Difference between revisions of "Urine analisis/MICROSCOPY"

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==== making wet mount for a mycroscope ====
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==== making wet mount for a microscope ====
  
 
https://www.youtube.com/watch?feature=player_embedded&v=qSsMe_OXv-0
 
https://www.youtube.com/watch?feature=player_embedded&v=qSsMe_OXv-0
  
  
====Cellular Microscopy: The Science of Blood Cells
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====Cellular Microscopy: The Science of '''Blood Cells'''====
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[https://backyardbrains.com/experiments/bloodcells]
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==A  Summary Study of Blood== [http://www.microscopy-uk.org.uk/mag/indexmag.html?http://www.microscopy-uk.org.uk/mag/articles/blood1.html]
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Introduction
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Perhaps one of the most evocative signs of sudden ill health or damage to the human body is the sight of red streams flowing from a fresh skin cut. Yet this very action, as we shall learn in a moment is just part of the body's many defence mechanisms. In this article, we shall look at key aspects of normal healthy human blood, and with the aid of small images, learn how to identify a few of the more serious diseases of the blood system.
 +
 
 +
Although a serious topic of study, this short article is intended for both students of Biology and general public interest. It is designed to be fairly light and easy to read without the reader requiring previous in-depth knowledge of Biology.
 +
 
 +
White Blood Cells (leucocytes)
 +
 
 +
Several different types of white blood cells can be found between the red cells and platelets. In the following images these have all been stained artificially dark blue or purple. They are larger than erythrocytes (red blood cells) but populate the blood system in much less denser quantities, typically 7000 cells per cubic millimetre of blood. Their function is to help protect the body from disease and infection. Unlike red cells, they are all nucleated (contain nuclei), yet despite this, live for only a few days in the bloodstream. White cells can be classified as belonging to 2 main groups - agranulocytes and the granulocytes. Several types from these two groups are described below.
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[https://backyardbrains.com/experiments/bloodcells]
 
 
====  Part G : Laboratory Methods and Materials  ====
 
====  Part G : Laboratory Methods and Materials  ====
 
[https://www.phys.ksu.edu/gene/g1a.htm]
 
[https://www.phys.ksu.edu/gene/g1a.htm]

Revision as of 02:36, 5 May 2015


Red blood cells can be seen well at 400x magnification as long as the microscope is of reasonable quality


http://www.hometrainingtools.com/microscope-slide-sets/c/151/


Experiments and ways to see things through the microscope

Observing bacteria under the light microscope

Why bacteria are difficult to see

Can one see bacteria using a compound microscope? The answer is a careful “yes, but”. Generally speaking, it is theoretically and practically possible to see living and unstained bacteria with compound light microscopes, including those microscopes which are used for educational purposes in schools. There are several issues to consider, however.


Bacteria are difficult to see with a bright-field compound microscope for several reasons:

   They are small: In order to see their shape, it is necessary to use a magnification of about 400x to 1000x. The optics must be good in order to resolve them properly at this magnification.
   Difficult to focus: At a high magnification, the bacterial cells will float in and out of focus, especially if the layer of water between the cover glass and the slide is too thick.
   They are transparent: Bacteria will show their color only if they are present in a colony. Individual cells present on the slide are clear. Regular bright-field optics will only show the bacteria if one closes the condenser iris diaphragm. This is due to the difference in the refractive index between the water and the bacterial cells.
   Difficult to recognize: An untrained eye may have problems differentiating bacteria from small dust and dirt which is present on the slide. Some bacteria also form clumps and therefore it is difficult to see the individual cells.

Research organizations and advances amateurs use phase contrast optics to see bacteria. This system converts the differences of the refractive index of the bacteria into brightness. The transparent bacteria can then be seen dark on bright background. In bright-field, closing the condenser iris diaphragm will also make the bacteria appear darker, but at the same time one also introduces artifacts (“fringes”) around the individual cells. One possibility is to stain the bacteria, but in this case there fixing and staining process may introduce artifacts.

