Member Barakat Adeoye
MemberForum Replies Created
-
The size of the chicken chest (breast muscle) in broiler poultry is primarily increased by manipulating the amino acid (protein) content and balance of the feed, as muscle tissue is composed of protein. This strategy is critical because breast meat is the most valuable part of the carcass.
The key nutritional factors used to maximize breast meat yield are:
1. High-Density Essential Amino Acids (AAs)
The most direct way to increase breast muscle growth is by ensuring a high and optimal supply of essential amino acids, which are the building blocks of protein that the chicken cannot produce on its own.
* Lysine (Lys): This is considered the single most critical amino acid for muscle accretion (growth). Broiler feed formulations are often based on the ratio of other AAs to Lysine. Higher levels of digestible Lysine are directly correlated with increased breast meat yield.
* Methionine (Met) and Threonine (Thr): These are the second and third most limiting amino acids, respectively, and are essential for maximizing the efficiency of Lysine utilization and for overall protein synthesis.
* Total Sulfur Amino Acids (TSAA): The combination of Methionine and Cystine (which Met converts to) is crucial for growth and feathering, but also significantly impacts breast muscle development.
* Arginine and Leucine: These and other essential amino acids also play important roles, particularly Leucine, which is known to activate the mTOR pathway, a cellular mechanism that directly regulates muscle protein synthesis and growth.
The Ideal Protein Concept
Modern poultry nutrition uses the “Ideal Protein” concept, which means balancing the ratio of all essential amino acids to Lysine, rather than simply feeding a high crude protein (CP) diet. The requirements for maximizing breast meat yield (BMY) are higher than the requirements for simply maximizing body weight gain or feed efficiency.
2. Protein-to-Energy Ratio
While amino acids are the building blocks, the bird needs energy to power the growth process. The relationship between protein and energy must be balanced:
* Higher AA-to-Energy Ratio: Broilers that are genetically selected for rapid growth and high breast yield require a relatively higher ratio of digestible amino acids to metabolizable energy (\text{ME}) in the feed.
* If the energy content is too low relative to protein, the bird may burn the expensive protein for energy instead of using it for muscle growth.
* If the energy content is too high, the bird might deposit more abdominal fat instead of lean muscle mass.
3. Feed Format and Consistency
The physical form of the feed affects how much a broiler can eat, which in turn impacts muscle growth.
* Pelleted Feed: Feeding broilers a pellet or a crumb (broken pellets for young birds) rather than a mash generally leads to:
* Increased feed intake.
* Improved feed conversion ratio (FCR).
* Higher growth rate and, consequently, a higher breast meat yield. This is due to reduced time spent eating and less energy wasted in digestion.
4. Other Functional Ingredients and Timing
* Feeding Phases: The density of essential amino acids is typically highest in the starter and grower phases when the breast muscle has the highest allometric growth rate (growing faster than the rest of the body). Some programs also increase the density in the finisher phase to compensate for the continued rapid growth of the breast muscle.
* Micronutrients and Additives:
* Chelated Trace Minerals: These are more bioavailable and can improve overall health, allowing more nutrients to be directed toward muscle deposition instead of immune function.
* Antioxidants (like Vitamin E and Selenium): These can help mitigate muscle myopathies (such as “woody breast” or “white striping”) that sometimes occur in fast-growing birds, which negatively impact meat quality and yield.The size of the chicken chest (breast muscle) in broiler poultry is primarily increased by manipulating the amino acid (protein) content and balance of the feed, as muscle tissue is composed of protein. This strategy is critical because breast meat is the most valuable part of the carcass.
The key nutritional factors used to maximize breast meat yield are:
1. High-Density Essential Amino Acids (AAs)
The most direct way to increase breast muscle growth is by ensuring a high and optimal supply of essential amino acids, which are the building blocks of protein that the chicken cannot produce on its own.
* Lysine (Lys): This is considered the single most critical amino acid for muscle accretion (growth). Broiler feed formulations are often based on the ratio of other AAs to Lysine. Higher levels of digestible Lysine are directly correlated with increased breast meat yield.
* Methionine (Met) and Threonine (Thr): These are the second and third most limiting amino acids, respectively, and are essential for maximizing the efficiency of Lysine utilization and for overall protein synthesis.
* Total Sulfur Amino Acids (TSAA): The combination of Methionine and Cystine (which Met converts to) is crucial for growth and feathering, but also significantly impacts breast muscle development.
