Monday, March 23, 2009
Raising Quail, Sanitation, Cleanliness and Disinfectants
If you want to be successful at raising quail, you will need a good management program. Three major parts of your management program must include: Cleaning, Sanitation and Disinfectants.
When raising quail these three things are required before you receive eggs, before moving chicks to brooding area and before moving to grow out pens. They are also required through out the whole raising quail process.
Below is an article from: www.msucares.com. It is to be used for educational purposes only.
This is a very good atricle that can help make your raising quail experience a lot better.
Sanitation: Cleaning and Disinfectants
Diseases and infections have always been a major concern to the poultry industry--especially in the hatchery. Fortunately, microbial contamination can be prevented and controlled using proper management practices and modern health products. Microorganisms are everywhere! Some are relatively harmless while others are highly pathogenic. Some pose a lethal threat to one species of animal while remaining harmless to another species. Some organisms are easily destroyed while others are very difficult to eliminate. The moral is: Treat all microorganisms as if they are a severe threat to the chick's livelihood.
Understanding the terms used to describe microbial control is important when selecting the appropriate action for eliminating disease causing organisms. Three terms commonly used but often misunderstood are sterilization, disinfection, and sanitation.
· Sterilization - The destruction of all infective and reproductive forms of all microorganisms (bacteria, fungi, virus, etc.).
· Disinfection - The destruction of all vegetative forms of microorganisms.Spores are not destroyed.
· Sanitation - The reduction of pathogenic organism numbers to a level at which they do not pose a disease threat to their host.
Most hatchery personnel have the impression that they are approaching a sterile condition because they use disinfectants when "disinfecting" the facilities. In fact, they may only achieve a sanitized condition at the very best. The most important consideration to remember when striving for a sanitized hatchery is that cleanliness is essential.
Proper cleaning of facilities removes the vast majority of all organisms and must be used before application of disinfectants. This applies to all areas within the hatchery including floors, walls, setters, hatcher's, trays, chick processing equipment, air and personnel. The success of a hatchery sanitation program is limited only by its weakest link. It is extremely important to remove as much organic matter as practicable from surfaces to be disinfected. All debris including down, egg shells, droppings, tissue residues, etc. must be removed from the hatchery. This is followed by thorough cleaning using warm water and appropriate cleaning aides. Care is focused on selecting the proper detergent and thus producing the cleanest hatchery environment possible. Special attention is placed on compensating for variations in hardness, salinity and pH of the cleaning water. A thorough rinsing with abundant quantities of clean sanitized water completes the cleaning process and removes most lingering residues of detergents, organic matter or microbial organisms that can interfere with the effectiveness of a disinfectant.
Only after the facilities have been thoroughly cleaned are the surfaces treated with an appropriate disinfectant solution. Not all disinfectants are suited for every situation. When selecting the right disinfectant, carefully consider:
1. The type of surface being treated.
2. The cleanliness of the surface.
3. The type of organisms being treated.
4. The durability of the equipment/surface material.
5. Time limitations on treatment duration.
6. Residual activity requirements
If the surface is free of organic matter and residual activity is not required, quaternary ammonium compounds and possibly halogen compounds can be used effectively. However, if surfaces are difficult to clean, residual activity is required or the contaminating organisms are difficult to destroy, then multiple phenolics or coal tar distillates may be needed.
Careful attention must assure that the disinfectant, if used as directed, meets requirements of the user. Be reasonable and don't expect the product to produce unattainable performance. Instead, select a different product or modify disease control practices.
In general, disinfectants can be divided into seven major categories. A more detailed summary of the basic attributes of each category of disinfectants is available later in this discussion as "General Characteristics of Disinfectants". The various classes of disinfectants are:
1. Alcohols
2. Halogens
3. Quaternary Ammonium Compounds
4. Phenolics
5. Coal Tar Distillates
6. Aldehydes
7. Oxidizing Agents
Although many disinfectants are available, those most suited for use in today's hatcheries include quaternary ammonium compounds, phenolics and aldehydes. However, each disinfectant is used only in appropriate locations for meeting the purposes for which it is designed.
