Virtually everything you do in life triggers a hormonal response in the body. Hormonal levels control our body's actions. It is very important to understand the key role hormones play in inducing muscular growth as well as muscular breakdown.

Hormones are chemical messengers that are secreted by the endocrine system. Once they are in the blood they travel to specific receptor sites on cells. Tissue adaptions are partly dependent on hormonal levels. It is important that the athlete has a basic understanding of these powerful messengers. Manipulating these hormones to your advantage ensures successful adaption, training, health and performance.

Muscle Fiber Changes

The most important adaption that takes place in muscle tissue is the increase in contractile proteins, actin and myosin. Other changes occur such as the synthesis of non-contractile proteins (satellite cells), which can become part of the contractile element of muscle tissue. Stimulation of these mechanisms occurs with resistance training. Decreasing protein breakdown and increasing protein synthesis are the first steps in hypertrophy.

The anabolic hormones insulin, insulin like growth factor, testosterone and growth hormone are all contributing factors to this process. Decreasing the catabolic hormones such as cortisol is also important in this process. The more muscle fibers stimulated with a particular exercise, the greater the adaptive response. Hormones have a great effect on the capabilities and structure of muscle fibers.

Receptors

The lock-and-key theory states that a specific hormone interacts with a specific receptor site. The hormone acts like a key while the receptor site is like a lock. Once the key opens the lock, a message is sent to the cell to perform a specific action. The genetic material in the nucleus of the cell either translates the message to mean protein synthesis or protein breakdown. Once an adaption ceiling is reached, the cell becomes down regulated (non-responsive) to the hormone. Down regulation of the receptor inhibits alteration in cell metabolism.

Two Main Hormones

There are two main categories of hormones: steroid and polypeptide hormones. These hormones affect muscle cells in different ways.

The gonads and the adrenal cortex secrete steroid hormones. The hormone diffuses across the sarcolemma and binds with its receptor, thus activating it. When the hormone reaches the cell nucleus it opens up units that are coded for protein synthesis. The hormone receptor-complex recognizes certain regulatory mechanisms of genes. The end result is that messenger RNA is processed and shuttled to the sarcoplasm where it becomes protein.

Polypeptide hormones are made of amino acids. Growth hormone and insulin are example of this classification. These hormones are not fat-soluble therefore they cannot penetrate the sarcolemma. They rely on secondary messengers to get their message to the cell nucleus. The change in the receptor as a result of the interaction with the hormone triggers the secondary messenger. A chain of intracellular events lead to the physiological response contributed to the hormone.

Heavy Resistance Exercise

Heavy resistance exercise stimulates significant adaptions in trained muscles such as increased strength, size and power. Resistance training causes endocrine glands to secrete hormones. These hormones provide an excess of information to the body. These hormones elicit different responses. The pattern and duration of exercise greatly influence the type of hormone secreted.



This in return greatly effects the tissue adaptions that occur. Hormonal increases that take place due to resistance training are different than responses activated by endurance exercise. Motor units are utilized with resistance training that are not with other types of exercise. These high threshold motor units are only activated when great amounts of force are needed, such as with heavy resistance training. The muscle fibers within these motor units are activated and a great amount of stress is placed upon the sarcolemmas of the muscle fibers. The stress elicits changes in sarcolemma permeability to nutrients and synthesis and sensitivity of receptors are affected. Finally, it is the force produced in the activated fibers that lead to the anabolic response in the muscle cells.

During and following exercise, numerous hormonal secretions take place. The desired outcome is synthesis of actin and myosin and inhibition of protein breakdown. If the stress is to great or long in duration, catabolic forces such as cortisol take over the muscle. The hormonal responses depend on tissues stimulated, duration of exercise and needed amount of repair.

Once a muscle has reached a high level of development, protein synthesis is no longer the key mechanism for growth. Thus decreasing protein breakdown is the number one contributor to muscular growth. Keep in mind that only the muscle fibers stimulated are subject to affect. This is why it is important to vary exercises. Only the fibers stimulated receive hormonal benefits. If you use the same exercise for biceps every time you train, you will not maximize growth because the same fibers are stimulated continuously. Angles and loading parameters control the extent of hormonal interaction within muscles.

The response of muscles to hormones is dependent on a few factors. If there are great amounts of the hormone in the blood, the chances of affecting the receptors are greater. If the cell is close to its genetic ceiling, the receptor becomes less responsive to the hormone. With heavy resistance training the recovery ability correlates with muscle fiber size. Incorrect training protocols can result in the downside of hormones, catabolism. Interactions between hormones and muscles can negatively influence cellular structure or have a positive effect on growth.

There is an array of factors that contribute to hypertrophy. However, increased force production cannot be contributed to hypertrophy alone. Neural factors play a great role in maximum force production. Each individual varies in forms of neurological efficiency just as they do with hormonal levels.

