Course Content
Laboratory Design and Layout
In this topic. we will; 1.Discuss the importance of laboratory design and layout. 2.Describe standards for a good science laboratory. 3.Describe the essential features of a prep room and a laboratory store. 4.Describe the basic laboratory services
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Laboratory Safety and Housekeeping
Objectives To highlight the importance of laboratory housekeeping practices and how its proper integration into laboratory management can: 1.Create order and good organization 2.Increase safety 3.Increase efficiency 4.In this chapter, we will discuss 5.The importance of laboratory housekeeping 6.Ways of enhancing good laboratory housekeeping practices
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Personal Protective Equipments
OBJECTIVES The objective of this topic is to highlight the importance of protective equipment’s and how its proper integration into laboratory management can to reduce: 1.Injury and deaths to laboratory users 2.Contamination of laboratory reagents and specimens  In this chapter, we will 1.Discuss the importance of laboratory protective equipment. 2.Describe the various types of laboratory protective equipment 3.Describe how to use laboratory protective equipment’s. 4.Describe how to care for laboratory protective equipment’s
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Laboratory Hazards
OBJECTIVES The objective of this chapter is to highlight the importance of laboratory hazards, how to identify and get rid (or minimize) of them from the laboratory. In this chapter, we will 1.Describe the various types of laboratory hazards and. 2.Describe causes of laboratory hazards 3.Describe the general ways to avoid laboratory hazards.
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First Aid
OBJECTIVES The objective of this chapter is to prepare you as a first aider, psychologically and emotionally, as well as by giving practical advice on what you should and should not do in a laboratory emergency. After studying the material in this chapter, you will be able to: 1.Define first aid 2.Recognize the reasons why first aid is given 3.Manage an emergency situation safely 4.Assess the sick or injured persons. 5.Identify general directions for giving first aid
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Laboratory Apparatus
This topic focuses on the importance of handling, care and cleaning of laboratory wares. In this chapter, we will 1.Classify the various laboratory wares. 2.Discuss use of various laboratory wares 3.Describe various cleaning methods for various laboratory stains 4.Describe the various laboratory cleaning agents
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Laboratory Cleaning
OBJECTIVES The objective of this topic is to learn the importance of ensuring general and overall cleanness of laboratory items and surfaces. In this chapter, we will: 1.Discuss the various types of dirt and stains. 2.Discuss the general methods of cleaning laboratory apparatus and surfaces. 3.Describe various types cleaning agents used for cleaning laboratory items. 4.Outline preparation of laboratory cleaning agents. 5.Discuss various methods used in sterilization and disinfections of laboratory items.
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Sterilization Techniques
Sterilization, also called biological cleaning is a bit more involving than chemical cleaning. This is because it involves total killing of microorganism’s present on the apparatus. There are two methods used in sterilization. 1.Physical methods 2.Chemical methods
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Laboratory Waste Management
OBJECTIVES This chapter presents methods for the management and ultimate disposal of laboratory waste that may present as hazards. The objectives of these chapter are b.To identify types of laboratory wastes c.To identify sources of laboratory wastes d.To describe methods of managing laboratory wastes
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Laboratory Chemicals and Reagents
OBJECTIVES The objectives of this chapter are to learn the importance of proper handling, preparation, storage and disposal of laboratory chemicals and reagents. In this chapter, we will 1.Discuss the various categories of laboratory reagents. 2.Discuss the general storage guidelines for laboratory chemicals. 3.Describe in details the various methods of handling, storage, and disposal of laboratory chemicals. 4.Discuss how to segregate non compatible laboratory chemicals. 5.Discuss the basic terms and concepts of preparing Solutions. 6.Describe how to prepare various laboratory reagents and solutions
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Laboratory Solution Preparation
OBJECTIVES The objectives of these topic are: 1.To define terms used in solution preparation 2.To prepare various concentrations of solutions 3.To prepare bench reagents
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Laboratory Equipments
OBJECTIVES The objective of this chapter are to give a better understanding of the technical requirements regarding installation, use and maintenance of various types of equipment which play an important role in performing laboratory tests. In this chapter, we will 1.Identify the various types of laboratory equipment’s 2.Discuss the use of the equipments. 3. Describe the components of the equipments. 4.Discuss the operational mechanisms of the equipments 5.Outline the general care and maintenance for the equipments
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Laboratory Animals
OBJECTIVES The objective of this chapter is to give a better understanding of the technical requirements regarding handling, care and maintained of various laboratory animals In this chapter, we will; 1. Identify the various types of laboratory animals. 2.Discuss the general care and handling of laboratory animals. 3. Describe the various methods of restraining and humane killing laboratory animals 4.Discuss care of specific disease free (SPF)and Gnotobiotic animals
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Cryogenic Technology
Cryogens are substances (liquids or fluids) usually at very extreme low temperatures (below –150 °C, –238 °F or 123 K). Cryogenic technology can be defined as the study of the production of low temperature fluids, measurements at low temperatures, and behavior of these materials at low temperature and how to produce them. It is also concerned with the application of low temperature processes and techniques
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Glass Blowing Technology
OBJECTIVES In this chapter, we will 1.Define the term glassblowing 2.Discuss importance of glassblowing in the laboratory 3.Describe composition and properties of glass used for glassblowing 4.Describe various tools used for glassblowing 5.Describe glass blowing techniques used in making simple glass apparatus 6.Discuss various conditions encountered in glass blowing 7.Discuss how to correct conditions encountered in glass blowing
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Vacuum Technology