Several considerations must be remembered when using any disinfectant to maximize its effectiveness. Some of these general considerations are:
Few disinfectants are effective instantaneously. Each requires a certain amount of time to bond with the microbe and exert a destructive influence. Allow adequate contact time (usually 30 minutes is sufficient) or select a different disinfectant.
When selecting disinfectants, consider their effectiveness on organisms that are of greatest concern. If a hatchery is experiencing problems with a certain viral disease, the disinfectant selected must be effective for destroying the specific organism causing the problem. Not all disinfectants are effective on all types or species of organisms. In most situations it is advisable to clean and disinfect in two different operations that are separated with thorough water rinsing. Many
cleaning/disinfecting producers promote their product based on ease and economy of use because they clean and disinfect in one operation. If these products are used, make sure that they satisfy all efficacy requirements demanded of other disinfectants.
The efficacy of disinfectant solutions is usually enhanced when applied in warm solutions rather that cold solutions. "Hot" solutions, however, may reduce disinfectant efficacy or promote a "cooked-on" condition for unremoved protein-rich residues.
When possible, allow all surfaces to dry thoroughly prior to reuse. Dryness helps prevent the reproduction, spread and transport of disease organisms. Although a surface is clean, it is more easily recontaminated with organisms if water remains on the surface. It is important when selecting the best disinfectant to consider its effect upon the developing embryo and the hatchery environment. Embryos are in a very sensitive stage of development when the eggs enter the hatchery. They can be severely affected if subjected to chemical vapors, even if a sterile environment is provided.
It must be remembered that an egg is not produced in a sterile environment. Before it is laid, the egg is subjected to a series of microbial attacks that can reduce the embryo's potential to develop into a healthy, robust chick. The vent of the hen is probably the most contaminated area that an egg passes through.
Poorly maintained nests can also distribute organisms to noninfected eggs. Fortunately, nature has provided several protective barriers for the embryo. Hatchery personnel must not conduct any procedure that interferes with the egg's natural defense. Producers must make every effort to collect and store eggs so that natural protections are not compromised.
Keeping egg shell surfaces dry is very important to prevent excessive microbial contamination and shell penetration. Without benefit of aqueous water the potentially dangerous microorganisms have little opportunity to invade the egg shell and infect the embryo. Sweating of eggs as they are moved from warm to cool environments must be prevented if sanitation programs are to be successful.
Embryos have the same requirements prior to pipping that the chicks have following hatching. They have the need for heat, moisture, and a high-quality source of air. They can be severely affected by harmful fumes originating from many chemicals often found in or near the hatchery. Although hatchability may not be affected, the quality of the chicks can be reduced. Whenever unusual odors from detrimental chemicals are detected in the hatchery, the product must be removed.
This applies to all chemicals within the hatchery, including disinfectants. As an example, vapors produced by improper use of phenolic disinfectants can cause changes in egg proteins and impair hatchability and chick quality.
Improper selection or use of some disinfectants can damage or hinder the function of hatchery equipment. Many disinfectants are corrosive and damaging to equipment parts. Some disinfectants can clog and gum-up spray nozzles if added to the water used in humidifiers. It is possible that electronic control devices can also be severely damaged or destroyed after prolonged exposure to some disinfectants.
Select disinfectants wisely and always follow label directions for their safe use. Not only does management have the responsibility to maximize hatchability and chick quality, but also to provide a safe working environment for the hatchery personnel. Safety of the people working in the hatchery must never be sacrificed for cost or productive efficiency.