Hormones In Blood

Blood levels are sometimes used to test for the secretion of hormones. This can be a complex task because the hormonal levels are ever changing in the bloodstream. It should be noted that just because a hormone is present in the bloodstream does not mean that it will successfully reach the receptor site. Although, the higher concentrations of the hormones in the blood the greater possibility for the hormone to bind to the receptor.

The ideal situation for anabolism is to have a higher number of anabolic hormones in the blood than catabolic hormones. This usually leads to positive cellular adaptions.

This concludes Part One of the two part series on manipulating your hormones. In part two, we will explore the specific actions of the primary anabolic and catabolic hormones.

In part two, we will discuss specific hormones and their effects on the body. In this article the main concern is increasing endogenous mechanisms that result in growth hormone secretion.

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By: Jamie Hale

Note: This is part two, click here for part one!

In part one, we discussed the basic relation between hormones and cellular adaptions. In part two, we will discuss specific hormones and their effects on the body.

The anabolic hormones we will be discussing are testosterone, growth hormone, insulin and insulin like growth factors. These are the primary hormones involved with muscular growth.

Testosterone

Everyone involved with the exercise industry has some conception of testosterone. To most it is an evil word, "TESTOSTERONE." This stuff makes people commit violent crimes, die of heart attacks and suffer from strokes. It also allows anyone to put on extraordinary amounts of muscle. Where do these ideas come from? They come from ignorant people who know zero about this hormone.

Testosterone indirectly effects protein synthesis by releasing growth hormone, which increases the release of Insulin Growth Factor (IGF) from the liver. Testosterone has effects on the nervous system, which lead to increasing neurotransmitters and increasing neuromuscular junctions, which enhance muscle size. As neurological efficiency increases, force production also increases.

The mechanism in which testosterone interacts with the cell nucleus is inexact. Once testosterone is secreted, a transport protein called globulin to a receptor site carries it. From here, a message is activated and sent to the cell nucleus. Protein synthesis is the result of this series of events. Concentrations of testosterone are often used as an anabolic marker. There are certain exercise variables that can have a positive effect on blood testosterone levels.

They Are As Follows:


Workouts lasting under sixty minutes.
Multiple sets
Compound exercises
Short rest intervals (one minute)
Heavy resistance, 80% - 90% of 1RM.
Have you ever heard the saying, "Squat and deadlift and your whole body will grow." Elevating testosterone levels as well as stimulating large amounts of muscle mass are the reason this occurs. If you rely solely on the use of machines, try introducing compound exercises and expect your gains to accelerate.

The majority of research done on hormonal responses in relation to exercise has been tested on male subjects. Testosterone responses have been credited as the major determinant in the difference between male and female muscularity and force production. On average, males produce about ten times the testosterone of females. Thus far, studies do not show any significant changes in women's testosterone levels due to exercise.

Growth Hormone

Growth hormone has been cited as a growth mechanism in skeletal muscle tissue and other tissues in the body. Growth hormone is important in the normal growth of a child as well as the role it plays in adapting to exercise.

Some Of The Roles Of Growth Hormone Include:


Increased protein synthesis
Utilization of fatty acids
Increasing amino acid transportation
Increasing cartilage growth
Promotes lipolysis
Reduces carbohydrate utilization for energy
Most studies say growth hormone is released due to neurological signals from the nervous system stimulated by exercise stress and anxiety. Signals to the hypothalamus cause a hormonal release that stimulates the secretion of growth hormone. Growth hormone also stimulates the release of IGFs from the liver. IGFs are potent anabolic agents, which enhance protein synthesis.

Blood levels of growth hormone vary throughout the day. The highest levels of secretion occur during sleep. This is one of the reasons adequate sleep assists the body in recovering and growing properly. Exercise has been shown to increase growth hormone secretion at any time during the day.

The pharmacological use of growth hormone is a highly debated subject. Some experts say growth hormone treatment is the main reason bodybuilders are much more muscular and ripped than they were in the past. Others report growth hormone is only beneficial to bodybuilders that simultaneously use anabolic steroids. Debating this topic is another article in itself. In this article the main concern is increasing endogenous mechanisms that result in growth hormone secretion. Further research is needed to tell us just how exogenous growth hormone compares to natural growth hormone production.

Increased hydrogen ions appear to stimulate the release of growth hormone. This means higher blood lactate concentrations (closely associated with hydrogen ions) mean higher blood levels of growth hormone.

Light resistance exercise has been shown to be non-effective in raising growth hormone levels. Kraemer found when using moderate resistance (10RM) with multiple sets and short rest periods (1 minute), serum growth hormone levels increased. By carefully designing your resistance-training program it is possible to reap the rewards of elevated growth hormone.

