Milestones and rates of growth in the development of biology.

An attempt has been made to examine the exponetial rate of increase of the great discoveries, the "milestones," in the rise of biology from the beginning of the seventeenth century, and particularly in the rise of genetics from the beginning of the twentieth century. The biological sciences in general, during the three centuries named, exhibit a doubling of the number of great discoveries in each fifty years. Genetics, in the twentieth century, has risen much faster. Its doubling time for the most significant discoveries has been about twenty-two and a half years. Either of these rates is of course far slower than the exponential rise in the total output of biological science, the number of scientists, or the cost of science, which have been generally reported to double about every ten years or less. It follows that, as time passes, and until these exponetial rates become considerably altered, a relationship of diminishing returns is quite evident. As time passes, even though the most significant discoveries continue to increase exponetially, it takes a greater total output, a greater number of (assisting?) scientists, and greater amounts of money to yield a set quantity of major new findings. The rapid rise of the life sciences cannot continue its present course into the twenty-first century without meeting ineluctable limits to expansion. It may be argued that as in other human spheres of activity, so too in natural science there are limits to growth which we are rapidly approaching. From the predictable asymptote only unpredictable breakthroughs might deliver us.     

Biological machines: from mills to molecules

Although scientific progress is usually represented as being linear, it may, in fact, have a cyclical character--some discoveries may be forgotten or lost (at least temporarily), and themes may reappear through the centuries. Consider, for example, the concept of 'molecular machines', from the exciting phase of research that flourished in the seventeenth century, to the idea of machines that is at centre stage in modern cell biology.     

Human treponematosis and tuberculosis: evidence from the New World.

The purpose of this study has been first, to critically review the evidence for the presence of human treponematosis and tuberculosis in the skeletal remains of prehistoric natives in the New World, and second, to report on nine new cases dated to before contact and suggesting the presence of these two disease conditions. A review of the medical history and findings by human paleopathologists leaves little doubt that both diseases originated in the Old World. The findings of this study lend further support to the fact that, although rare, human treponematosis and tuberculosis were indeed endemic in the pre-Columbia New World before contact. There is no evidence that these two diseases could have arisen independently and de novo, especially during the relatively short time since man's arrival in the New World. Where a disease has been endemic for quite some time as appears to be the case with human treponematosis and tuberculosis, milder forms of the disease and improved host response could have developed in which only the most severe cases would be observable. This explains the rarity of skeletal lesions suggestive of these two human disease conditions in prehistoric human populations.     

数据科学在旧石器考古学中的应用

从考古学诞生之初,对抽象数据的解读与分析就一直伴随。对于旧石器考古学而言,“人工制品”成为了传达史前物质文化信息的主要载体,对人工制品中所提取的数据进行科学解读,成为了复原古代人类历史的关键步骤。数据科学在旧石器考古学中的应用具有三个主要因素,分别是数理统计学、计算机应用,以及旧石器考古学的基础数据与核心科学问题以及理论知识,即采用某种或多种逻辑将旧石器考古学领域的数据进行基于计算机平台的数理统计,并借助计算机语言对庞大的数据进行快速计算,从而帮助我们解释和重建史前人类社会。在目前的旧石器考古学领域,研究者们已经不再满足于对标本所进行的基础的描述性信息统计,对数据进行科学的处理并系统解读的诉求前所未有的强烈,这种诉求不断推动着学科的发展,深化了我们原本对史前社会的认识,甚至开拓出了新的研究领域,极大地推动了旧石器考古学的发展。本文就数据科学的概念、技术路线,以及在旧石器考古学中的应用历史与发展前景做详细介绍,希望通过系统性的梳理,使更多读者熟悉相关的研究手段与具体技术,使更多考古学者对数据科学的应用产生兴趣,从而应用于相关的项目研究中。     

