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Post by skytroll on Aug 17, 2008 9:31:47 GMT -5
Examine this description of this finding, years back. This relates to pebrine, cholera, globigerina, all related to the ........? SEA MONKEY? Artemia Salina, the Sea monkey, the brine, the stuff that makes chalk? ...... takes us right back to Bechamp and Pasteur. Pasteur was appointed by the French Govt. to study this. Bechamp already knew what it was. Koch comes in with the b. anthrax. It has been called many things, but check out the picture of it. www.captain.at/artemia-gallery.phpnow, it has been called globigerina? globigerina and chalk: "GREY GOO"? how the nano building block works? If globigerina helps form chalk, there you have it. GLOBIGERINA, A. d'Orbigny, a genus of Perforate Foraminifera of pelagic habit, and formed of a conical spiral aggregate of spheroidal chambers with a crescentic mouth. The shells accumulate at the bottom of moderately deep seas to form "Globigerina ooze" and are preserved thus in the chalk. Hastigerina only differs in the "flat" or nautiloid spiral. Is this what is in the Dead Sea and the Great Salt Lake Desert? Do you get my drift? www.1911encyclopedia.org/GlobigerinaSkytroll
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Post by skytroll on Aug 17, 2008 9:43:06 GMT -5
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Post by skytroll on Aug 17, 2008 9:49:35 GMT -5
Note the description of this and how relates to Morgellons description: Parasites in the BLOOD: pages 4 and 5: tinyurl.com/6fpauwbooks.google.com/books?id=ZuGqboLtvk4C&pg=PA4&lpg=PA4&dq=pebrine+cholera&source=web&ots= TxHPJS5U5y&sig=zQP62zIV_hcZmRE916Ikt-mY-Tg&hl=en&sa= X&oi=book_result&resnum=1&ct=result#PPA4,M1 Skytroll
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Post by skytroll on Aug 17, 2008 10:34:32 GMT -5
Hemozoia? nsdl.org/resource/2200/20070624011804803TShould there be rivers in the land, which drain off from the ground the stagnant water and the rain water, the people will be healthy and bright. But if there be no rivers, and the water that the people drink to be marshy, stagnant, and fenny, the physique of the people must show protruding bellies and enlarged spleens.” Hippocrates Airs, Waters, and Places The above inscription is the first known record accurately describing aspects of the epidemiology of malaria, as well as presenting a few salient clinical features of the acute disease. Hippocrates observed and wrote about the three kinds of periodic fevers and chills associated with the synchronous forms of malaria. Today, physicians not only recite the Hippocratic Oath upon graduating from medical schools around the world, but they still refer to the fevers caused by malaria in a similar fashion. The word malaria is Latin, and means “bad air.” This lone infectious disease has been a perennial cause of human suffering and mortality, mainly throughout the tropical and sub-tropical regions of Africa, Asia, and South and Central America. According to the World Health Organization, more than 300 million diagnosed cases and 2 million deaths occur yearly. This represents a gross under-estimation of the problem, since millions more will most likely acquire the infection each year without ever realizing it. There are over 400 species of the malarial parasite (Plasmodium spp.), many of which infect a wide variety of cold-and-warm-blooded animals, only four routinely infect humans. Each one of the latter is transmitted by the bite of an infected female Anopheles spp. mosquito. It follows then, that ecological alterations favoring the spread of these insects also facilitate the spread of the infection wherever malaria occurs. To get some idea of the complexity of the ecological differences among the numerous malaria endemic zones, one must consider at least four different, yet related, aspects: the host, the insect vectors, the parasites, and the physical conditions under which transmission occurs. Integration of these seemingly disparate subject areas into a unified view with respect to geographic locale is essential to begin identifying environmental factors that might be taken advantage of for the purpose of controlling the spread of the parasite. 2 Early History [Back to Outline of Sections] As mentioned, the Greeks were the first to write about malaria. Even earlier, the Egyptians made numerous references to it in their hieroglyphs. However, it wasn’t until late in the 18th century that serious inroads into its etiology were made. Laveran, working on bird malaria in north Africa, is given credit for first observing the living parasite inside red blood cells, yet his most exciting discovery was in microscopically observing the development of male sex cells of the parasite, referred to as exflagellation, in a drop of infected bird blood. These important findings earned for him a Nobel Prize in medicine. Yuri Romanovsky, working in Russia, independently developed the stains needed to clearly identify the parasites in blood smears, allowing anyone with the interest and a microscope to become involved in malaria research. In 1897-1898, Ronald Ross, a future Nobel laureate, discovered during his work in India that female culicine mosquitoes were the transmitters and definitive hosts for bird malaria (i.e., they harbored the sexual stages of the parasite). Ross demonstrated how transmission of the parasite occurred by successfully infecting twenty-one out of twenty-eight healthy sparrows and other passerine birds employing mosquitoes that had previously fed on infected birds. He found the parasites in the stomach of the infected mosquitoes, and shortly thereafter discovered the sporozites (the infective stage) in their salivary glands. Ross speculated, based upon his fundamental findings, that a single experiment using red cells taken from patients infected with Plasmodium falciparum and dapple-winged, anophelene mosquitoes would establish the existence of a similar cycle for human malaria. Grassi, Bignami, and Bastianelli, working in Italy, used human volunteers and confirmed Ross’s suspicions, and published their findings in a series of seminal papers in 1898 and 1899. 3 The Plasmodia [Back to Outline of Sections] Malaria is caused by a protozoan belonging to the genus Plasmodium. Although there are over 400 species, four routinely cause disease in humans: Plasmodium falciparum, P. vivax, P. ovale, and P. malariae. While they all belong to the same genus, each species behaves quite differently in most aspects of their biology within the human and mosquito host. They also vary with respect to geographic distribution. P. falciparum is found in most tropical regions throughout the world, and is the most dangerous of the four in terms of both its lethality and morbidity. Relapses cannot occur with this species. In contrast, relapses due to P. vivax can routinely occur due to a latency period, during which time the parasites in the infected hepatocytes remain dormant. The longevity of relapse is apparently dependent on the particular geographical region in which the organism is found. P. vivax is prevalent in many sub-tropical zones, as well as in the tropics. P. ovale is similar to P. vivax in its biology, but is found primarily in West Africa. 3.1 This plasmodium drifts off into malaria: www.medicalecology.org/diseases/malaria/malaria.htmnow do these relate to the pebrine? they may.? Protozoaires Les Rhizopodes www.cosmovisions.com/rhizopodes.htmtinyurl.com/6hbsssimages.google.com/images?ie=UTF-8&oe=utf-8&q=pebrine%20and%20plasmodium&um=1&sa=N&tab=wi Skytroll
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