RFMG8Y2E–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RFM1XTA1–Paramecium caudatum on the leaf background
RF2WJD200–Paramecium Caudatum flat vector icon. Simple solid symbol isolated on white background
RMRHKAK0–. Biology. Biology. 60 ORGANISMS OF ONE CELL TfflCHOCYSTS GASTfVC VACUOL£. C. A CILIATED PROTOZOON, PARAMECIUM CAUDATUM An infusion of vegetable or animal matter becomes the feed- ing ground not only of bacteria and flagellated protozoa, but also, after some considerable time, of ciliated protozoa as well. Prom the fact that all of these organisms appear in such infu- sions, the term Infusoria was formerly employed to designate all of them indis- criminately. The bacteria were first recognized as having no systematic rela- tion to the other forms, and were separated in classification from the
RFR5557R–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background
RFEHGNTH–animal conjugation of Paramecium caudatum
RFF3AW6M–Paramecium caudatum
RM2CDN8YA–Paramecium caudatum
RM2EM3MFW–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x80 related to 35mm, Germany
RM2CDPDN6–model biological micro organism paramecium caudatum 3d illustration
RFCWT15Y–microscopy micrograph animal, conjugation of Paramecium caudatum, magnification 200X
RF2K4Y0WM–Amoeba, protozoa and unicellular protist cells, vector euglena bacteria or paramecium organism. Protozoan microorganism, bacterium fission and binary protista amoeba of chlamydomonas microbiology
RFRKFMYB–Colorful sketch of Infusoria. Vector illustration EPS 10
RF2T306D1–Cell division, scientific animation of mitosis. Motion. Abstract visualization of cells motion, concept of biology.
RFHXFHYA–Infusorium icon, gray monochrome style
RFGJHY79–culture cells microscope
RFGJHY7B–culture cells microscope
RFM1XTD8–Paramecium caudatum on the leaf background
RFGJHY75–culture cells microscope
RFMG8Y4F–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RFR55588–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background
RFKRJ0X8–Paramecium caudatum
RFGJW82T–model biological micro organism paramecium caudatum 3d illustration
RM2AWTME2–The microscope and its revelations . Fig. 194 Kerona silurus:—a, contractile cavity; h, mouth; c, c,animalcules swallowed by the Kerona, after having themselves in-gested particles of indigo. Fig. 195. Paramecium caudatum:—a a, contractile cavities;b, mouth. immediate dcinity of the mouth (Kg. 196), is the means byfar the most frequently employed by the beings of this class,both for progression through the water, and for drawingahmentary particles into the interior of their bodies. In sometheir vibration is constant, whilst in others it is only occasional,thus conveying the impression that th
RM2EM3MFC–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x100 related to 35mm, Germany
RM2CDPDRH–model biological micro organism paramecium caudatum 3d illustration
RF2T3088N–Cell division, scientific animation of mitosis. Motion. Abstract visualization of cells motion, concept of biology.
RFM1XTCH–Paramecium caudatum on the leaf background
RFMG8Y0H–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RFR5557K–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background
RFKRJ115–model biological micro organism paramecium caudatum 3d illustration
RM2ANDNH6–The Journal of experimental zoology . 2° C. 43 — 8 per cent or 35 per cent of thedeaths occurred and this is marked on an ordinate halfwaybetween 41° and 42°. At a temperature between 42° and 43°C.100 — 43 per cent or 57 per cent of the deaths occurred. Thisnumber 57 is represented on an ordinate halfway between 42°and 43°. Lines drawn connecting these points give the curve forSpirostomum shown in figure 1. The curves for the other formsare constructed in the same manner. Of these six species Paramecium caudatum is seen to be themost variable. The animals experimented with were taken fromsever
RM2EM3MTN–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x100 related to 35mm, Germany
RF2K50NG6–Protozoa, protista and amoeba microorganism cells, vector micro organism. Ameba and protist unicellular cells in lab microscope, protozoan eukaryotic organism types
RFMG8Y3R–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RFR55587–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background
RFKRJ119–model biological micro organism paramecium caudatum 3d illustration
RF2GPFY4B–Infusorium icon, gray monochrome style
RM2EM3MFD–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x100 related to 35mm, Germany
RM2ANDN4E–The Journal of experimental zoology . he end of the two months while Races 1 and 6 main-tained themselves a few weeks longer. Although Race 5, underthe influence of some unknown condition, disappeared muchsooner than the others, yet its resistance during its early healthyperiod of rapid development was just the same as that duringthe later period of depression. For example^ one experiment on TABLE 7• Paramecium, caudatum Pure line no. 1 TEMPERATURE 37° 38° 39° 40° 41° Totals 37000 6883ca.0.5 618103 545375 480 Number of deaths 480 Percentage dead at given temperature 16.6 68.9 100 TABLE 8 Param
RFJ5W4HE–paramecium under the microscope
RMHRF66K–Paramecium Caudatum
RFMG8Y4R–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RM2EM3MKM–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x80 related to 35mm, Germany
RM2ANDMB2–The Journal of experimental zoology . he end of the two months while Races 1 and 6 main-tained themselves a few weeks longer. Although Race 5, underthe influence of some unknown condition, disappeared muchsooner than the others, yet its resistance during its early healthyperiod of rapid development was just the same as that duringthe later period of depression. For example^ one experiment on TABLE 7• Paramecium, caudatum Pure line no. 1 TEMPERATURE 37° 38° 39° 40° 41° Totals 37000 6883ca.0.5 618103 545375 480 Number of deaths 480 Percentage dead at given temperature 16.6 68.9 100 TABLE 8 Param
RFJ5W4HK–paramecium under the microscope
RMHRF6YP–Protozoa, Paramecium caudatum, LM
RFMG8Y2D–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RM2EM3KJJ–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x120 related to 35mm, Germany
RM2CE27X3–. Biology . new contractilevacuoles are formed by the daughter cells which separate andbegin an independent existence. The entire process requiresfrom half an hour to two hours according to the temperature. Irritability.—Like A moeba proteus again, Paramecium respondsto external stimuli, but having definite motile organs its re-sponses are more definite and more easily studied. It answers PARAMECIUM CAUDATUM 65 to all sudden stimuli by a definite reaction termed a motorresponse. It backs away by reversal of its ciliary action, thenturns on its axis and moves forward again. If the offendingobje
RMHRH54N–LM of Paramecium caudatum in cell division
RFMG8Y1C–Paramecium caudatum under the microscope - Abstract shapes in color of green, red, orange and brown on white background.
RM2EM3KWT–slipper animalcules (Paramecium caudatum), phase-contrast MRI image, magnification x80 related to 35mm, Germany
RMRHK1FW–. The biology of the protozoa. Protozoa; Protozoa. Fig. 145.—Paramecium caudatum in a period of depression and recovery by treat- ment with salts. (After Calkins, i concludes, that the environment is so stabilized that its stimuli do not call out the cyclical changes which might be expected with an irritable and adaptable protoplasmic organization. If, however, reorganization as effected by division does not leave the protoplasm in its original labile condition, then inter-divisional activity of the progeny starts with a different organization than did the previous generation and this, continu