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"Cancer Research History 20th century."
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Ontario Cancer Institute
To achieve this goal the institute divided its operation into four strands: two of the strands were the research areas - the study of advanced radiation therapy and biology, which worked separatively but cooperatively; a third was patient care; and the fourth element was leadership, provided by the clinical chiefs, the heads of the research divisions, and the administration, in particular the institute's first administrator, John Law. Together these strands helped create a philosophy that made the Ontario Cancer Institute unique and provided the basis for its national and international success. Essential to these successes was a new graduate department, Medical Biophysics, based in the University of Toronto School of Graduate Studies. This department, which provided an innovative, research-based doctoral and masters program, meant that the OCI could accurately be described as a centre for cancer treatment, research, and education. McCulloch describes how the first quantitative assay for stem cells played a major role in bringing OCI research to the international stage as well as influencing other science and much of the clinical thinking in the Institute. Other major advances that brought international recognition have been the identification of the mechanisms that allow cancer cells to resist death from the effects of a variety of different tumours and the isolation of the gene that encodes the T cell receptor, a critical part of the immune apparatus for dealing with foreign cells and viruses. McCulloch also details how lack of space to meet growing demands was a continuing source of frustration and disagreement, and how sometimes serious interpersonal problems hindered the forward thrust of development. Describing these events as well as institute's successes, he provides an insight into the history of Canada's premier cancer research centre.
eBook
Golden holocaust
The cigarette is the deadliest artifact in the history of human civilization. It is also one of the most beguiling, thanks to more than a century of manipulation at the hands of tobacco industry chemists. In Golden Holocaust, Robert N. Proctor draws on reams of formerly-secret industry documents to explore how the cigarette came to be the most widely-used drug on the planet, with six trillion sticks sold per year. He paints a harrowing picture of tobacco manufacturers conspiring to block the recognition of tobacco-cancer hazards, even as they ensnare legions of scientists and politicians in a web of denial. Proctor tells heretofore untold stories of fraud and subterfuge, and he makes the strongest case to date for a simple yet ambitious remedy: a ban on the manufacture and sale of cigarettes.
eBook
The Intriguing History of Cancer Immunotherapy
Immunotherapy is often perceived as a relatively recent advance. In reality, however, one should be looking for the beginnings of cancer immunotherapy under different names as far as in the Antiquity. The first scientific attempts to modulate patients' immune systems to cure cancer can be attributed to two German physicians, Fehleisen and Busch, who independently noticed significant tumor regression after erysipelas infection. The next significant advances came from William Bradley Coley who is known today as the Father of Immunotherapy. It was Coley who first attempted to harness the immune system for treating bone cancer in 1891. His achievements were largely unnoticed for over fifty years, and several seminal discoveries in the field of Immunology, such as the existence of T cells and their crucial role in immunity in 1967, stepped up the research toward cancer immunotherapy known today. The following paper tracks cancer immunotherapy from its known beginnings up until recent events, including the 2018 Nobel Prize award to James Allison and Tasuku Honjo for their meticulous work on checkpoint molecules as potential therapeutic targets. That work has led to the successful development of new checkpoint inhibitors, CAR T-cells and oncolytic viruses and the pace of such advances brings the highest hope for the future of cancer treatment.
Journal Article
Genomic prediction unifies animal and plant breeding programs to form platforms for biological discovery
Wayne Powell and colleagues compare the different tools and approaches used by the plant breeding community versus the animal breeding community for crop and livestock improvement. They argue that the two disciplines can be united via adoption of genomic selection along with the exchange of resources and techniques between the two areas.
The rate of annual yield increases for major staple crops must more than double relative to current levels in order to feed a predicted global population of 9 billion by 2050. Controlled hybridization and selective breeding have been used for centuries to adapt plant and animal species for human use. However, achieving higher, sustainable rates of improvement in yields in various species will require renewed genetic interventions and dramatic improvement of agricultural practices. Genomic prediction of breeding values has the potential to improve selection, reduce costs and provide a platform that unifies breeding approaches, biological discovery, and tools and methods. Here we compare and contrast some animal and plant breeding approaches to make a case for bringing the two together through the application of genomic selection. We propose a strategy for the use of genomic selection as a unifying approach to deliver innovative 'step changes' in the rate of genetic gain at scale.
Journal Article
Appreciating force and shape — the rise of mechanotransduction in cell biology
The form of vertebrates is shaped by the sensing and relaying of mechanical forces that are applied between cells and their microenvironment. Mechanobiology has emerged as a field of research dedicated to studying these forces and their communication through signalling processes, which are collectively known as mechanotransduction.
Although the shapes of organisms are encoded in their genome, the developmental processes that lead to the final form of vertebrates involve a constant feedback between dynamic mechanical forces, and cell growth and motility. Mechanobiology has emerged as a discipline dedicated to the study of the effects of mechanical forces and geometry on cell growth and motility — for example, during cell–matrix adhesion development — through the signalling process of mechanotransduction.
Journal Article
A history of exploring cancer in context
The concept that progression of cancer is regulated by interactions of cancer cells with their microenvironment was postulated by Stephen Paget over a century ago. Contemporary tumour microenvironment (TME) research focuses on the identification of tumour-interacting microenvironmental constituents, such as resident or infiltrating non-tumour cells, soluble factors and extracellular matrix components, and the large variety of mechanisms by which these constituents regulate and shape the malignant phenotype of tumour cells. In this Timeline article, we review the developmental phases of the TME paradigm since its initial description. While illuminating controversies, we discuss the importance of interactions between various microenvironmental components and tumour cells and provide an overview and assessment of therapeutic opportunities and modalities by which the TME can be targeted.
Journal Article
Thermal ablation of tumours: biological mechanisms and advances in therapy
Minimally invasive thermal ablation of tumours has become common since the advent of modern imaging. This Opinion article examines the mechanisms of tumour cell death that are induced by the most common thermoablative techniques and discusses the rapidly developing areas of research in the field.
Minimally invasive thermal ablation of tumours has become common since the advent of modern imaging. From the ablation of small, unresectable tumours to experimental therapies, percutaneous radiofrequency ablation, microwave ablation, cryoablation and irreversible electroporation have an increasing role in the treatment of solid neoplasms. This Opinion article examines the mechanisms of tumour cell death that are induced by the most common thermoablative techniques and discusses the rapidly developing areas of research in the field, including combinatorial ablation and immunotherapy, synergy with conventional chemotherapy and radiation, and the development of a new ablation modality in irreversible electroporation.
Journal Article