Beginning with an introduction to relevant genetic techniques, chapters cover all major groups of LAB, including the Bifidobacteria; plasmid biology, gene transfer, phage, and sugar metabolism; gene expression of various LAB; applications for genetically engineered LAB, including the emerging field of medical applications; and the legal and consumer issues that arise from such applications. This resource will set the benchmark for the state of knowledge of LAB genetics and should be of value to food scientists and other researchers working with LAB in its present and future capacities. Professionals using lactic acid bacteria (LAB) for research and/or as working organisms, whether in food and dairy fermentations or in the exciting new field of clinical delivery agents, will find this book invaluable. In addition, professors teaching under- and post-graduates in microbiology, and postgraduate research students will also find this an essential reference work.

The Lactic Acid Bacteria is planned as a series in a number of volumes, and the interest shown in it appears to justify a cautious optimism that a series comprising at least five volumes will appear in the fullness of time. This being so, I feel that it is desirable to introduce the series by providing a little of the history of the events which culminated in the decision to produce such a series. I also wish to indicate the boundaries of the group 'The Lactic Acid Bacteria' as I have defined them for the present purposes, and to outline my hopes for future topics in the series. Historical background lowe my interest in the lactic acid bacteria (LAB) to the late Dr Cyril Rainbow, who introduced me to their fascinating world when he offered me a place with him to work for a PhD on the carbohydrate metabolism of some lactic rods isolated from English beer breweries by himself and others, notably Dr Dora Kulka. He was particularly interested in their preference for maltose over glucose as a source of carbohydrate for growth, expressed in most cases as a more rapid growth on the disaccharide; but one isolate would grow only on maltose. Eventually we showed that maltose was being utilised by 'direct fermentation' as the older texts called it, specifically by the phosphorolysis which had first been demonstrated for maltose by Doudoroff and his associates in their work on maltose metabolism by a strain of Neisseria meningitidis.

This volume, the first in a series on the lactic acid bacteria, offers a series of reviews by carefully selected experts drawn from several countries. Although there have been a number of excellent conferences on the lactic acid bacteria in recent years there is no publication which brings together the topics explored so thoroughly in the present text. Several topics will have particular interest to the agriculture industry, including spoilage in sugar productions, lactic acid bacteria in plant silage and conversation/upgrading of other materials for use in animal feeding, coffee, and cocoa fermentations and the role of sporolactobacilli. A review of factors governing the competitive behavior of lactic acid bacteria in mixed cultures ties together a number of the themes developed in other chapters.

The Lactic Acid Bacteria is planned as a series in a number of volumes, and the interest shown in it appears to justify a cautious optimism that a series comprising at least five volumes will appear in the fullness of time. This being so, I feel that it is desirable to introduce the series by providing a little of the history of the events which culminated in the decision to produce such a series. I also wish to indicate the boundaries of the group 'The Lactic Acid Bacteria' as I have defined them for the present purposes, and to outline my hopes for future topics in the series. Historical background lowe my interest in the lactic acid bacteria (LAB) to the late Dr Cyril Rainbow, who introduced me to their fascinating world when he offered me a place with him to work for a PhD on the carbohydrate metabolism of some lactic rods isolated from English beer breweries by himself and others, notably Dr Dora Kulka. He was particularly interested in their preference for maltose over glucose as a source of carbohydrate for growth, expressed in most cases as a more rapid growth on the disaccharide; but one isolate would grow only on maltose. Eventually we showed that maltose was being utilised by 'direct fermentation' as the older texts called it, specifically by the phosphorolysis which had first been demonstrated for maltose by Doudoroff and his associates in their work on maltose metabolism by a strain of Neisseria meningitidis.