OBJECTIVES In this chapter, we will 1.Define the term vacuum and degrees of vacuum 2.Discuss types of vacuum system 3.Describe how vacuum is created 4.Describe various types of vacuum pumps 5.Describe instruments for measuring vacuums 6.Discuss leaks and leaks detection in vacuum systems 7.Discuss materials used in vacuum system construction 8.Discuss vacuum cleaning techniques 9.Discuss applications of vacuums
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Photographic Technology
Photography simply means writing, drawing or printing with light. Light is therefore most fundamental in photography because without it then no photographs will be produced. Light is a form of energy, it’s a source of all colors and its composed of different wavelengths, those that are of importance in photography are those that fall within the visible region of the electromagnetic spectra because they can be perceived by the human eye. These are composed of different colors e.g. red, blue green yellow orange etc.
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Laboratory Inventory Management
OBJECTIVES The objective of this chapter is to give a better understanding of good inventory management practices . In this chapter, we will: 1.Describe the importance of good laboratory stock management practices 2.Define the various terms used in inventory management 3.Discuss ways to monitor, control and record laboratory stock
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Laboratory Inspection
The laboratory inspection is the safety audit of the conditions and operations that occur on a daily basis in a specific laboratory. Laboratory inspections are conducted at least annually to ensure safety and compliance with all applicable lab safety regulations and guidelines. These inspections are also intended to provide a formal opportunity for laboratory personnel to ask questions regarding any aspect of lab safety in order to improve overall compliance. Laboratory inspectors need to have a greater understanding of safe laboratory operations. The lab inspector needs a higher level of laboratory safety training to be able to recognize problem areas and be able to ask questions and eliminate the hazards.
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Laboratory Management
The objectives of this topic are to; 1.Describe what management is. 2.Explain the primary functions of management. 3.Describe the primary types of managers and the roles they play.
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Principles of Laboratory Management
OBJECTIVES The objectives of this topic are to; 1.Describe what management is. 2.Explain the primary functions of management. 3.Describe the primary types of managers and the roles they play.
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Schools and Theories of Management
The objectives of this topic are 1. To understand the way in which management thought has evolved in the West since 1900; 2. To appreciate how these 'theories' may be applied today; 3. To compare and contrast the various theories presented
0/7
Management Functions
OBJECTIVES 1. To describe the process of management's five functions: planning, organizing, staffing. leading, and controlling.
0/6
Delegation
Delegation is the process by which managers assign a portion of their total workload to others. It includes assigning formal authority and responsibility for completion of specific activities.
0/4
Line and Staff Relationship
The line and staff relationship is a form of organizational structure that exists in many companies. It refers to the relationship between line departments (also known as line units) and staff departments (also known as staff units).
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Centralization and Decentralization
This refers to the extent to which decision-making power and authority is dispersed to lower levels. It also refers to the degree of delegation of duties, power and authority to lower levels of an organization.
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Span of Control
Span of control management refers to the number of subordinates who report directly to a given superior.
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Leadership
Leadership is an important aspect of management and the ability to lead is one of the keys to being an effective manager. Leadership is the art or process of influencing people so that they will strive willingly and enthusiastically toward achievement of group goals. Effective leaders must be able to influence the thoughts and behavior of others towards the accomplishment of some goals or goal.
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Motivation
One of the most important functions of management is to create willingness amongst the employees to perform in the best of their abilities. Therefore the role of a leader is to arouse interest in performance of employees in their jobs through motivating them to act in the desired direction.
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Effective Communication
Effective communication is a process of exchanging ideas, thoughts, knowledge and information such that the purpose or intention is fulfilled in the best possible manner.
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Management Styles
OBJECTIVES The objectives of these topic are 1.Define the various types of management styles. 2.To discuss pros and cons of management styles. 3. Explain how we can determine which style to use in a variety of situations.
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Labor Laws and Industrial Relationships
Labor laws refers to rules and regulations are put in place to govern the working relationship and protect the rights of employers and workers by clearly stipulating the obligations and responsibilities of each party to the employment. They are enforced by the Kenyan government agencies to ensure that there is harmony in the workplace
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Woodwork Workshop Practice
Woodwork, also known as woodworking, is the craft or skill of creating objects or structures from wood using various tools and techniques. Woodwork encompasses a wide range of activities, from simple woodworking projects to complex furniture making and carpentry. It combines both practical skills and creativity to transform raw wood into functional or decorative items.
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Metalwork Workshop Practice
Metalwork refers to the craft or skill of working with metal to create objects, structures, or components. It involves various processes, techniques, and tools to shape, manipulate, and join metal materials.
0/5
Plastics
Plastics are a group of synthetic materials made from polymers, which are large molecules composed of repeating subunits called monomers. Plastics have a wide range of applications due to their versatility, durability, lightweight nature, and ability to be molded into various shapes.
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Laboratory Practice and Management
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Microscopes