Teste Albumasare cum Sibylla: astrology and the Sibyls in medieval Europe

In the 1480s Dominican humanist Filippo de’ Barbieri published an illustration of a supposedly ancient female seer called the ‘Sybilla Chimica’, whose prophetic text repeated the words of the ninth-century astrologer Abu Ma‘shar. In tracing the origins of Barbieri’s astrological Sibyl, this article examines three sometimes interlocking traditions: the attribution of an ante-diluvian history to the science of the stars, the assertion of astrology’s origins in divine revelation, and the belief in the ancient Sibyls’ predictions of the birth of Christ and other Christian truths. Medieval authors from the twelfth century on began to cite these traditions together, thereby simultaneously authorizing the use of astrology to predict religious changes and blurring the categories of natural and supernatural as applied to human understanding. This blending of astrology and prophecy appears notably in works by such authors as John of Paris, John of Legnano, Johannes Lichtenberger, and Marsilio Ficino. Ultimately the trajectory that produced Barbieri’s astrological Sibyl would lead to a wave of astrological apocalyptic predictions in the sixteenth and seventeenth centuries, as well as to the harnessing of astrology for the defense of the faith in the form of an astrological natural theology, sacralizing science as well as nature.     

Henderson Island prehistory: colonization and extinction on a remote Polynesian island

Situated at the extreme margin of the Indo-West Pacific biotic province, the four islands of the isolated Pitcairn Group hold interest for biogeographers and archaeologists alike. Human settlement may have been as early as the 8th century AD for the uplifted limestone island of Henderson, the most pristine island of its kind. An archaeological survey of the Pitcairn Islands is provided, while Henderson is examined in detail. Recent extensive excavations provide a record of change during 600 years of human occupation. Adaptation to the ecologically-marginal conditions is documented by artefacts, more than 150000 vertebrate bones, molluscs and subfossil plant remains recovered from stratigraphic contexts. The effects of prehistoric human occupation on the pristine environment are revealed by Polynesian plant and animal introductions, bird extinctions and range reductions, possible over-predation of marine molluscs, exploitation of sea turtles, and large-scale burning for swidden agriculture. The origin of human colonists is documented by analysing imported artefacts by geochemical characterization (x-ray fluorescence analysis). The human abandonment of Henderson, by the seventeenth century, is viewed in the context of prehistoric regional dynamics.     

Colonial to modern skeletal change in the U.S.A.

Eighty-two people dating from 1675 to 1879 compared with 182 modern middle-class White and Black skeletons test the myths of radical changes produced by improved diet, less disease, and nineteenth century immigration. Longevity increases and health and growth improvement is clearest in reduced juvenile deaths (census data) and deepening of true pelvis. Stature increase is minimal (though seventeenth century Londoners and modern West Africans are shorter than Colonial to Modern Americans); teeth deteriorate and for cultural reasons fractures increase. Clavicles and forearms elongate. From Old to New World Colonial samples there is a noticeable skull change (and a greater Old World to Modern contrast) but White Colonial to Modern shows strong continuity surprisingly, the key changes being increasing head height, and retraction of face with increasing nose projection, and longer mastoids, resulting from selection and mixture. Blacks change more, possibly from Indian and White mixture. Variabilities are above average. Change is much less than expected, and apparently involves heterosis and selection as well as the obvious health advance and mixtures.     

South American mammal diversity and Hernandez’s Novae Hispaniae Thesaurus

Following the discovery of the West Indies, philosophers of the XVI and XVII centuries came into contact with a particularly unexpected fauna which was considerably different from the documented animals at that time. These animals included the Xenarthra (the sloth, and armadillo) and Marsupialia. These new discoveries occurred during a period of crisis for the traditional Aristotelian and Galenical sciences. This debate developed in two opposing directions: on the one hand towards the confirmation of the well-established tradition of Magia Naturalis, and on the other towards the Galilean Scientia Nova which encouraged people to follow a more mathematical approach when interpreting nature in all its complexity. The first reports and zoological papers of the seventeenth century express the same wonder at these discoveries as all that was “mirum et insolitum” in the typical baroque style of that time.      