* Arginine and Leucine: These and other essential amino acids also play important roles, particularly Leucine, which is known to activate the mTOR pathway, a cellular mechanism that directly regulates muscle protein synthesis and growth.
The Ideal Protein Concept
Modern poultry nutrition uses the “Ideal Protein” concept, which means balancing the ratio of all essential amino acids to Lysine, rather than simply feeding a high crude protein (CP) diet. The requirements for maximizing breast meat yield (BMY) are higher than the requirements for simply maximizing body weight gain or feed efficiency.
2. Protein-to-Energy Ratio
While amino acids are the building blocks, the bird needs energy to power the growth process. The relationship between protein and energy must be balanced:
* Higher AA-to-Energy Ratio: Broilers that are genetically selected for rapid growth and high breast yield require a relatively higher ratio of digestible amino acids to metabolizable energy (\text{ME}) in the feed.
* If the energy content is too low relative to protein, the bird may burn the expensive protein for energy instead of using it for muscle growth.
* If the energy content is too high, the bird might deposit more abdominal fat instead of lean muscle mass.
3. Feed Format and Consistency
The physical form of the feed affects how much a broiler can eat, which in turn impacts muscle growth.
* Pelleted Feed: Feeding broilers a pellet or a crumb (broken pellets for young birds) rather than a mash generally leads to:
* Increased feed intake.
* Improved feed conversion ratio (FCR).
* Higher growth rate and, consequently, a higher breast meat yield. This is due to reduced time spent eating and less energy wasted in digestion.
4. Other Functional Ingredients and Timing
* Feeding Phases: The density of essential amino acids is typically highest in the starter and grower phases when the breast muscle has the highest allometric growth rate (growing faster than the rest of the body). Some programs also increase the density in the finisher phase to compensate for the continued rapid growth of the breast muscle.
* Micronutrients and Additives:
* Chelated Trace Minerals: These are more bioavailable and can improve overall health, allowing more nutrients to be directed toward muscle deposition instead of immune function.
* Antioxidants (like Vitamin E and Selenium): These can help mitigate muscle myopathies (such as “woody breast” or “white striping”) that sometimes occur in fast-growing birds, which negatively impact meat quality and yield. -
Keeping litter dry and birds healthy starts with <strong data-start=”49″ data-end=”90″>good ventilation and moisture control. Ensure proper <strong data-start=”106″ data-end=”117″>airflow to remove humidity, <strong data-start=”138″ data-end=”183″>avoid water leaks or overfilling drinkers, and <strong data-start=”189″ data-end=”228″>stir or replace wet spots regularly. Use <strong data-start=”234″ data-end=”264″>absorbent litter materials, maintain the right <strong data-start=”285″ data-end=”321″>temperature and stocking density, and provide <strong data-start=”335″ data-end=”352″>balanced feed to prevent diarrhea that can wet the litter.Keeping litter dry and birds healthy starts with good ventilation and moisture control. Ensure proper airflow to remove humidity, avoid water leaks or overfilling drinkers, and stir or replace wet spots regularly. Use absorbent litter materials, maintain the right temperature and stocking density, and provide balanced feed to prevent diarrhea that can wet the litter.
-
Chicken egg production is affected by a complex interplay of genetic (internal) and environmental/management (external) factors. Maintaining an optimal balance across all these areas is crucial for high and consistent laying performance.
Here are the key factors:
1. Biological and Genetic Factors
| Factor | Effect on Production |
|—|—|
| Age of Hen | Production increases rapidly to a peak (around 25–35 weeks) and then gradually declines as the hen gets older. |
| Breed/Strain | Different breeds and genetic strains are selected for different laying capacities (e.g., Leghorns vs. Dual-Purpose). |
| Body Weight | Achieving the correct target body weight during the rearing phase is essential for optimal onset and peak production. |
| Molting | Hens naturally go through a molting period (feather shedding and renewal), during which egg production stops or is severely reduced. |
2. Nutritional Factors
The hen must consume adequate amounts of specific nutrients to sustain the energy and material demands of laying an egg daily.