When going through the menstrual cycle, women have higher blood levels of growth hormone than men. Research on females has shown when using heavy resistance (5RM) and resting for three minutes between sets, no significant rise in growth hormone occurs. However, when using moderate resistance (10RM) with short rest periods (1 minute) rises occur. Varying routines is important for altering levels of growth hormone.

Insulin

Insulin is a peptide hormone that is secreted from the beta cells of the pancreas. Insulin can have positive effects on skeletal muscle, but it can also enhance bodyfat levels.

Insulin Functions Are As Follows:


Lowers blood glucose.
Promotes cellular uptake of carbohydrates, amino acids and fatty acids.
Excessive insulin results in fat storage.
Training has been shown to increase the sensitivity of insulin. The insulin drop during exercise is reduced by the training effect. Further research needs to be conducted to determine insulin's response in regards to training.


"Injectable insulin is very dangerous and can result in fatality within a matter of minutes."
Insulin acts as a powerful anabolic agent by shuttling amino acids into the muscle cell. Many experts view this hormone as the most powerful anabolic agent in existence. This is why the use of injectable insulin has become commonplace among bodybuilders. Injectable insulin is very dangerous and can result in fatality within a matter of minutes. If you use injectable insulin be sure it is under the supervision of a doctor.

Manipulating insulin levels is important for physique purposes. The right amounts at the right time result in muscular gains while chronically high levels result in fat storage. Excessive levels of insulin reduce testosterone and growth hormone levels. High levels of insulin can also stop the production of eicosanoids. Jay Robb has stated that production of eicosanoids is synthesized within the body from essential fatty acids especially from linolenic acid. Levels of insulin can be manipulated by carbohydrate intake. Too much of a good thing can result in a bad thing.

IGF

Insulin like growth factors (IGFs) are secreted by the liver after growth hormone signals liver DNA to synthesize them. IGFs are classified as IGF-I, a 70 amino-acid polypeptide, or IGF-II, a 67 amino-acid polypeptide. IGFs travel in the blood while being attached to binding proteins where they attach to receptor sites.

The disruption of various cells including fat and muscle cells stimulates the release of IGF. Fat cells store high levels of IGF, while skeletal muscle contains small amounts. It is likely that non-liver cells release IGF without the assistance of growth hormone. It is also possible that specific cells produce IGF, but do not release it into the bloodstream.

Binding proteins play an important part in the function of IGF. IGF has been shown to stimulate the release of binding protein within the muscle itself, therefore changing the cells responsiveness to IGF. Nutritional profile has also shown to be an important factor in IGF responsiveness. Sudden changes in nitrogen balance and protein intake seem to effect IGF levels. Binding proteins act as a reservoir for IGF. These proteins release IGF once a receptor site is open. Thus the amount of IGF degradation is reduced.

At this time, it is unclear how heavy resistance training effects IGF levels. One study showed that a variety of different exercise patterns elicited an IGF rise about two hours after training. Further research needs to be conducted to learn more about exercise effects on IGF levels.

Controlling anabolic hormones is one of the most important aspects of controlling your physique. These powerful hormones previously discussed can help you to reach your fullest potential.

Main Catabolic Hormone

The most powerful catabolic hormone is cortisol. Minimizing cortisol levels can assist greatly in maximizing your growth potential.

Cortisol is a hormone that is produced by the adrenal cortex. This hormone is released to help the body deal with stress and provide energy to the body. The problem with this hormone is the catabolic effects it has on the body.

These Effects Are As Follows:


Increases proteolytic enzymes (enzymes that degrade protein)
Turns amino acids to carbohydrates
Inhibits protein synthesis
Breakdown of collagen and ligament tissue
Cortisol has greater catabolic effects in fast twitch fibers in comparison to slow twitch fibers
In cases of injury, cortisol elevation results in nitrogen degradation and causes a loss of contractile protein. This loss results in muscle atrophy. Inside the muscle, anabolic hormones such as insulin and testosterone counter the actions of cortisol. If the anabolic hormones occupy a greater number of receptors, protein is maintained or enhanced. When cortisol is bound to a greater number of receptors, protein breakdown is enhanced. Ensuring that anabolic hormones are higher than catabolic hormones is important for muscle maintenance and growth.

Resistance training that utilizes high volume; large muscle groups and shorter rest periods are responsible for the highest levels of cortisol. This is interesting because the stimulus that causes the greatest catabolic effect also causes the greatest growth hormone response. While cortisol levels promote breakdown, short time increases could also help with muscular growth. Muscles must be broken down in order to repair themselves and grow. Short-term cortisol elevation would help this process. Athletes often use testosterone-cortisol ratio blood levels to determine if their bodies are in a growth state. This sounds logical, but this ratio has proven unsuccessful as being a marker for mass and strength gains. The multiple roles of cortisol make the test inadequate in being a true marker of anabolism or catabolism.

In conclusion, it is evident that hormones are responsive to muscle tissue. Performance will be enhanced maximally by proper use of anabolic hormones