Assuming that a proper state of sanitation is achieved, it must be remembered that the status of disease-free surfaces can be compromised if facilities are not maintained properly. Hatchery personnel must be made aware that they can be a major source of reinfection by transporting of microorganisms on clothes, hands and attire. Since people are direct carriers of microbes, provisions must be made available at appropriate locations in the hatchery for the washing of hands and footwear. Laboratory coats and caps can significantly reduce the spread of microbial organisms. Restricting movement of hatchery personnel by assigning duties within specific areas can reduce the distribution of organisms throughout the hatchery.
The risk posed by disease causing organisms is a constant challenge to hatchery personnel. Always use control measures that have been proved effective rather than trusting visual cleanliness as an indicator of sanitation. A clean surface does not always indicate a disease-free state. Assuming so may be fatal to the chicks and the management program.
We at www.howtoraisequail.com take no responsibility for the use or outcome of this information.
-----------------------------------------------------------------
To find out more about Raising Quail visit:
How to Raise Quail.com
-----------------------------------------------------------------
When raising quail these three things are required before you receive eggs, before moving chicks to brooding area and before moving to grow out pens. They are also required through out the whole raising quail process.
Below is an article from: www.msucares.com. It is to be used for educational purposes only.
This is a very good atricle that can help make your raising quail experience a lot better.
Sanitation: Cleaning and Disinfectants
Diseases and infections have always been a major concern to the poultry industry--especially in the hatchery. Fortunately, microbial contamination can be prevented and controlled using proper management practices and modern health products. Microorganisms are everywhere! Some are relatively harmless while others are highly pathogenic. Some pose a lethal threat to one species of animal while remaining harmless to another species. Some organisms are easily destroyed while others are very difficult to eliminate. The moral is: Treat all microorganisms as if they are a severe threat to the chick's livelihood.
Understanding the terms used to describe microbial control is important when selecting the appropriate action for eliminating disease causing organisms. Three terms commonly used but often misunderstood are sterilization, disinfection, and sanitation.
· Sterilization - The destruction of all infective and reproductive forms of all microorganisms (bacteria, fungi, virus, etc.).
· Disinfection - The destruction of all vegetative forms of microorganisms.Spores are not destroyed.
· Sanitation - The reduction of pathogenic organism numbers to a level at which they do not pose a disease threat to their host.
Most hatchery personnel have the impression that they are approaching a sterile condition because they use disinfectants when "disinfecting" the facilities. In fact, they may only achieve a sanitized condition at the very best. The most important consideration to remember when striving for a sanitized hatchery is that cleanliness is essential.
Proper cleaning of facilities removes the vast majority of all organisms and must be used before application of disinfectants. This applies to all areas within the hatchery including floors, walls, setters, hatcher's, trays, chick processing equipment, air and personnel. The success of a hatchery sanitation program is limited only by its weakest link. It is extremely important to remove as much organic matter as practicable from surfaces to be disinfected. All debris including down, egg shells, droppings, tissue residues, etc. must be removed from the hatchery. This is followed by thorough cleaning using warm water and appropriate cleaning aides. Care is focused on selecting the proper detergent and thus producing the cleanest hatchery environment possible. Special attention is placed on compensating for variations in hardness, salinity and pH of the cleaning water. A thorough rinsing with abundant quantities of clean sanitized water completes the cleaning process and removes most lingering residues of detergents, organic matter or microbial organisms that can interfere with the effectiveness of a disinfectant.
Only after the facilities have been thoroughly cleaned are the surfaces treated with an appropriate disinfectant solution. Not all disinfectants are suited for every situation. When selecting the right disinfectant, carefully consider:
1. The type of surface being treated.
2. The cleanliness of the surface.
3. The type of organisms being treated.
4. The durability of the equipment/surface material.
5. Time limitations on treatment duration.
6. Residual activity requirements
If the surface is free of organic matter and residual activity is not required, quaternary ammonium compounds and possibly halogen compounds can be used effectively. However, if surfaces are difficult to clean, residual activity is required or the contaminating organisms are difficult to destroy, then multiple phenolics or coal tar distillates may be needed.