Microscopes are among the most expensive items in the laboratory. They are used for magnifying. There are many types of microscopes each suited for a specific purpose. They include,

  1. Light or optical microscope
  2. Electron microscope
  3. Phase contrast microscope  
  4. Fluorescent microscope
  5. UV microscope
  6. Dark ground illumination microscope
    • THE LIGHT MICROSCOPE

Light microscopes were invented in the 17th century. They operate by allowing light rays from a light source beneath the stage to be transmitted through the eye piece lens and objective lens. Depending on their strength, these two lenses can routinely provide a magnification of over X400.

The light microscope has had profound influence in microbiology and cell biology, however, they have a limit in the amount of details they can show. This limit is set by its resolving power. The resolving power is the minimum distance by which two points must be separate for them to be perceived  as two separate points  rather than a single fused point .For light   microscope these image should be 2 μm apart .The limited resolution of light microscope  is imposed  by the wavelength of the visible light .

These put a limit in the amount of structural details that can be detected within the cell. Higher magnification can be achieved by using a sppecial objective lens with a fluid i.e. oil emersion, placed between the lenses. But even then it is not possible to achieve magnification of 2000

 Types of light microscopes

  1. Monocular microscopes
  2. Binocular microscopes

Monocular microscopes are those microscopes having one eye piece lens fixed to the microscope. They include:

  • The standard microscope

This is the ordinary common light microscope. Its stage is not permanently fixed and it can be inclined or and it’s movable.

  • Fixed Inclined Limb Microscope

The stage is maintained in a horizontal plane and the body tube is inclined towards the user, in some models, the rotation of the body tube in a horizontal plane is possible. These may be useful in teaching as the teacher can share the instrument with students without moving or exchanging places with students.

STRUCTURAL COMPONENTS OF MICROSCOPES

The three basic, structural components of a compound microscope are the head, base and arm.