Commercializing medical technology

As medicine moves into the 21st century, life saving therapies will move from inception into medical products faster if there is a better synergy between science and business. Medicine appears to have 50-year innovative cycles of education and scientific discoveries. In the 1880’s, the chemical industry in Germany was faced with the dilemma of modernization to exploit the new scientific discoveries. The solution was the spawning of novel technical colleges for training in these new chemical industries. The impact of those new employees and their groundbreaking compounds had a profound influence on medicine and medical education in Germany between 1880 and 1930. Germany dominated international science during this period and was a training center for scientists worldwide. This model of synergy between education and business was envied and admired in Europe, Asia and America. British science soon after evolved to dominate the field of science during the prewar and post World War (1930’s–1970’s) because the German scientists fled Hitler’s government. These expatriated scientists had a profound influence on the teaching and training of British scientists, which lead to advances in medicine such as antibiotics. After the Second World War, the US government wisely funded the development of the medical infrastructure that we see today. British and German scientists in medicine moved to America because of this bountiful funding for their research. These expatriated scientists helped drive these medical advances into commercialized products by the 1980’s. America has been the center of medical education and advances of biotechnology but will it continue? International scientists trained in America have started to return to Europe and Asia. These American-trained scientists and their governments are very aware of the commercial potential of biotechnology. Those governments are now more prepared to play an active role this new science. Germany, Ireland, Britain, Singapore, Taiwan and Israel are such examples of this government support for biotechnology in the 21st century. Will the US continue to maintain its domination of biotechnology in this century? Will the US education system adjust to the new dynamic of synergistic relationships between the education system, industry and government? This article will try to address these questions but also will help the reader understand who will emerge by 2015 as the leader in science and education.     

Fever theory in the seventeenth century: building toward a comprehensive physiology.

Physicians in the seventeenth century developed several theories to explain the causes and cures of fever. These theories relied heavily upon the most important physiological discovery of the period, the circulation of blood throughout the human body. In addition, physicians, increasingly emphasized careful observation of their patients'' symptoms, in order to develop empirically effective methods of treatment.     

The discovery of the body: human dissection and its cultural contexts in ancient Greece.

In the first half of the third century B.C, two Greeks, Herophilus of Chalcedon and his younger contemporary Erasistratus of Ceos, became the first and last ancient scientists to perform systematic dissections of human cadavers. In all probability, they also conducted vivisections of condemned criminals. Their anatomical and physiological discoveries were extraordinary. The uniqueness of these events presents an intriguing historical puzzle. Animals had been dissected by Aristotle in the preceding century (and partly dissected by other Greeks in earlier centuries), and, later, Galen (second century A.D.) and others again systematically dissected numerous animals. But no ancient scientists ever seem to have resumed systematic human dissection. This paper explores, first, the cultural factors--including traditional Greek attitudes to the corpse and to the skin, also as manifested in Greek sacred laws--that may have prevented systematic human dissection during almost all of Greek antiquity, from the Pre-Socratic philosopher-scientists of the sixth and fifth centuries B.C. to distinguished Greek physicians of the later Roman Empire. Second, the exceptional constellation of cultural, political, and social circumstances in early Alexandria that might have emboldened Herophilus to overcome the pressures of cultural traditions and to initiate systematic human dissection, is analyzed. Finally, the paper explores possible reasons for the mysteriously abrupt disappearance of systematic human dissection from Greek science after the death of Erasistratus and Herophilus.     

Mechanism and vitalism. A history of the controversy

This is an attempt to interpret the history of mechanism vs. vitalism in relation to the changing framework of culture and to show the interrelation between both these views and experimental science. After the scientific revolution of the seventeenth century, causal mechanism of classical physics provided the framework for the study of nature. The teleological and holistic properties of life, however, which are incompatible with this theory yielded — as a result both of internal developments within biology and of a general reaction against dogmatic rationalism — to a vitalistic interpretation of life which ascribed a mysterious force to living organisms. It will be shown that both mechanism and vitalism are related to the experimental climate of the time in which they were popular. The controversy has now lost its raison d'être as a result of the development of the theory of systems and of a better understanding of the chemistry and evolution of life.     