Beginning with an introduction to relevant genetic techniques, chapters cover all major groups of LAB, including the Bifidobacteria; plasmid biology, gene transfer, phage, and sugar metabolism; gene expression of various LAB; applications for genetically engineered LAB, including the emerging field of medical applications; and the legal and consumer issues that arise from such applications. This resource will set the benchmark for the state of knowledge of LAB genetics and should be of value to food scientists and other researchers working with LAB in its present and future capacities. Professionals using lactic acid bacteria (LAB) for research and/or as working organisms, whether in food and dairy fermentations or in the exciting new field of clinical delivery agents, will find this book invaluable. In addition, professors teaching under- and post-graduates in microbiology, and postgraduate research students will also find this an essential reference work.

Today large numbers of geoscientists apply thermodynamic theory to solu tions of a variety of problems in earth and planetary sciences. For most problems in chemistry, the application of thermodynamics is direct and rewarding. Geoscientists, however, deal with complex inorganic and organic substances. The complexities in the nature of mineralogical substances arise due to their involved crystal structure and multicomponental character. As a result, thermochemical solutions of many geological-planetological problems should be attempted only with a clear understanding of the crystal-chemical and thermochemical character of each mineral. The subject of physical geochemistry deals with the elucidation and application of physico-chemical principles to geosciences. Thermodynamics of mineral phases and crystalline solutions form an integral part of it. Developments in mineralogic thermody namics in recent years have been very encouraging, but do not easily reach many geoscientists interested mainly in applications. This series is to provide geoscientists and planetary scientists with current information on the develop ments in thermodynamics of mineral systems, and also provide the active researcher in this rapidly developing field with a forum through which he can popularize the important conclusions of his work. In the first several volumes, we plan to publish original contributions (with an abundant supply of back ground material for the uninitiated reader) and thoughtful reviews from a number of researchers on mineralogic thermodynamics, on the application of thermochemistry to planetary phase equilibria (including meteorites), and on kinetics of geochemical reactions."

The fifth volume in this series is focused on the chemical and physical interactions between rocks undergoing metamorphism and the fluids that they generate and that pass through them. The recognition that such pro cesses can profoundly affect the course of metamorphism has resulted in a number of recent papers and we consider that it is time for a review by some of the interested parties. We hope our selection of contributors provides an adequate cross section and demonstrates some of the flavor of this rapidly developing field. A cursory examination of the volume will reveal that there are widely divergent opinions on the compositions of metamorphic fluids and on the ways in which they interact physically and chemically with the rocks through which they pass. Since our own views are extensively discussed in Chapters 4 and 8, we leave the reader to determine his own brand of the "truth. " We wish to thank D. Bird, S. Bohlen, D. Carmichael, G. Flowers, C. Foster, C. Graham, E. Perry, J. Selverstone, R. Tracy, J. Valley, and R. Wollast for their chapter reviews. Thanks are also due C. Cheverton for her editorial assistance, and the helpful staff at Springer-Verlag New York."

When I undertook the production of the First Edition of this book it was my first foray into the world of book editing, and I had no idea of what I was undertaking! I was not entirely alone in this, as in asking me to produce such a book the commissioning Editor, Mr George Olley of Elsevier Ap plied Science Publishers, had pictured a text of perhaps 300 pages, but on seeing my list of chapter titles realized that we were talking about a - chapter, two-volume work. We eventually decided to go ahead with it, and the result was more successful than either of us had dared to hope could be It was therefore with rather mixed emotions that I contemplated the case. a second edition at the suggestion of Blackie Press, who had taken over the title from Elsevier. On the one hand, I was naturally flattered that the book was considered important enough to justify a second edition. On the other hand, I was very well aware that the task would be even greater this time.