| Nutrient | Role in Egg Production |
|—|—|
| Energy | Required for metabolism and the energy-intensive process of egg formation; deficiency reduces laying rate. |
| Protein/Amino Acids | Essential for forming the albumen (egg white); Methionine and Lysine are crucial amino acids. |
| Calcium | Vital for eggshell formation; deficiency leads to thin-shelled or soft-shelled eggs and lower production. |
| Vitamin D3 | Required for efficient calcium absorption; deficiency negatively impacts shell quality and production. |
| Water | An egg is \sim70\% water; dehydration due to poor access or quality is one of the fastest ways to stop egg laying. |
3. Environmental and Management Factors
These are external factors controlled by the producer that dramatically influence a hen’s stress level and physiological processes.
| Factor | Effect on Production |
|—|—|
| Light Duration (Photoperiod) | Hens require at least 14–16 hours of light per day to stimulate the pituitary gland for optimal laying. Shortening day length reduces production. |
| Ambient Temperature | High heat stress (>30^{\circ}\text{C}) reduces feed intake, increases stress, and severely drops egg production and shell quality. Extreme cold also stresses the bird, shifting energy from egg production to maintenance. |
| Stress | Any form of negative stress (e.g., overcrowding, sudden changes, loud noises, fright, excessive handling) can cause production to decline rapidly. |
| Housing/Density | Poor ventilation (leading to high ammonia levels), wet litter, or overcrowded conditions increase stress and disease risk, reducing lay. |
| Health and Disease | Diseases (e.g., Infectious Bronchitis, Newcastle Disease, Avian Influenza) or high parasite/mite loads can cause a sharp drop in lay and often result in misshapen or poor-quality eggs. |Chicken egg production is affected by a complex interplay of genetic (internal) and environmental/management (external) factors. Maintaining an optimal balance across all these areas is crucial for high and consistent laying performance.
Here are the key factors:
1. Biological and Genetic Factors
| Factor | Effect on Production |
|—|—|
| Age of Hen | Production increases rapidly to a peak (around 25–35 weeks) and then gradually declines as the hen gets older. |
| Breed/Strain | Different breeds and genetic strains are selected for different laying capacities (e.g., Leghorns vs. Dual-Purpose). |
| Body Weight | Achieving the correct target body weight during the rearing phase is essential for optimal onset and peak production. |
| Molting | Hens naturally go through a molting period (feather shedding and renewal), during which egg production stops or is severely reduced. |
2. Nutritional Factors
The hen must consume adequate amounts of specific nutrients to sustain the energy and material demands of laying an egg daily.
| Nutrient | Role in Egg Production |
|—|—|
| Energy | Required for metabolism and the energy-intensive process of egg formation; deficiency reduces laying rate. |
| Protein/Amino Acids | Essential for forming the albumen (egg white); Methionine and Lysine are crucial amino acids. |
| Calcium | Vital for eggshell formation; deficiency leads to thin-shelled or soft-shelled eggs and lower production. |
| Vitamin D3 | Required for efficient calcium absorption; deficiency negatively impacts shell quality and production. |
| Water | An egg is \sim70\% water; dehydration due to poor access or quality is one of the fastest ways to stop egg laying. |
3. Environmental and Management Factors
These are external factors controlled by the producer that dramatically influence a hen’s stress level and physiological processes.
| Factor | Effect on Production |
|—|—|
| Light Duration (Photoperiod) | Hens require at least 14–16 hours of light per day to stimulate the pituitary gland for optimal laying. Shortening day length reduces production. |
| Ambient Temperature | High heat stress (>30^{\circ}\text{C}) reduces feed intake, increases stress, and severely drops egg production and shell quality. Extreme cold also stresses the bird, shifting energy from egg production to maintenance. |
| Stress | Any form of negative stress (e.g., overcrowding, sudden changes, loud noises, fright, excessive handling) can cause production to decline rapidly. |
| Housing/Density | Poor ventilation (leading to high ammonia levels), wet litter, or overcrowded conditions increase stress and disease risk, reducing lay. |
| Health and Disease | Diseases (e.g., Infectious Bronchitis, Newcastle Disease, Avian Influenza) or high parasite/mite loads can cause a sharp drop in lay and often result in misshapen or poor-quality eggs. | -
Yes, definitely — <strong data-start=”18″ data-end=”76″>broilers usually perform better on pellets or crumbles than on mash. Pelleted feed improves <strong data-start=”114″ data-end=”175″>feed intake, growth rate, and feed conversion ratio (FCR) because birds spend less energy eating and waste less feed. Crumbles are especially good for young chicks as they’re easier to eat. However, if pellet quality is poor (too much fines), performance can drop — so <strong data-start=”387″ data-end=”424″>feed form consistency and quality are crucial for the best results.Yes, definitely — broilers usually perform better on pellets or crumbles than on mash. Pelleted feed improves feed intake, growth rate, and feed conversion ratio (FCR) because birds spend less energy eating and waste less feed. Crumbles are especially good for young chicks as they’re easier to eat. However, if pellet quality is poor (too much fines), performance can drop — so feed form consistency and quality are crucial for the best results.