  • Head/Bodyhouses the optical parts in the upper part of the microscope
  • Base of the microscope supports the microscope and houses the illuminator
  • Armconnects to the base and supports the microscope head. It is also used to carry the microscope.

When carrying a compound microscope always take care to lift it by both the arm and base, simultaneously.

OPTICAL COMPONENTS OF MICROSCOPES

There are two optical systems in a compound microscope: Eyepiece Lenses and Objective Lenses:

Eyepiece or Ocular is what you look through at the top of the microscope. Typically, standard eyepieces have a magnifying power of 10 xs. Optional eyepieces of varying powers are available, typically from 5x-30x. 

Eyepiece Tube holds the eyepieces in place above the objective lens. Binocular microscope heads typically incorporate a diopter adjustment ring that allows for the possible inconsistencies of our eyesight in one or both eyes. The monocular (single eye usage) microscope does not need a diopter. Binocular microscopes also swivel (Interpupillary Adjustment) to allow for different distances between the eyes of different individuals.

Objective Lenses are the primary optical lenses on a microscope. They range from 4x-100x and typically, include, three, four or five on lens on most microscopes. Objectives can be forward or rear-facing.

Nosepiece houses the objectives. The objectives are exposed and are mounted on a rotating turret so that different objectives can be conveniently selected. Standard objectives include 4x, 10x, 40x and 100x although different power objectives are available.

Coarse and Fine Focus knobs are used to focus the microscope. Increasingly, they are coaxial knobs – that is to say they are built on the same axis with the fine focus knob on the outside. Coaxial focus knobs are more convenient, the viewer does not have to grope for a different knob.

Stage is where the specimen to be viewed is placed. A mechanical stage is used when working at higher magnifications where delicate movements of the specimen slide are required.

Stage Clips are used when there is no mechanical stage. The viewer is required to move the slide manually to view different sections of the specimen.

Aperture is the hole in the stage through which the base (transmitted) light reaches the stage.

Illuminator is the light source for a microscope, typically located in the base of the microscope. Most light microscopes use low voltage, halogen bulbs with continuous variable lighting control located within the base.

Condenser is used to collect and focus the light from the illuminator on to the specimen. It is located under the stage often in conjunction with an iris diaphragm.

Iris Diaphragm controls the amount of light reaching the specimen. It is located above the condenser and below the stage. Most high quality microscopes include an Abbe condenser with an iris diaphragm. Combined, they control both the focus and quantity of light applied to the specimen.

Condenser Focus Knob moves the condenser up or down to control the lighting focus on the specimen.

Magnification and resolving power of a light microscopes

Magnification is simply the ability to make tiny things appear big. Increase in magnification power can be achieved by using a wide range of objective lens. Magnifying power is always linked to the resolving power.  The higher the magnification , the higher the resolving power and hence the more the details of the specimen  that can be seen .The resolving power of  an  objective lens depends on the numerical aperture (NA)  of that objective lens .

The following are the usual NA values of the commonly used objective lens

X10 objective lens = NA 0. 25  

X20 objective lens = NA 0.45

X40 objective lens = NA 0.65

X100 objective lens = NA 1.25

Immersion oil

In a light microscope, beam of light passes from the specimen on the stage and moves through air towards the objective lens and from the objective lens, this light will also have to travel through an air space between the objective lens and the eye piece lens before reaching the eye

 Movement of light through different medium as describe above will cause the light to be refracted or to bend. This bending of light have little effect on low power objective  lens  i.e. X10,X20 or X40 objectives, but it have significant limitation  to the amount of light  which enter through the high power objective lens i.e.  X100 objective lens and consequently its resolving power.

Such bedding can be avoided by replacing the air between the specimen and the lens with an oil Immersion which have the same optical property as that of glass. These makes light to pass in a straight line as though it was passing through the same media i.e. glass all the way. These therefore will enhance a better resolving power

 

Chromatic and spherical aberration

Chromatic aberration  occurs when  a biconcave lens  splits white light  into its component colors  and in the process blue light is magnified more than red light  so that blue comes into focus  near to the lens. Spherical aberration occurs due to the edges of the lens giving slightly higher magnification than its center

Illumination system of the light microscopes  

Daylight illumination should be discouraged because it is not reliable, difficult to use and rarely adequate for oil emulsion work. Good microscopy requires an adequate well controllable illumination system. These can be achieved by using a microscope with an inbuilt illumination system provided by a special bulb installed below the stage instead of relying on the reflective mirror.