Careful attention must assure that the disinfectant, if used as directed, meets requirements of the user. Be reasonable and don't expect the product to produce unattainable performance. Instead, select a different product or modify disease control practices.
In general, disinfectants can be divided into seven major categories. A more detailed summary of the basic attributes of each category of disinfectants is available later in this discussion as "General Characteristics of Disinfectants". The various classes of disinfectants are:
1. Alcohols
2. Halogens
3. Quaternary Ammonium Compounds
4. Phenolics
5. Coal Tar Distillates
6. Aldehydes
7. Oxidizing Agents
Although many disinfectants are available, those most suited for use in today's hatcheries include quaternary ammonium compounds, phenolics and aldehydes. However, each disinfectant is used only in appropriate locations for meeting the purposes for which it is designed.
Several considerations must be remembered when using any disinfectant to maximize its effectiveness. Some of these general considerations are:
Few disinfectants are effective instantaneously. Each requires a certain amount of time to bond with the microbe and exert a destructive influence. Allow adequate contact time (usually 30 minutes is sufficient) or select a different disinfectant.
When selecting disinfectants, consider their effectiveness on organisms that are of greatest concern. If a hatchery is experiencing problems with a certain viral disease, the disinfectant selected must be effective for destroying the specific organism causing the problem. Not all disinfectants are effective on all types or species of organisms. In most situations it is advisable to clean and disinfect in two different operations that are separated with thorough water rinsing. Many
cleaning/disinfecting producers promote their product based on ease and economy of use because they clean and disinfect in one operation. If these products are used, make sure that they satisfy all efficacy requirements demanded of other disinfectants.
The efficacy of disinfectant solutions is usually enhanced when applied in warm solutions rather that cold solutions. "Hot" solutions, however, may reduce disinfectant efficacy or promote a "cooked-on" condition for unremoved protein-rich residues.
When possible, allow all surfaces to dry thoroughly prior to reuse. Dryness helps prevent the reproduction, spread and transport of disease organisms. Although a surface is clean, it is more easily recontaminated with organisms if water remains on the surface. It is important when selecting the best disinfectant to consider its effect upon the developing embryo and the hatchery environment. Embryos are in a very sensitive stage of development when the eggs enter the hatchery. They can be severely affected if subjected to chemical vapors, even if a sterile environment is provided.
It must be remembered that an egg is not produced in a sterile environment. Before it is laid, the egg is subjected to a series of microbial attacks that can reduce the embryo's potential to develop into a healthy, robust chick. The vent of the hen is probably the most contaminated area that an egg passes through.
Poorly maintained nests can also distribute organisms to noninfected eggs. Fortunately, nature has provided several protective barriers for the embryo. Hatchery personnel must not conduct any procedure that interferes with the egg's natural defense. Producers must make every effort to collect and store eggs so that natural protections are not compromised.
Keeping egg shell surfaces dry is very important to prevent excessive microbial contamination and shell penetration. Without benefit of aqueous water the potentially dangerous microorganisms have little opportunity to invade the egg shell and infect the embryo. Sweating of eggs as they are moved from warm to cool environments must be prevented if sanitation programs are to be successful.
Embryos have the same requirements prior to pipping that the chicks have following hatching. They have the need for heat, moisture, and a high-quality source of air. They can be severely affected by harmful fumes originating from many chemicals often found in or near the hatchery. Although hatchability may not be affected, the quality of the chicks can be reduced. Whenever unusual odors from detrimental chemicals are detected in the hatchery, the product must be removed.
This applies to all chemicals within the hatchery, including disinfectants. As an example, vapors produced by improper use of phenolic disinfectants can cause changes in egg proteins and impair hatchability and chick quality.
Improper selection or use of some disinfectants can damage or hinder the function of hatchery equipment. Many disinfectants are corrosive and damaging to equipment parts. Some disinfectants can clog and gum-up spray nozzles if added to the water used in humidifiers. It is possible that electronic control devices can also be severely damaged or destroyed after prolonged exposure to some disinfectants.
