Skeleton 48
Section II: External Anatomy 56
Section III: Muscular System 60
Section IV: Digestive and Respiratory Systems 66
Section V: Cardiovascular System 71
Section VI: Urogenital System 80
Section VII: Sensory Organs 84
Section VIII: Brain and Cranial Nerves 91
Chapter 4: The Perch 100
Introduction 100
Section I: Skeleton 100
Section II: External Anatomy 103
Section III: MOUTH, ORAL CAVITY, AND PHARYNX 105
Section IV: Pleuroperitoneal Cavity and Viscera 106
Chapter 5: The Mudpuppy 110
Introduction 110
Section I: Skeleton 110
Section II: External Anatomy 117
Section III: Muscular System 117
Section IV: Mouth, Oral Cavity, and Pharynx 130
Section V: Pleuroperitoneal Cavity and Viscera 131
Section VI: Urogenital System 134
Section VII: Cardiovascular System 138
Chapter 6: The Frog 148
Introduction 148
Section I: Skeleton 148
Section II: External Anatomy 154
Section III: Mouth, Oral Cavity, and Pharynx 155
Section IV: Pleuroperitoneal Cavity, Viscera, and Urogenital System 156
Section V: Cardiovascular System 161
Chapter 7: The Cat 168
Introduction 168
Section I: Skeleton 169
Cranial Skeleton: Supplement—Comparative Mammalian Skulls 178
Section II: External Anatomy 197
Section III: Muscular System 198
Section IV: Digestive and Respiratory Systems 225
Section V: Cardiovascular System 241
Section VI: Urogenital System 260
Section VII: Brain and Cranial Nerves 265
Chapter 8: Reptile Skulls and Mandibles 274
Introduction 274
Section I: Turtle Skull and Mandible 274
Section II: Iguana Skull and Mandible 281
Section III: Snake Skull and Mandible 289
Section IV: Alligator Skull and Mandible 294
Section V: Dinosaur Skull and Mandible 301
Chapter 9: The Pigeon 308
Introduction 308
Skeleton 308
External Anatomy 315
Musculature 318
Body Cavity, Viscera, and Vessels 321
Selected References 332
Index 336

CHAPTER 1

Craniata and Vertebrata


Publisher Summary


The vertebrates themselves, or Verte­brata, are included in a larger taxon termed “Craniata.” Within Craniata and Vertebrata are many taxa. These taxa and the evolutionary relationships among them are outlined in this chapter. The taxa related to vertebrates include Echinodermata (sand dollars, sea lilies, star fish, sea cucumbers, urchins), Hemichordata (acorn worms and pterobranchs), Urochordata (tunicates or sea squirts), and Cephalochordata (amphioxus). The chordates are united by the presence of the synapomorphies—an endostyle; a dorsal, hollow nerve cord; a notochord; and a postanal tail. Another feature important in chordates is the presence of pharyngeal slits. The lampreys, or Petromyzontoidea, represent the most basal living vertebrates. Several important synapomorphies mark this group. All verte­brates have at least two semicircular ducts in the inner ear—structures concerned with improving balance and position of the organism. Also, vertebrates have musculature associated with the fins, allowing better control of the fins and thus of their locomotion through water.

The vertebrates or Vertebrata form an ancient group with a history spanning some 545 million years. On the one hand, they include the organisms most familiar to us, such as fish, birds, cats and dogs, as well as humans; on the other, few people are aware of the great diversity in their form, structure, and habits. Indeed, they include some of the largest and more complex organisms ever evolved. But vertebrates are part of a larger grouping of animals, and to understand their history and the development of their structure, they must be placed in phylogenetic context.

In discussing vertebrates, several other groups of organisms are usually considered. A monophyletic or natural group (see later) of organisms is referred to as a taxon (plur., taxa). The taxa related (in terms of recent common ancestry) to vertebrates include Echinodermata (sand dollars, sea lilies, star fish, sea cucumbers, urchins), Hemichordata (acorn worms and pterobranchs), Urochordata (tunicates or sea squirts), and Cephalochordata (amphioxus). These are the typical nonvertebrate (or “invertebrate”) relatives of the group in which we are mainly interested. The vertebrates themselves, or Vertebrata, are included in a larger taxon termed Craniata. Within Craniata and Vertebrata are many taxa. These taxa and the evolutionary relationships among them (see Figure 1.1) are briefly outlined here to provide an organizational framework for undertaking the dissection of the vertebrates discussed in this manual. Before this, however, it is necessary to present an explanation of several important terms used in discussions of phylogeny. Phylogeny refers to the pattern of descent among taxa. It describes, in other words, the evolutionary or genealogical relationships among them. Evolution is a historical (and on-going) process. Therefore, the evolution of organisms occurred in only one way—for example, humans and chimpanzees are, among living creatures, either each other’s closest relatives (they share a common ancestor not shared by other organisms) or they are not. Only one of these possibilities is correct. Evolutionary biologists try to recover the pattern of descent based on the data they have available to them. Phylogenies are therefore hypotheses that approximate the true pattern of descent. As hypotheses, they are testable and thus open to falsification when new data become available. If a hypothesis is falsified, then another one may be proposed—for example, new evidence might show that humans share a recent common ancestor with a different great ape than chimpanzees, such as orangutans.