Glare

Glare in microscopes is  simply that  inconvenience caused  as a result of light  reaching the eye  which does not go into making  up the perfect image , instead, it only interferes with the image and the ability of the objective to  distinguish details in a specimen   . To test for glare, remove the eyepiece and check to see if the inside of the tube is illuminated. These indicate presence of glare.

glare can be reduced in the following ways:

  • Positioning a microscope with an inbuilt illumination in a subdued light i.e. not in front of a window.
  • Avoid using a large source of illumination than its necessary.
  • Reducing the condenser glare by reducing the condenser aperture i.e. by adjusting the iris diaphragm when using low power objective.

Microscope filters

 Filters are special devises in microscopes are used to:

  • Reduce the intensity of light when it is required.
  • To increase contrast and resolution.
  • To transmit light of selected wavelength.
  • To protect the eyes from injuries caused by UV light.

Procedure for using light microscope

  • Place the microscope on a firm bench.
  • Turn on, adjust or switch on the in-built bulb of the microscope to direct light into the microscope.
  • Switch or rock the lowest objective (x10) into the optical train.
  • Place the slide containing the specimen on the stage.
  • Rock down the objective using coarse adjustment until it comes to stop. Do so while your eyes are looking at the objective, not into the microscope.
  • Now look into the microscope and using the coarse adjustment knob, rock up the objective until you see the image then rock the fine adjustment knob to focus properly.
  • If you need higher magnification, switch the x40 objective into train and then use the adjustment to focus the image and if you need still higher magnification, apply oil immersion on the specimen placed on the stage and switch the x100 objective into train.
  • Rock down the objective to touch the slide while the eyes are out of the microscope.
  • Rock up the condenser to the maximum.
  • Focus clearly using fine adjustment.

Care and maintenance of light microscopes

  1. Carry microscopes using both hands by the limb and the base and should be in upright position so as to avoid dropping loose parts e.g. mirror and eye- pieces.
  2. Do not touch the microscopes lens using   fingers
  3. Clean microscope  lens using lens cleansing tissues
  4. Microscopes should be kept clean and covered to avoid dust
  5. Keep microscopes away from direct sunlight and dust i.e.  always cover microscopes and keep then in locked cupboards
  6. The optical parts should be cleaned using a little xylene on a lens cleaning tissue or soft cloth. Do not use sleeves or lab coats
  7. Never place microscopes at the edge of benches
  8. Avoid using a high power objective when a low power objective is satisfactory
  9. It is dangerous to rock down the objective while you are looking into the microscope. You risk breaking the slide, the objective lens or the condenser
  10. Repair should be left only to a trained expert
  11. Do not place wet preparation on the stage without wiping the undersurface of the slide.

b) THE ELECTRON MICROSCOPE

The development of electron microscope has revolutionized microscopic studies since 1950s. These microscope uses electron beams instead of light and electromagnet instead of glass lens. The electrons are recorded in efflorescent screen which then forms a viewable image on the screen (photomicrograph)

 Electrons travel in cathode ray tube which is a vacuum chamber. The specimens are mounted in total vacuum   in order to enable the electrons to travel with high velocity without colliding with air or any atoms in space within. These electrons pass through an electromagnet which acts as lenses where they produce electric fields

Also the specimens are prepared by sectioning using an extremely delicate microtome which produces extremely thin slices which are fixed using osmic acid or glutaraldehyde for cytoplasm components

Electron microscope have very high resolving power  that is 1000 times  more than an optical microscope  , thus specimens can be magnified  much more without loss of clarity . With this microscope, materials which were initially described as structureless have been shown to have elaborate internal organization and the so called homogeneous fluids have now shown to contain a variety of complex structures. These microscopes have had a greater impact in biology and have helped in opening up a new world whose existence was barely realized in the 1950s  

The electron microscope however has some disadvantages which include:

  • The materials for examination have to be mounted in a vacuum and therefore only dead specimens can be viewed.
  • The materials have to be fixed and stained, these preliminary treatments may distort the delicate structures inside the cells and create images that are not real (artifacts). These problem can be overcome by using electron microscopes together with other types of microscopes.

