Clinical Immunobiology
- 1st Edition, Volume 2 - January 1, 1974
- Imprint: Academic Press
- Editors: Fritz H. Bach, Robert A. Good
- Language: English
- Paperback ISBN:9 7 8 - 1 - 4 8 3 2 - 0 2 9 0 - 7
- eBook ISBN:9 7 8 - 1 - 4 8 3 2 - 1 6 3 3 - 1
Clinical Immunobiology, Volume 2 covers the advances in the field being made to apply bone marrow transplantation to the treatment of several diseases. This volume is divided into… Read more
Purchase options
Institutional subscription on ScienceDirect
Request a sales quoteClinical Immunobiology, Volume 2 covers the advances in the field being made to apply bone marrow transplantation to the treatment of several diseases. This volume is divided into 11 chapters and begins with surveys of the clinical considerations of bone marrow transplantation. Considerable chapters are devoted to the application of this transplantation to the treatment of various diseases, including aplastic anemia, aregenerative pancytopenia, leukemia, uniformly fatal severe combined immunodeficiency diseases, and Wiskott-Aldrich syndrome. Other chapters examine the cellular engineering in the form of bone marrow and thymus transplantation. The remaining chapters consider the effects of exposure to excessive amounts of radiation or cytotoxic chemicals, as well as the hematopoietic failure based on malfunction of the complex process of normal hematological development and maintenance. This book will be of great value to clinical immunobiologists, practicing physicians, researchers, and medical and biology students.
List of Contributors
Preface
Contents of Volume 1
Bone Marrow Transplantation
I. Introduction
II. Terminology
III. Technique
IV. Histocompatibility
V. Preparation of the Recipient
VI. Clinical Results
VII. Special Consideration According to Underlying Disease
VIII. Support for the Patient without Marrow Function
IX. Success or Failure of Engraftment
X. GVH Disease
XI. Immunological Status of Long-Term Survivors of Marrow Transplantation
XII. Infection following Engraftment
XIII. Nature of Tolerance
XIV. Antileukemic Effect (Adoptive Immunotherapy)
XV. Malignant Transformation of Donor Cells
XVI. A Look at the Future
References
Bone Marrow Transplantation for Aplasias and Leukemias
I. The First Bone Marrow Grafts in Man after Irradiation Exposure
II. Experimental and Clinical Bone Marrow Graft in Leukemia after Irradiation Conditioning (GVH versus GVL)
III. Bone Marrow Graft in Aplasias and Leukemias after ALG Conditioning; Split Lymphocyte Chimerism
IV. Bone Marrow Transplantation Using a Combination of ALG and Cyclophosphamide
V. Experimental Research for New Means to Control GVH
References
Bone Marrow and Thymus Transplants: Cellular Engineering to Correct Primary Immunodeficiency
I. Lymphoid System Development and the Concept of Two Interacting Immunity Systems
II. Correction of the DiGeorge Syndrome by Thymus Transplantation
III. Bone Marrow Transplants to Correct Immunodeficiency Diseases
IV. Bone Marrow Transplant to Correct SCID
V. Bone Marrow Transplant in Treating the Wiskott-Aldrich (WA) Syndrome
VI. Aspiration as a Problem in SCID Patients Fully Reconstituted Immunologically by Bone Marrow Transplantation
VII. Efforts to Use Isolated Stem Cells from Immunological Reconstitution in SCID
VIII. Efforts to Use Bone Marrow Transplantation to Correct SCID When a Matched Sibling Donor Is Not Available
IX. Genetic Determination of Histocompatibility Characteristics in Men and Mice
X. Bone Marrow Transplantation to Correct SCID with a Donor Mismatched with Recipient at All HL-A SD Determinants but Matched at the LD Locus Controlling MLC
XI. Correction of Clq Deficiency by Marrow Transplantation in SCID
XII. Relationship of Successful Marrow Transplantation in Aregenerative Anemia and Leukemia to Transplantations used in SCID
XI. Correction of Clq Deficiency by Marrow Transplantation in SCID