La formation des élites scientifiques chinoises en Europe dans la première moitié du XX siècle : l'exemple du préhistorien Pei Wen Chung

At the beginning of the XXth century a new intellectual elite appears in China. Geology, mineralogy, geography and medicine are the first profitable domains of this movement. In time of the creation of Geological Survey of China and the support of the western countries, the prehistoric archaeology is going to take advantage in this scientific revival. Having followed the educations of the big western universities, young particularly promising Chinese scholars prospect and make important discoveries. One of them, Pei Wen Chung, is so going to come to take the lessons of Abbé Henri Breuil in France, during more than two years (1935-1937) at the Institute of human palaeontology.     

The consequences of political dictatorship for Russian science

The Soviet communist regime had devastating consequences on the state of Russian twentieth century science. Country Communist leaders promoted Trofim Lysenko--an agronomist and keen supporter of the inheritance of acquired characters--and the Soviet government imposed a complete ban on the practice and teaching of genetics, which it condemned as a "bourgeois perversion". Russian science, which had previously flourished, rapidly declined, and many valuable scientific discoveries made by leading Russian geneticists were forgotten.     

The origins of medical physics

The historical origins of medical physics are traced from the first use of weighing as a means of monitoring health by Sanctorius in the early seventeenth century to the emergence of radiology, phototherapy and electrotherapy at the end of the nineteenth century. The origins of biomechanics, due to Borelli, and of medical electricity following Musschenbroek's report of the Leyden Jar, are included. Medical physics emerged as a separate academic discipline in France at the time of the Revolution, with Jean Hallé as its first professor. Physiological physics flowered in Germany during the mid-nineteenth century, led by the work of Adolf Fick. The introduction of the term medical physics into English by Neil Arnott failed to accelerate its acceptance in Britain or the USA. Contributions from Newton, Euler, Bernoulli, Nollet, Matteucci, Pelletan, Gavarret, d'Arsonval, Finsen, Röntgen and others are noted. There are many origins of medical physics, stemming from the many intersections between physics and medicine. Overall, the early nineteenth-century definition of medical physics still holds today: ‘Physics applied to the knowledge of the human body, to its preservation and to the cure of its illnesses’.     

Le peuplement humain en Eurasie : l’Asie centrale montagneuse et les piémonts sous-himalayens du Plio-Pléistocène à l’Holocène, origines, évolution humaine et migrations

During the years 1996 and 1997, a team of the Laboratory of Prehistory, National Museum of Natural History, Paris, and of the Departments of Archaeology, Karachi and Peshawar University, Pakistan, leads the first prehistoric field investigation in the District of Chitral, Hindu Kush, close to the Wakhan Corridor (the Amu Daria course in the Pamir). Problematics are the origins and the becoming of the Epipaleolithic/Neolithic hunters-gatherers known in the Pamir Plateau and the Gissar Range, the lithics tradition of which share common roots with the Sub-Himalayan Soanian tradition (Mode 1). A second field investigation has been conduced in the North West India, where Soan developed from Early Pleistocene, in the Frontal Range of the Siwaliks and Himachal Pradesh during the years 2003, 2005 and 2006 in cooperation with the Department of Archaeology and Museums of Punjab, India. New discoveries in both countries support new hypothesis for the understanding of human evolution in Asia and Homo sapiens origins.     

The ancient DNA revolution: the latest era in unearthing New Zealand’s faunal history

In the 25 years since the first DNA sequences were obtained from the extinct moa, ancient DNA analyses have significantly advanced our understanding of New Zealand's unique fauna. Here, we review how DNA extracted from ancient faunal remains has provided new insights into the evolutionary histories and phylogenetic relationships of New Zealand animals, and the impacts of human activities upon their populations. Moreover, we review how ancient DNA has played a key role in improving our ability to taxonomically identify fragmentary animal remains, determine biological function within extinct species, reconstruct past faunas and communities based on DNA preserved in sediments, resolve aspects of the ecology of extinct animals and characterising prehistoric parasite faunas. As ancient DNA analyses continue to become increasingly applied, and sequencing technologies continue to improve, the next 25 years promises to provide many more exciting new insights and discoveries about New Zealand's unique fauna.     