Select disinfectants wisely and always follow label directions for their safe use. Not only does management have the responsibility to maximize hatchability and chick quality, but also to provide a safe working environment for the hatchery personnel. Safety of the people working in the hatchery must never be sacrificed for cost or productive efficiency.
Assuming that a proper state of sanitation is achieved, it must be remembered that the status of disease-free surfaces can be compromised if facilities are not maintained properly. Hatchery personnel must be made aware that they can be a major source of reinfection by transporting of microorganisms on clothes, hands and attire. Since people are direct carriers of microbes, provisions must be made available at appropriate locations in the hatchery for the washing of hands and footwear. Laboratory coats and caps can significantly reduce the spread of microbial organisms. Restricting movement of hatchery personnel by assigning duties within specific areas can reduce the distribution of organisms throughout the hatchery.
The risk posed by disease causing organisms is a constant challenge to hatchery personnel. Always use control measures that have been proved effective rather than trusting visual cleanliness as an indicator of sanitation. A clean surface does not always indicate a disease-free state. Assuming so may be fatal to the chicks and the management program.
We at www.howtoraisequail.com take no responsibility for the use or outcome of this information.
-----------------------------------------------------------------
To find out more about Raising Quail visit:
How to Raise Quail.com
-----------------------------------------------------------------
Sunday, March 1, 2009
Poultry Disease and Raising Quail (Part 10)
Poultry and Raising Quail health basics.
Disease prevention focuses primarily on dedicated planning and sound management practices that keep infectious diseases out in the first place and stop noninfectious diseases before they start. With this approach, you place a higher priority on planning and expenditures for disease prevention than on short-term savings and stop-gap treatments. It is essentially a mental attitude that recognizes the ever present risk of disease and the fact that disease prevention does not cost; it pays, and many times over.
Failure to concentrate on planned disease prevention often leads to personal disappointment and sometimes disastrous financial loss. A flock receiving good health security management is a delight, and a source of both pride and profit.
A good disease control program emphasizes three primary goals or areas:
1. Reduce exposure to disease organisms by proper sanitation and stress management.
2. Increase bird resistance to disease by using recommended immunization procedures.
3. Treat disease outbreaks with specific medications that are effective against the disease being treated.
Diseases have consistently been a major limiting factor to profitable production. Some diseases result from egg transmission or organisms through the use of infected breeder flocks. Other diseases are brought into the poultry house by vectors like wild birds, rodents, parasites, and even the poultry man.
Disease results when exposure combined with the virulence of an organism is greater than the resistance of the host. Disinfectants reduce the exposure time and number of organisms. Vaccines help build the natural resistance or immunity of the birds. Medications and drugs help battle the disease organisms after they have overwhelmed the birds' natural defenses.
Most diseases can be eradicated from the poultry flock by applying the basic principles of hygiene and excellent sanitation. Other diseases are not easily eliminated, but can be controlled by proper use of disinfectants and sanitizers. If not controlled, the potential for microbial contamination and spread of infectious diseases in the flock is always a threat to the success of any operation.
Sanitation is a rather simple word, commonly used in our daily conversations to refer to the establishment of environmental conditions that are favorable to health. It is those management practices that actually prevent disease or contamination by disease causing organisms. For the most part, they are simple mechanical applications.
They are not sophisticated and usually require little in capital expenditures. These management practices do require a positive attitude, a workable program, and proper application.
There is a practical way to clean a poultry house or hatchery. Each time, the process involves time, labor, energy, and money, so the job must be done correctly to achieve the best results. Disinfecting alone will not control disease, but combined with other disease control practices, will do much to reduce the incidence of many diseases.
Vaccination is one of the more effective ways to prevent specific diseases. This is why we vaccinate poultry; so they are protected from explosive disease outbreaks. Viruses stimulate the development of better immunity than other types of microorganisms; so most poultry vaccinations are against viral diseases like Newcastle disease, infectious bronchitis, laryngotracheitis, fowl pox, and infectious bursal disease.