Types of electron microscopes

  • Transmission electron microscope –images are derived from electrons which have passed through the specimens
  • Scanning electron microscope –solid specimens are bombarded with a beam of electrons which causes secondary electrons to be emitted from the surface of specimen. These electrons are recorded on a photoelectric plate as in transmission electron microscope. The scanning electron microscope enables some details   on the surface to be seen more clearly. Images seen on these microscopes are three dimensional.

 PHASE CONTRAST MICROSCOPE

This microscope was developed in 1940s. It enables transparent objects to be seen and it is ideal for studying unstained living cells. In appreciation of living cells, there may be sudden changes of refractive index between the inside and the outside of the cell or between the nucleus and the cytoplasm. An annulus is used to give a halo cone of rays since full cone illumination will cause direct or diffracted rays to be superimposed

The region on the center has a low refractive index and the outside have a high refractive index. The transmitted rays are diffracted and will not enter the annulus. The region will appear dark. The diffracted and the undiffracted rays strike different parts of the phase plate where the phase contrast as well as the amplitude can be altered. The diffraction patterns are produced by interfering and reinforcement of light waves. Variation in brightness occur at boundaries of different diffractive indexes in the specimen which gives the characteristic of a halo appearance

THE UV MICROSCOPE

The visible region of the electromagnetic spectrum extends from 650 Ao (deep red) –450Ao . Wavelengths shorter than 400Ao are called UV. In this region, some cellular compounds e.g. nucleic acid and proteins absorb a particular wavelength. If the UV microscope is used in conjunction with visible light microscopy, much useful information may be obtained. UV microscopes use quartz lenses to transmit the UV light. These microscopes however have limited use in living cells because the UV rays rapidly kill the living cell. They also require the use of filters to protect the eyes from the harmful effect of the UV radiations.

FLUORESCENT MICROSCOPE

 When certain chemical substances are irradiated by UV light, they absorb the radiation and emit visible light. Objects which emit such chemicals within living cells can therefore be absorbed as fluorescent areas when illuminated with UV light. The chemicals absorbed are known as fluorochromes. The method is extremely sensitive and can detect minute quantities of materials. It is particularly useful for studying how proteins and other molecules enter or are adsorbed into cells. The proteins are labeled by coupling with the molecules of fluorescent dyes. The fluorescent substances may be naturally present within the cell or e.g. norepinephrine within certain neurons or it may be artificially introduced into the cell as a marker.e.g. administration of antibodies tagged with fluorescent substances. The fluorescent substances will be visible wherever there are antigens  

  1. e)     DARK FIELD (ILLUMINATION) MICROSCOPE

This type of microscope is appropriate for observing microorganisms suspended in fluid .These method enables  clear viewing of microorganisms structures and motility, it makes some  living organisms  visible which cannot be seen  by ordinary  transmitted light

In this type of microscope, light enter special condensers, which have a central ‘blacken-out’ area so that light entering cannot pass out directly through it to enter the objective.  Instead, the light is reflected to pass through the outer edge of the condenser edge at wide angle so that the only light entering the eyes come from the specimen themselves with no light entering directly from the light source. In this way, specimens are seen brightly illuminated against a black background like stars in a night sky or dust in a shaft of sunlight across a darkened room

The region on the center has a low refractive index and the outside have a high refractive index. The transmitted rays are diffracted and will not enter the annulus. The region will appear dark. The diffracted and the undiffracted rays strike different parts of the phase plate where the phase contrast as well as the amplitude can be altered. The diffraction patterns are produced by interfering and reinforcement of light waves. Variation in brightness occur at boundaries of different diffractive indexes in the specimen which gives the characteristic of a halo appearance

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