-
Factors affecting chicken egg production include:
-
<strong data-start=”56″ data-end=”69″>Nutrition – Balanced feed with enough protein, calcium, and vitamins.
-
<strong data-start=”135″ data-end=”147″>Lighting – Hens need 14–16 hours of light daily for steady laying.
-
<strong data-start=”211″ data-end=”228″>Age and breed – Productivity declines with age; some breeds lay more eggs than others.
-
<strong data-start=”307″ data-end=”324″>Health status – Diseases, parasites, or stress reduce output.
-
<strong data-start=”378″ data-end=”405″>Temperature and housing – Extreme heat or cold affects laying consistency.
-
<strong data-start=”462″ data-end=”486″>Management practices – Clean housing, fresh water, and reduced stress are key.Factors affecting chicken egg production include:
Nutrition – Balanced feed with enough protein, calcium, and vitamins.
Lighting – Hens need 14–16 hours of light daily for steady laying.
Age and breed – Productivity declines with age; some breeds lay more eggs than others.
Health status – Diseases, parasites, or stress reduce output.
Temperature and housing – Extreme heat or cold affects laying consistency.
Management practices – Clean housing, fresh water, and reduced stress are key.
-
-
To prevent respiratory issues in broilers during winter, it’s essential to balance <strong data-start=”83″ data-end=”114″>ventilation and temperature. Keep houses warm but ensure <strong data-start=”144″ data-end=”162″>fresh air flow to remove ammonia and moisture. Key strategies include:
-
<strong data-start=”225″ data-end=”247″>Proper ventilation – Avoid airtight houses; maintain air exchange without chilling birds.
-
<strong data-start=”324″ data-end=”345″>Litter management – Keep it dry to reduce ammonia and bacterial growth.
-
<strong data-start=”405″ data-end=”425″>Humidity control – Maintain 50–70% to prevent condensation and respiratory irritation.
-
<strong data-start=”501″ data-end=”523″>Heater maintenance – Ensure uniform heat distribution and clean burners regularly.
-
<strong data-start=”593″ data-end=”608″>Biosecurity – Limit disease entry from outside sources.
-
<strong data-start=”658″ data-end=”671″>Nutrition – Provide vitamins (A, E, C) and trace minerals to strengthen immunity.To prevent respiratory issues in broilers during winter, it’s essential to balance ventilation and temperature. Keep houses warm but ensure fresh air flow to remove ammonia and moisture. Key strategies include:
Proper ventilation – Avoid airtight houses; maintain air exchange without chilling birds.
Litter management – Keep it dry to reduce ammonia and bacterial growth.
Humidity control – Maintain 50–70% to prevent condensation and respiratory irritation.
Heater maintenance – Ensure uniform heat distribution and clean burners regularly.
Biosecurity – Limit disease entry from outside sources.
Nutrition – Provide vitamins (A, E, C) and trace minerals to strengthen immunity.
-
-
That’s a great summary — it clearly highlights the key economic differences between broiler and layer farming in terms of return speed, risk, and income stability.That’s a great summary — it clearly highlights the key economic differences between broiler and layer farming in terms of return speed, risk, and income stability.
-
Thanks for sharing.
-
Adequate lysine and balanced amino acids are key for better breast muscle growth.
-
Early vaccines help build strong immunity when chicks are most vulnerable.
-
Keeping litter dry and using ammonia or phenolic disinfectants helps destroy oocysts effectively.
-
The main economic difference is that broiler farming offers quick but potentially higher-risk returns from selling meat, while layer farming provides a steady, consistent income from selling eggs over a longer period. Broilers have a fast turnover (6-8 weeks) and higher market value per bird, but require careful market timing to maximize profit. Layers have a long production cycle (up to 2 years), lower upfront costs in some areas, but a more consistent income stream due to continuous egg demand
-
Thanks for sharing .
-
Spot on, Dr. Shabir Sb that controlling ammonia and keeping litter dry are keys for maintaining respiratory health.
-
Very well summarized, Md — that’s a precise list of real winter-season challenges we face on farms.