Disease producing microorganisms can be classified smallest to largest as viruses, bacteria, fungi, protozoa, and parasites. All except the viruses are sensitive to drugs or antibiotics, so treatment against them is available when outbreaks occur. Because viruses are resistant to drugs and antibiotics, their control is fully dependent upon prevention through sanitation, isolation, and vaccination.
Vaccination is basically the introduction of a specific biological substance (antigen) into the bird to stimulate the formation of a resistance or immunity to a particular disease. Usually the biological substance is some of the live disease organisms that you want to protect the bird against. The presence of these organisms in the blood stimulates the body's defense mechanism to produce antibodies that attack the disease causing organisms when the bird is exposed to them. Scientists have developed weakened (attenuated) forms of most disease causing viruses with little danger of causing the severe form of the disease. Even the killed form of some disease causing viruses stimulate the production of antibodies. In these cases, the 100 percent safely killed virus is used. Short-term protection against a particular disease can also be given by vaccination with an antiserum that contains antibodies previously formed by animals that have been exposed to that particular disease.
So-called vaccination outbreaks do occur periodically. The factors influencing vaccine response in poultry are many, mainly depending on the host and environment. Seldom are all factors considered when vaccination programs are initiated. Ordinarily some protective immunity is produced when poultry are vaccinated, although the vaccine in itself cannot guarantee it. When vaccination failures occur, the total vaccination program should be reviewed.
Although vaccination offers a method of preventing many poultry diseases from establishing themselves, certain drugs and antibiotics are needed to help alleviate the symptoms of a vast number of diseases. The drugs make up an unassociated list of chemicals, and a great many are specific for a certain disease or for a group of similar diseases. New ones come on the market regularly and many others are in the process of experimentation.
Drugs must reach the pathogenic microscopic organisms in the bird to be effective. Most drugs kill on contact, weaken the organism, or upset its life cycle. Drugs may be administered through the feed, in water, or by injection.
Most drugs are chemicals that disrupt the life cycle of the organism involved. As most of the drugs are quantitative, their activity is determined by the amount administered to the bird. Some are effective when given in a large amount over a short period; others are better if given in small daily dosages over a long period. To be effective, the manufacturer's recommended dosage must be used. Any dilution will not produce the results anticipated. Some drugs produce excellent results from a disease prevention standpoint, but can have a harmful
effect on the bird. Therefore, do not administer more than the recommended amount of any drug.
When drugs are administered to a bird over a long period of time, particularly at a low level, certain species of bacteria become resistant, and finally the resistance becomes so great that the drug is ineffective.
Resistance develops primarily to drugs that are absorbed from the intestinal (systemic drugs) tract although resistance to non-absorbed drugs like bacitracin has been documented.
Antibiotics are used for disease control. Usually they are specific for those diseases caused by bacteria or related organisms. They are of no value against virus infections except to reduce stress on the birds caused by secondary bacterial/fungal/parasitic infections. The beneficial effects of antibiotics are due to their ability to disrupt various phases of cellular metabolism.
An antibiotic will prevent bacterial multiplication, provided enough is present to attack all the bacteria present. If the amount of antibiotic is small and the number of bacteria large, the antibiotic will not produce its full effect. Antibiotics also act by changing the intestinal flora.
Some drugs used in the poultry industry produce major effects in treating specific diseases; others are less valuable, and some are ineffective. In some instances the birds have become resistant, producing a change in the value of the drug. The diagnostic laboratory uses a technique known as a sensitivity test to determine which drugs are effective in treating a disease. The test actually shows which drugs are effective and those that are ineffective for treating the disease.
Proper administration of medications requires that all precautions be followed as shown on the product label. Be sure that the dosage, route of administration, and required withdrawal period are observed. Use only drugs approved by the Food and Drug Administration for treatment of the specific poultry disease involved.