XIII. Correction of SCID by Fetal Liver Transplantation
XIV. New Experimental Observations Relevant to Cellular Engineering in Man
XV. Cellular Engineering and Common Diseases of Man
XVI. Cellular Engineering and Immunodeficiencies Based on Defective Development of Biological Amplification Systems
XVII. Immunodeficiencies in Common Human Diseases—A Challenge for Cellular Engineering
XVIII. Nutritional Deprivation and Immunological Deficiency—A Possible Challenge for Cellular or Molecular Engineering
XIX. Aging and Cellular Engineering
Bibliography
Selective Immunotherapy with Transfer Factor
I. Introduction
II. Early Beginnings—Viable Cells as Vehicles of TF
III. Histoincompatible Cell Transfer and Graft-versus-Host (GvH) Disease
IV. Viable Lymphocytes versus TFD for Immunotherapy
V. Later Developments—Availability of TFD
VI. The Scope of TFD for Immunological Reconstitution
VII. TFD Immunotherapy of Infectious Disease
VIII. Reconstitution of Congenital Immunodeficiency Diseases with TFD Therapy
IX. TFD and Cancer Immunotherapy
X. Immunotherapy with TFD—Unresolved Questions
XI. Conclusion
References
Transfer Factor
I. Introduction
II. Preparation of Transfer Factor
III. Evaluation of Cellular Immunity
IV. Technique of Transfer Factor Therapy and Prophylaxis of Infection
V. Wiskott-Aldrich Syndrome
VI. Mucocutaneous Candidiasis
VII. Combined Immunodeficiency Disease
VIII. Infectious Diseases
IX. Diseases of Unknown Etiology
X. Malignancy
XI. Adverse Reactions
XII. Specificity of Transfer
XIII. Potential Uses of Transfer Factor
XIV. Conclusion
References
Transfer Factor Therapy in Immunodeficiencies
I. Introduction
II. Preparation of TF
III. Effects in Normal Subjects
IV. Effects in Immunodeficiencies
V. Effects on Clinical Manifestations
VI. Discussion
VII. Summary
References
Immunological Surveillance: Pro and Con
I. Historical Introduction
II. Tumor Immunogenicity
III. Effects of Minimal Immunity on Nascent Tumors
IV. Experimental Alteration of the Immune Response
V. Experiments of Nature
VI. Miscellaneous Correlations
VII. Tumor Susceptibility and Phylogeny
VIII. General Conclusions
References
Serology of Cancer
I. Serological Detection of Antigens Associated with Tumors of Experimental Animals
II. Serological Approaches to the Study of Viral Oncogenesis
III. Serological Detection of Antigens Associated with Human Cancer
IV. Conclusions
Bibliography
The Role of Cell-Mediated Immunity in Control and Growth of Tumors
I. Introduction
II. Evidence That Immune Cells Play an Important Role in the Rejection of Tumors Containing TAA
III. Tests for Cell-Mediated Immunity
IV. Demonstration of Cell-Mediated Immunity to Animal Tumors Using in Vitro Techniques
V. Escape Mechanisms from Immunological Surveillance
VI. The “Unblocking” Phenomenon
VII. “Potentiating” and “Arming” Serum Effects
VIII. Cell Types Involved in Host Defense Reactions against Cancer
IX. Demonstration of Cell-Mediated Immunity to Human Tumors
X. Possible Implications of Tumor Immunology for Cancer Prevention and Therapy
XI. Conclusion
References
Experimental Models of Tumor Immunotherapy
I. Nonspecific Stimulation of the Immune Apparatus
II. Active Specific Immunotherapy
III. Adoptive Transfer of Cell-Mediated Immunity
IV. Passive Immunotherapy
V. Passive Transfer to Immunological Mediators
VI. Antiblocking Immunotherapy
VII. Discussion
References
Graft versus Leukemia
I. The Problem
II. Conceptual Considerations
III. The Treatment Model—Overview
IV. The Treatment Model—Dissected
V. Recent Experimental Results
VI. Clinical Implications?
VII. Summary
References
Subject Index
- Edition: 1
- Volume: 2
- Published: January 1, 1974
- No. of pages (eBook): 330
- Imprint: Academic Press
- Language: English
- Paperback ISBN: 9781483202907
- eBook ISBN: 9781483216331
Read Clinical Immunobiology on ScienceDirect