“艺术的外貌、科学的内涵、使命的担当”——植物园500年来的科研与社会功能变迁(二):科学的内涵

世界植物园500多年来的科研行进轨迹既是整个生物学发展史的一个缩影, 也表现出人类对植物资源发掘与利用, 使之服务于经济与社会发展的不懈追求。从16-17世纪的植物园主要研究药用植物并发掘药物, 到18-20世纪以来从植物分类学逐步拓展至众多植物学分支学科, 进一步发展到当今的植物分子生物学及基因组、代谢组学等等。植物园在长达几个世纪的发展进程中, 其科学研究内涵始终贯穿其中, 既奠定了18世纪植物分类学的根基, 也对18世纪以来许多生物学发现及其理论体系的建立作出了不可磨灭的贡献。同时, 16世纪以来跨大陆、跨地区、跨国家之间的植物引种驯化及其发掘利用与传播深刻改变了世界经济社会格局, 影响了一些国家的兴衰。在近代500多年的植物引种驯化与传播过程中, 植物园发挥了引领作用。本文试图对植物园500年来的科学研究轨迹进行梳理, 展望当今植物园在植物宏观与微观生物学及其大数据时代相关研究领域的发展趋势, 为我国植物园的科研方向提供可借鉴的参考。     

Empiric physiology in epidemiologic doctrines of the 18th century, Hungarian General Norm of Health in 1770

According to standard textbooks, the last episode of European New Age plague pandemic died out by 1720 in Marseilles. Despite this allegation, the pandemic continued in well-documented new outbreaks, which attacked and devastated Central and Eastern Europe throughout the first half of the 18th century. At the beginning, military campaigns spread the infection out of the Ottoman Empire. Later on commercial goods took over this role via land or sea from Asia or out of the eastern Mediterranean region. Finally, the plague in Europe--except Russia and the Ottoman Empire--"died out" virtually by the end of the 18th century. Explaining this, there many scientific reasons were suggested: 1. Oriental rat fleas as main vectors of infection could not tolerate any more the European weather conditions (although there were no virtual climate changes in the last 300 years). 2. Black rats that lived in close proximity to man, were being outplayed by brown rats living rather outside of human habitats; 3. There emerged less virulent Yersinia strains that caused natural human immunisation. In spite of these suggestions, which may have contributed to the success, joint civil and military health authorities blocked the plague indeed, as a result of disciplined and relentless law enforcement. In Hungary, respectively in the Hapsburg Empire, well-advised health legislation backed up the effectiveness of local authorities. Following the last great devastation in 1738-1740, the General Norm of Health Service--a voluminous decree--summed up by 1770 all the time honoured empiric rules of foregoing centuries. It can be excellently demonstrated, how exactly the empiric rules discovered a century later met scientific facts of physiology and microbiology.     

Forensic Medicine: An Aid to Criminal Investigation

Forensic medicine is medicine as applied to the problems of the law. The origins of both are hidden in the mists of antiquity, dating from the beginnings of family and tribal life. Recorded human history goes back for 6000 years. Sumeria, Babylon and Egypt all contributed to the development of forensic medicine. Imhotep was probably the first real medicolegal expert. Hippocrates, the Greek physician, and Galen, the Roman, made considerable contributions. Little advance was made during the millenium of the Dark Ages. But Renaissance medicine gave this branch of medicine an impetus in the seventeenth, eighteenth and nineteenth centuries, and in the twentieth, interest in forensic medicine is worldwide. The physician, the coroner, the pathologist, the medical specialist and the forensic laboratory contribute to the investigation of crimes against the person, and to the solution of such problems as identification, untoward deaths, apparent drowning and many others.