Regardless of the products used, always keep an accurate record of all vaccines and medications administered to the birds. Record the dates, product lot numbers, and all other pertinent information that can be used to monitor the flock's health status.
Remember that disease can affect all types of birds, and all types of people keep birds. Disease outbreaks never discriminate. By practicing health control in the flock, the producer also helps insure the health status of other producers located near him. Good neighbors are a valuable asset in the prevention and elimination of disease problems.
All the information above can be found at www.msucares.com. It is to be used for educational purposes only.
We at www.howtoraisequail.com take no responsibility for the use or outcome of this information.
-----------------------------------------------------------------
To find out more about Raising Quail visit:
How to Raise Quail.com
-----------------------------------------------------------------
Disease prevention focuses primarily on dedicated planning and sound management practices that keep infectious diseases out in the first place and stop noninfectious diseases before they start. With this approach, you place a higher priority on planning and expenditures for disease prevention than on short-term savings and stop-gap treatments. It is essentially a mental attitude that recognizes the ever present risk of disease and the fact that disease prevention does not cost; it pays, and many times over.
Failure to concentrate on planned disease prevention often leads to personal disappointment and sometimes disastrous financial loss. A flock receiving good health security management is a delight, and a source of both pride and profit.
A good disease control program emphasizes three primary goals or areas:
1. Reduce exposure to disease organisms by proper sanitation and stress management.
2. Increase bird resistance to disease by using recommended immunization procedures.
3. Treat disease outbreaks with specific medications that are effective against the disease being treated.
Diseases have consistently been a major limiting factor to profitable production. Some diseases result from egg transmission or organisms through the use of infected breeder flocks. Other diseases are brought into the poultry house by vectors like wild birds, rodents, parasites, and even the poultry man.
Disease results when exposure combined with the virulence of an organism is greater than the resistance of the host. Disinfectants reduce the exposure time and number of organisms. Vaccines help build the natural resistance or immunity of the birds. Medications and drugs help battle the disease organisms after they have overwhelmed the birds' natural defenses.
Most diseases can be eradicated from the poultry flock by applying the basic principles of hygiene and excellent sanitation. Other diseases are not easily eliminated, but can be controlled by proper use of disinfectants and sanitizers. If not controlled, the potential for microbial contamination and spread of infectious diseases in the flock is always a threat to the success of any operation.
Sanitation is a rather simple word, commonly used in our daily conversations to refer to the establishment of environmental conditions that are favorable to health. It is those management practices that actually prevent disease or contamination by disease causing organisms. For the most part, they are simple mechanical applications.
They are not sophisticated and usually require little in capital expenditures. These management practices do require a positive attitude, a workable program, and proper application.
There is a practical way to clean a poultry house or hatchery. Each time, the process involves time, labor, energy, and money, so the job must be done correctly to achieve the best results. Disinfecting alone will not control disease, but combined with other disease control practices, will do much to reduce the incidence of many diseases.
Vaccination is one of the more effective ways to prevent specific diseases. This is why we vaccinate poultry; so they are protected from explosive disease outbreaks. Viruses stimulate the development of better immunity than other types of microorganisms; so most poultry vaccinations are against viral diseases like Newcastle disease, infectious bronchitis, laryngotracheitis, fowl pox, and infectious bursal disease.
Disease producing microorganisms can be classified smallest to largest as viruses, bacteria, fungi, protozoa, and parasites. All except the viruses are sensitive to drugs or antibiotics, so treatment against them is available when outbreaks occur. Because viruses are resistant to drugs and antibiotics, their control is fully dependent upon prevention through sanitation, isolation, and vaccination.
