Listing 1 - 10 of 10 |
Sort by
|
Choose an application
633.51 --- 677.21 --- Cotton and similar fibres --- Cotton --- Plant and Crop Sciences. Crops --- Fibre Crops --- Tropical Africa --- tropical regions --- economic botany --- tropical agriculture --- agronomy --- Gossypium --- Cotton. --- 677.21 Cotton --- 633.51 Cotton and similar fibres --- Textile fibres --- plant oils
Choose an application
Choose an application
Choose an application
Choose an application
This book deals with the thought of William Harrison, a well-known Elizabethan intellectual, whose ideas are significant chiefly because they are often representative of the thoroughgoing Protestantism which adapted continental reformed ideas to the circumstances of Tudor England. The book explains how the mentality of Harrison, a university-trained Protestant, reveals a coherent worldview based upon a particular view of history which he applied to many areas of contemporary concern: the complete reformation of the church, the improvement of society, the removal of economic injustice, the reorientation of practical life and the restraint of the dangerous speculation current in natural philosophy. Dr Parry draws upon a unique and previously unknown manuscript source, Harrison's interpretation of world history, which provides unusually detailed information about how one individual interpreted the world.
Protestantism --- Reformation --- 284.1 <41> --- English Reformation --- Christianity --- Church history --- Protestant churches --- 284.1 <41> Lutheraanse hervorming. Reformatie van Luther--Verenigd Koninkrijk van Groot-Brittannië en Noord-Ierland --- Lutheraanse hervorming. Reformatie van Luther--Verenigd Koninkrijk van Groot-Brittannië en Noord-Ierland --- History --- Elisabeth --- Harrison, William, --- Elizabeth --- Relations with Protestants. --- England --- Great Britain --- Arts and Humanities
Choose an application
Choose an application
Choose an application
Systems biology has emerged as a highly interdisciplinary ?eld that has created broad enthusiasm in the scienti?c community. Systems biology is in vogue because of its potential to revolutionize not only biology but also medicine. Developments are anticipated that will change how we think about disease and how we approach therapeutic intervention. Perhaps the boldest vision of this future is presented by Dr. Leroy Hood, President of the Institute for Systems Biology in Seattle. He has been a protagonist and the main driving force of the underlying concept. - cording to Dr. Hood, systems biology will make possible a new era of medical care comprising predictive, preventive, personalized and part- ipatory (P4) medicine. While this vision appears futuristic, it has enticed both academic scienti?c communities and pharmaceutical industry R&D organizations. Systems biology ultimately attempts to understand biological s- tems at the molecular level. Examples of such systems are subcellular regulatory circuits with all their components, cells, organs, as well as - tire organisms. Over the past decade, technologies have been developed that enable systems-level interrogations, e.g., gene expression pro?ling, proteomics, and metabonomics, to name a few. Scientists have used such platforms to accumulate a tremendous amount of data. Although we have learned a great deal by collecting such detailed information, it seems our understanding has not similarly increased.
Biological systems --- Molecular biology --- Oncology. --- Cytology. --- Endocrinology. --- Cancer Research. --- Cell Biology. --- Internal medicine --- Hormones --- Cell biology --- Cellular biology --- Biology --- Cells --- Cytologists --- Tumors --- Cancer research. --- Cell biology. --- Endocrinology . --- Cancer research --- Biological control systems --- Pharmaceutical preparations
Choose an application
Histology. Cytology --- Oncology. Neoplasms --- oncologie --- cytologie --- histologie
Choose an application
Systems biology has emerged as a highly interdisciplinary ?eld that has created broad enthusiasm in the scienti?c community. Systems biology is in vogue because of its potential to revolutionize not only biology but also medicine. Developments are anticipated that will change how we think about disease and how we approach therapeutic intervention. Perhaps the boldest vision of this future is presented by Dr. Leroy Hood, President of the Institute for Systems Biology in Seattle. He has been a protagonist and the main driving force of the underlying concept. - cording to Dr. Hood, systems biology will make possible a new era of medical care comprising predictive, preventive, personalized and part- ipatory (P4) medicine. While this vision appears futuristic, it has enticed both academic scienti?c communities and pharmaceutical industry R&D organizations. Systems biology ultimately attempts to understand biological s- tems at the molecular level. Examples of such systems are subcellular regulatory circuits with all their components, cells, organs, as well as - tire organisms. Over the past decade, technologies have been developed that enable systems-level interrogations, e.g., gene expression pro?ling, proteomics, and metabonomics, to name a few. Scientists have used such platforms to accumulate a tremendous amount of data. Although we have learned a great deal by collecting such detailed information, it seems our understanding has not similarly increased.
Histology. Cytology --- Oncology. Neoplasms --- oncologie --- cytologie --- histologie
Listing 1 - 10 of 10 |
Sort by
|