FIGURE 1.1 Cladogram showing phylogeny of Deuterostomata. Some synapomorphies of the main groups are provided in the boxes below the cladogram.

Phylogeny and Classification


For most of the past 250 years, the classification of organisms has followed the Linnean system, which uses ranks to designate levels of organization of the organisms being classified. Most readers will be familiar with the main formal Linnean ranks, ordered hierarchically from most to least inclusive: Kingdom, Phylum, Class, Order, Family, Genus, and Species. Researchers have differed in assigning rank to the vertebrates and their relatives. For example, some authors have recognized three phyla: Phylum Echinodermata, Phylum Hemichordata, and Phylum Chordata. Others consider Urochordata and Cephalochordata as phyla on their own, separate from Chordata. Still others have viewed Urochordata as a separate phylum, but Cephalochordata as a subphylum of the Phylum Chordata. If you find this confusing, you’re not alone! The different designations did—or at any rate were meant to—have some grounding in biological reality. They reflected a particular researcher’s perception of the magnitude of the difference in the levels of organization (a quality that may be referred to as a grade) among the taxa under consideration. Thus, if a taxon was considered a phylum, it mainly implied that its members had a fundamentally different basic body plan than if it was considered only a subphylum of a larger taxon. As you have probably already realized, researchers’ perceptions along these lines are subjective.

In recent years, however, the formal Linnean ranking system has fallen increasingly into disuse as systematists have become aware that there is no intrinsic or special value of any particular taxon that would justify its recognition as a higher or lower rank, compared to other taxa. In other words, there is no special reason for “elevating” birds or Aves to the rank of Class, equal and thereby excluded from, the Class Reptilia. In fact, it is improper to do so, because the birds are properly part of the taxon named Reptilia. Here, formal ranks are not used, and taxa are referred to simply by their name (except for the preceding paragraph, in which ranks were used to reflect the historical understanding of the groups).

Formal names are applied to natural or monophyletic groups. A monophyletic group includes an ancestor and all of its descendants (provided that the phylogeny has been carefully reconstructed). Such groups are termed clades. Clades are recognized based on common ancestry. If two taxa are in a clade, it is because they are linked by a common ancestor. Biologists infer such ancestral relationships through the presence of shared derived characters or synapomorphies (see later). If two (or more) taxa share a character that is exclusive to them, then we assume that they share this feature because they have inherited it from a common ancestor, rather than each having evolved the character independently, and so infer that the taxa are descendants of the same ancestor (which we are not able to actually recognize, and thus refer to as hypothetical). Biologists use many characters in trying to reconstruct phylogeny. The practice is complicated by the fact that organisms can and do evolve very similar characters independently of each other, an occurrence referred to as homoplasy. In reconstructing phylogeny, a researcher considers the totality of evidence. It is rare that only a single character can be used to reconstruct phylogeny.

The pattern of relationships among taxa is depicted visually by a cladogram, which is essentially a diagram of nodes and branches, with the nodes representing ancestors and the branches that diverge from a node representing the descendant taxa of the ancestor.1 The node, then, may be thought of as representing the hypothetical ancestor of the two taxa that diverge from it. The pattern of branching represents the pattern of relationship. Examine the cladogram in Figure 1.1. Note the node from which the Hemichordata and Chordata diverge. This node represents ancestor species that split to produce two lineages, one that evolved into Chordata and the other into Hemichordata. The two branches that diverge from this ancestor represent the evolutionary paths to the divergent taxa.

Only the branching pattern is of concern. The length of the branches is immaterial in terms of absolute time, but relative time is implied by branching sequence. Clearly, the divergence of Cephalochordata and Craniata occurred after the divergence of Hemichordata and Somitichordata.

Informal names, set between quotation marks, are used to designate a group of organisms that do not descend from the same common ancestor, but that do possess (or lack) some of the features of the taxon in which we are interested. Many of these terms were considered formal names in earlier classifications. For example, the term “protochordates” is commonly used to refer to the hemichordates, urochordates, and cephalochordates. Grouping them together is a shorthand way of referring to them as close relatives of chordates (no quotation marks here, so this is the vernacular form of the formal name Chordata), and that they lack various characters that chordates possess. We must be clear that informal groups, though convenient, do not reflect phylogeny; they are not monophyletic.

In discussing how biologists reconstruct phylogeny, the nature of the similarity among organisms must be considered, because it is necessary to differentiate between those similarities that are useful in reconstructing phylogeny and those that are not. One kind, termed plesiomorphic, refers to similarity based on presence of ancestral conditions or states. Consider the Vertebrata, in which the presence of vertebrae is an ancestral feature—in...