Vaccination is basically the introduction of a specific biological substance (antigen) into the bird to stimulate the formation of a resistance or immunity to a particular disease. Usually the biological substance is some of the live disease organisms that you want to protect the bird against. The presence of these organisms in the blood stimulates the body's defense mechanism to produce antibodies that attack the disease causing organisms when the bird is exposed to them. Scientists have developed weakened (attenuated) forms of most disease causing viruses with little danger of causing the severe form of the disease. Even the killed form of some disease causing viruses stimulate the production of antibodies. In these cases, the 100 percent safely killed virus is used. Short-term protection against a particular disease can also be given by vaccination with an antiserum that contains antibodies previously formed by animals that have been exposed to that particular disease.
So-called vaccination outbreaks do occur periodically. The factors influencing vaccine response in poultry are many, mainly depending on the host and environment. Seldom are all factors considered when vaccination programs are initiated. Ordinarily some protective immunity is produced when poultry are vaccinated, although the vaccine in itself cannot guarantee it. When vaccination failures occur, the total vaccination program should be reviewed.
Although vaccination offers a method of preventing many poultry diseases from establishing themselves, certain drugs and antibiotics are needed to help alleviate the symptoms of a vast number of diseases. The drugs make up an unassociated list of chemicals, and a great many are specific for a certain disease or for a group of similar diseases. New ones come on the market regularly and many others are in the process of experimentation.
Drugs must reach the pathogenic microscopic organisms in the bird to be effective. Most drugs kill on contact, weaken the organism, or upset its life cycle. Drugs may be administered through the feed, in water, or by injection.
Most drugs are chemicals that disrupt the life cycle of the organism involved. As most of the drugs are quantitative, their activity is determined by the amount administered to the bird. Some are effective when given in a large amount over a short period; others are better if given in small daily dosages over a long period. To be effective, the manufacturer's recommended dosage must be used. Any dilution will not produce the results anticipated. Some drugs produce excellent results from a disease prevention standpoint, but can have a harmful
effect on the bird. Therefore, do not administer more than the recommended amount of any drug.
When drugs are administered to a bird over a long period of time, particularly at a low level, certain species of bacteria become resistant, and finally the resistance becomes so great that the drug is ineffective.
Resistance develops primarily to drugs that are absorbed from the intestinal (systemic drugs) tract although resistance to non-absorbed drugs like bacitracin has been documented.
Antibiotics are used for disease control. Usually they are specific for those diseases caused by bacteria or related organisms. They are of no value against virus infections except to reduce stress on the birds caused by secondary bacterial/fungal/parasitic infections. The beneficial effects of antibiotics are due to their ability to disrupt various phases of cellular metabolism.
An antibiotic will prevent bacterial multiplication, provided enough is present to attack all the bacteria present. If the amount of antibiotic is small and the number of bacteria large, the antibiotic will not produce its full effect. Antibiotics also act by changing the intestinal flora.
Some drugs used in the poultry industry produce major effects in treating specific diseases; others are less valuable, and some are ineffective. In some instances the birds have become resistant, producing a change in the value of the drug. The diagnostic laboratory uses a technique known as a sensitivity test to determine which drugs are effective in treating a disease. The test actually shows which drugs are effective and those that are ineffective for treating the disease.
Proper administration of medications requires that all precautions be followed as shown on the product label. Be sure that the dosage, route of administration, and required withdrawal period are observed. Use only drugs approved by the Food and Drug Administration for treatment of the specific poultry disease involved.
Regardless of the products used, always keep an accurate record of all vaccines and medications administered to the birds. Record the dates, product lot numbers, and all other pertinent information that can be used to monitor the flock's health status.
Remember that disease can affect all types of birds, and all types of people keep birds. Disease outbreaks never discriminate. By practicing health control in the flock, the producer also helps insure the health status of other producers located near him. Good neighbors are a valuable asset in the prevention and elimination of disease problems.
All the information above can be found at www.msucares.com. It is to be used for educational purposes only.
We at www.howtoraisequail.com take no responsibility for the use or outcome of this information.
-----------------------------------------------------------------
To find out more about Raising Quail visit:
How to Raise Quail.com
-----------------------------------------------------------------