This is a book about the why and how of doing experiments on rocks, minerals, magmas, and fluids. It could have as logically been subtitled "Experimental petrology" as "Experimental geochemistry," but we chose geochemistry to emphasize the broad and overlapping nature of current experimental work. We have tried to aim the book at a general readership which we hope will include advanced undergraduate students, graduate students, and anyone else interested in learning something about experimental petrology. Although we hope there will be something of interest for the practicing experimentalist, our aim is at the non-experimentalist interested in learning why experiments are useful, what kind of experiments can be done, and what some of the major problems and limitations are and how they can best be avoided. The result of a journey through this book should be an ability to evaluate published experimental work critically and a knowledge of the kinds of problems an experimentalist might be able to help solve. Some details of experimental technique are included in the Appendix for those readers who want to "get their hands dirty. " Indeed, one of our main incentives for writing this book was to try to encourage more petrologists and geochemists to become experimentalists. In our pedagogical approach we have chosen to discuss a small number of case histories as illustrations of principles and techniques. We have tried to select studies we regard as well executed.

Lavender Li, a teenage girl who died 30 years ago because of her star-crossed love with Britt Lynn and the rebellious gene in her blood, comes back to the world through reincarnation carrying a mission to save 100 lives in a week. Lavender goes to seek Britt's help and feels moved when she discovers Britt is faithful to their true love and stays unmarried. 30 years ago, their love was not accepted by Lavender's father. Now their love encounters a new problem-their age difference is unacceptable by the society. Will their true love be blessed? Or is it cursed again? When carrying out the mission, Britt and Lavender have to fight against the natural and man-made calamities, they also find rebellions are in all walks of life, and true loves are fundamentally the same, regardless of race, religion, or age. Though written with all the uncontainable hilarity and wittiness, Rebellious Love is also a deeply touching love story. Rebellion never changes, so does true love.

The idea for a series of volumes dealing with the 'Landmark Papers' defining the development of different areas of our science was discussed at a meeting of the council of the Mineralogical Society of Great Britain & Ireland in 2002. Council approved the idea by reasoning "which of us would not be interested in a collection of papers illustrating the development of a branch of mineralogy?" This, the third collection of such papers has been selected by Bernard Evans of the University of Washington. Much of Earth's crust and arguably parts of its mantle are composed of rock that has undergone partial to complete textural and mineralogical reconstitution as a result of changes in conditions imposed on it. Metamorphic rocks carry a record of surface, shallow and deep geological events and processes going back to 4 Ga. Early in the last century, the descriptive science of metamorphic petrography began a gradual evolution into metamorphic petrology and petrogenesis much as we know it today. Researchers came to depend more and more on related sciences, such as thermodynamics, materials science, mineralogy, tectonophysics, and isotope geochemistry, to provide a fuller understanding of the facts coming from the field and the laboratory. Fundamental principles and procedures from these borrowed sciences helped keep metamorphic petrology moving and contributed to its endless fascination. The purpose of this Landmark series is to let students read for themselves in the original how some of the giants of the field set down their ideas. Their papers convey something that is not necessarily obvious in the summaries found in our textbooks, namely a feeling and respect for the environment of intellectual discourse in which the early thinkers worked. Many things that we consider self-evident today were not at that time part of the general scientific understanding, yet they wrote with admirable clarity and logic and made the best of what information was available.

Write so that it highlights the benefits of buying your book over other like it. If you have not purchased the customized back cover, the About the Book text will be your back cover text. Please refer to Customized Back Cover text for word counts. (If you are interested in purchasing the Customized Back Cover, please contact 1st Books staff) It's a story about a black woman that has endured trials and tribulations growing up in the early seventies, and through out her lifetime. It is about a woman that survives against all odds, even when she thought she would die. The book is about how she remembers certain moments in her past that have caused her emotional pain and left scars, yet in some form these memories connect her to the present, and helps her grow, as well as heal. The book is about love, family and forgiveness. It tells you about the mistakes she made in her life and the regrets she has. It also tells you that you can be forgiven and still be happy. What she tries to do, is tell the reader that you should not run from you past, but learn from all the mistakes you make, and believe in your self no matter the cost. another. We make mistakes, but we can't let those mistakes ruin what we work so hard to accomplish. The book tries to tell you that all scars will heal in time, and you should be true to yourself and always follow your dreams. Why all women should read this book is simple. It was written from the heart, and will make you cry and maybe even laugh. But you will want to read it again and again.