What is a safe source of bacteria? For recreational or educational purposes, one should never use spoiled food or (heaven forbid!) use bacteria obtained from the human body and grown on agar plates. The risks involved are simply not worth it, especially when working with students. Other sources, such as soil or humus have other disadvantages. The impurities make it difficult to keep bacteria from other particles apart, especially if one uses bright-field optics. Rather I recommend the use of yogurt. It should be possible to see small circular cells (cocci), which may also occur in pairs. It is also possible to scratch some bacterial cells off from certain kinds of cheese. Brevibacterium can be found on Limburger cheese, for example. One has to be aware that some cheeses use a combination of bacteria and fungi, however, and that the larger fungal cells may outweigh the bacteria.

In summary, there are easier (and maybe also more interesting) specimens to observe than bacteria. I you want to see individual cells, then I do recommend that you start out with yeast suspensions. These eukaryotic cells are much larger and can be more easily identified.

For pictures of bacteria in phase contrast read the following post: Bacteria in phase contrast


making wet mount for a microscope

https://www.youtube.com/watch?feature=player_embedded&v=qSsMe_OXv-0


Cellular Microscopy: The Science of Blood Cells

[1]

==A Summary Study of Blood== [2]

Introduction

Perhaps one of the most evocative signs of sudden ill health or damage to the human body is the sight of red streams flowing from a fresh skin cut. Yet this very action, as we shall learn in a moment is just part of the body's many defence mechanisms. In this article, we shall look at key aspects of normal healthy human blood, and with the aid of small images, learn how to identify a few of the more serious diseases of the blood system.

Although a serious topic of study, this short article is intended for both students of Biology and general public interest. It is designed to be fairly light and easy to read without the reader requiring previous in-depth knowledge of Biology.

White Blood Cells (leucocytes)

Several different types of white blood cells can be found between the red cells and platelets. In the following images these have all been stained artificially dark blue or purple. They are larger than erythrocytes (red blood cells) but populate the blood system in much less denser quantities, typically 7000 cells per cubic millimetre of blood. Their function is to help protect the body from disease and infection. Unlike red cells, they are all nucleated (contain nuclei), yet despite this, live for only a few days in the bloodstream. White cells can be classified as belonging to 2 main groups - agranulocytes and the granulocytes. Several types from these two groups are described below.



Part G : Laboratory Methods and Materials

[3]

Laboratory Methods A. Sterile Techniques B. Growth Media C. Incubation Temperature and Growth Rates D. Using Toothpicks and Inoculating Loops E. Spreading Cells F. Pipets and Pipetting G. Subculturing Yeast H. Isolating Single Colonies I. Replica Plating J. Estimating the Number of Yeast Cells in a Culture K. Dilution and Plating Procedures L. Microscopic Examination of Yeast M.Yeast Strains N. Irradiating Yeast With Ultraviolet Radiation


super nice hack :

http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0098781



dreaming with have one of this ones

http://www.amazon.com/AmScope-B100B-E-Magnification-Brightfield-Illumination/dp/B007LBLTU6/ref=sr_1_34?s=industrial&ie=UTF8&qid=1430778994&sr=1-34&keywords=Binocular+Compound+Microscope

http://bestcompoundmicroscopes.com/ http://www.amazon.com/gp/product/B005TJ5CEG/ref=as_li_qf_sp_asin_il_tl?ie=UTF8&camp=1789&creative=9325&creativeASIN=B005TJ5CEG&linkCode=as2&tag=bestcompoundmicroscopes-20

http://www.amazon.com/gp/product/B004QEFO1Q/ref=as_li_qf_sp_asin_il_tl?ie=UTF8&camp=1789&creative=9325&creativeASIN=B004QEFO1Q&linkCode=as2&tag=bestcompoundmicroscopes-20


http://www.amazon.com/gp/product/B009N3QV44/ref=as_li_qf_sp_asin_il_tl?ie=UTF8&camp=1789&creative=9325&creativeASIN=B009N3QV44&linkCode=as2&tag=bestcompoundmicroscopes-20

Do-it-yourself guide: How to use the modern single molecule toolkit http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2574008/



An exploration of your house in close-up . Studying motion

http://www.microscopy-uk.org.uk/dww/home/hombrown.htm


What you need:

A compound microscope capable of 200X or 400X magnification. Clean slides and coverslips. Distilled water (the water collected from the ice box when defrosting the fridge is an acceptable substitute). One or more of: talcum powder, pasteurised milk.