Erscheint lt. Verlag 3.8.2006
Sprache englisch
Themenwelt Medizin / Pharmazie Medizinische Fachgebiete Chirurgie
Naturwissenschaften Biologie Evolution
Naturwissenschaften Biologie Ökologie / Naturschutz
Naturwissenschaften Biologie Zoologie
Technik
Veterinärmedizin Vorklinik
Veterinärmedizin Klinische Fächer Chirurgie
ISBN-10 0-12-378593-6 / 0123785936
ISBN-13 978-0-12-378593-0 / 9780123785930
Haben Sie eine Frage zum Produkt?
PDFPDF (Adobe DRM)
Größe: 109,5 MB

Kopierschutz: Adobe-DRM
Adobe-DRM ist ein Kopierschutz, der das eBook vor Mißbrauch schützen soll. Dabei wird das eBook bereits beim Download auf Ihre persönliche Adobe-ID autorisiert. Lesen können Sie das eBook dann nur auf den Geräten, welche ebenfalls auf Ihre Adobe-ID registriert sind.
Details zum Adobe-DRM

Dateiformat: PDF (Portable Document Format)
Mit einem festen Seiten­layout eignet sich die PDF besonders für Fach­bücher mit Spalten, Tabellen und Abbild­ungen. Eine PDF kann auf fast allen Geräten ange­zeigt werden, ist aber für kleine Displays (Smart­phone, eReader) nur einge­schränkt geeignet.

Systemvoraussetzungen:
PC/Mac: Mit einem PC oder Mac können Sie dieses eBook lesen. Sie benötigen eine Adobe-ID und die Software Adobe Digital Editions (kostenlos). Von der Benutzung der OverDrive Media Console raten wir Ihnen ab. Erfahrungsgemäß treten hier gehäuft Probleme mit dem Adobe DRM auf.
eReader: Dieses eBook kann mit (fast) allen eBook-Readern gelesen werden. Mit dem amazon-Kindle ist es aber nicht kompatibel.
Smartphone/Tablet: Egal ob Apple oder Android, dieses eBook können Sie lesen. Sie benötigen eine Adobe-ID sowie eine kostenlose App.
Geräteliste und zusätzliche Hinweise

Zusätzliches Feature: Online Lesen
Dieses eBook können Sie zusätzlich zum Download auch online im Webbrowser lesen.

Buying eBooks from abroad
For tax law reasons we can sell eBooks just within Germany and Switzerland. Regrettably we cannot fulfill eBook-orders from other countries.

EPUBEPUB (Adobe DRM)
Größe: 27,2 MB

Kopierschutz: Adobe-DRM
Adobe-DRM ist ein Kopierschutz, der das eBook vor Mißbrauch schützen soll. Dabei wird das eBook bereits beim Download auf Ihre persönliche Adobe-ID autorisiert. Lesen können Sie das eBook dann nur auf den Geräten, welche ebenfalls auf Ihre Adobe-ID registriert sind.
Details zum Adobe-DRM

Dateiformat: EPUB (Electronic Publication)
EPUB ist ein offener Standard für eBooks und eignet sich besonders zur Darstellung von Belle­tristik und Sach­büchern. Der Fließ­text wird dynamisch an die Display- und Schrift­größe ange­passt. Auch für mobile Lese­geräte ist EPUB daher gut geeignet.

Systemvoraussetzungen:
PC/Mac: Mit einem PC oder Mac können Sie dieses eBook lesen. Sie benötigen eine Adobe-ID und die Software Adobe Digital Editions (kostenlos). Von der Benutzung der OverDrive Media Console raten wir Ihnen ab. Erfahrungsgemäß treten hier gehäuft Probleme mit dem Adobe DRM auf.
eReader: Dieses eBook kann mit (fast) allen eBook-Readern gelesen werden. Mit dem amazon-Kindle ist es aber nicht kompatibel.
Smartphone/Tablet: Egal ob Apple oder Android, dieses eBook können Sie lesen. Sie benötigen eine Adobe-ID sowie eine kostenlose App.
Geräteliste und zusätzliche Hinweise

Zusätzliches Feature: Online Lesen
Dieses eBook können Sie zusätzlich zum Download auch online im Webbrowser lesen.

Buying eBooks from abroad
For tax law reasons we can sell eBooks just within Germany and Switzerland. Regrettably we cannot fulfill eBook-orders from other countries.

Mehr entdecken
aus dem Bereich
Soforthilfe bei den häufigsten Schmerzzuständen

von Hadi Taghizadeh; Justus Benrath

eBook Download (2024)
Springer Berlin Heidelberg (Verlag)
CHF 29,30

von Felix Largiadèr; Hans-Detlev Saeger …

eBook Download (2022)
Georg Thieme Verlag KG
CHF 78,15