UFC Fighter Sean Sherk's Low Oxygen Gas Mask MMA Fitness Training!

UFC Fighter Sean Sherk's Intense Simulated High Altitude (Low Oxygen) Gas Mask Workout performed by us at The Los Angeles Fitness Expo, Jan. 2011.  We found it to be much harder than running near the highest peaks of the Santa Monica Mountains at Sandstone Peak (3,111 feet).  This is part of the National Park Service near Malibu (see video below).  

The information below is from their website:

Elevation Training Mask helps condition the lungs by creating pulmonary resistance, your diaphragm is strengthened, surface area and elasticity in the alveoli is increased.

Elevation Training Mask will help get your breathing under control and help with lung stamina, it can be used during running, cycling (stationary for beginners) and other workouts. 

If you train with less oxygen you can eventually go on for longer! Elevation Training Mask is great because it regulates how much air you can breathe in, making it so that you breath less oxygen, in turn making the air thinner (due to the low oxygen intake it's similar to altitude training).

Following are the changes that significantly boost Athletic Performance when using Elevation Training Mask.

·  Increases in Lung capacity as your lungs have to work 9 times harder to get the oxygen in

·  Increases anaerobic Thresholds

·  Gas exchange becomes more efficient

·  Energy Production levels rise

·  Mental and Physical stamina increase

·  Mental Focus gets better

The Benefits

Elevation Training Mask mimics the effect of High Altitude Training. When top athletes want to improve in their performance, they go to high altitude levels to train, and when they come back to sea level to race, they are performing much stronger, faster, and have more endurance due to the type of training they have been doing prior to the event.

With reduced oxygen consumption the human body changes in several ways. The production of red blood cells and new capillaries (small blood vessels) increase the transfer of oxygen from the lungs to the rest of the body. An important natural hormone involved in this process is EPO (erythropoietin).

GMT is also fantastic for anyone suffering from asthma, as most asthmatics tend to over breathe, with the gas mask on they will learn to control their breathing, and some say it can even cure it if done on a regular basis.

Blood

Blood is an 'aqueous body fluid'. In other words it is water containing a whole range of substances. It is contained in a complex network called the vascular system and is pumped around the body by the heart.  Blood has two main functions. It: provides defense against disease transports compounds, ions, and some elements to and from other tissues and cells.

Red blood cells and haemoglobin

Oxygen is one of the substances transported with the assistance of red blood cells. The red blood cells contain a pigment called hemoglobin, each molecule of which binds four oxygen molecules. Oxyhemoglobin forms. The oxygen molecules are carried to individual cells in the body tissue where they are released. The binding of oxygen is a reversible reaction.

Hb + 4O₂     Hb.4O₂

The four 'disks' in the diagram of hemoglobin are the parts of the molecule where the oxygen molecules bind, while the four folded 'sausage shapes' represent polypeptide chains.

At high oxygen concentrations oxyhemoglobin forms, but at low oxygen concentrations oxyhemoglobin dissociates to hemoglobin and oxygen. The balance can be shown by an oxygen dissociation curve for oxyhemoglobin. 

at relatively low oxygen concentrations there is uncombined hemoglobin in the blood and little or no oxyhemoglobin, e.g. in body tissue 

at relatively high oxygen concentrations there is little or no uncombined hemoglobin in the blood; it is in the form of oxyhemo globin, e.g. in the lungs. 

Note Historically oxygen and carbon dioxide concentrations are expressed as partial pressures (measured in kPa), also called oxygen or carbon tension. The amount of oxygen held by the hemoglobin, i.e. its saturation level, is normally expressed as a percentage. 

Oxygen dissociation curves can be used to illustrate Le Chatelier's Principle which states that a system in dynamic equilibrium responds to any stress by restoring the equilibrium. For example shifts in the position of the curve occur as a result of the concentration of CO₂ or changes in pH. 

The effect of carbon dioxide in the blood

Hemoglobin can also bind carbon dioxide, but to a lesser extent. Carbaminohaemoglobin forms. Some carbon dioxide is carried in this form to the lungs from respiring tissues.

The presence of carbon dioxide helps the release of oxygen from hemoglobin, this is known as the Bohr effect. This can be seen by comparing the oxygen dissociation curves when there is less carbon dioxide present and when there is more carbon dioxide in the blood.

When carbon dioxide diffuses into the blood plasma and then into the red blood cells (erythrocytes) in the presence of the catalyst carbonic anhydrase most CO₂ reacts with water in the erythrocytes and the following dynamic equilibrium is established

H₂O + CO₂     H₂CO₃

Carbonic acid, H₂CO₃, dissociates to form hydrogen ions and hydrogen carbonate ions. This is also a reversible reaction and undissociated carbonic acid, hydrogen ions and hydrogen carbonate ions exist in dynamic equilibrium with one another

H₂CO₃     H⁺ + HCO₃^-

Inside the erythrocytes negatively charged HCO₃^- ions diffuse from the cytoplasm to the plasma. This is balanced by diffusion of chloride ions, Cl^-, in the opposite direction, maintaining the balance of negative and positive ions either side. This is called the 'chloride shift'.

The dissociation of carbonic acid increases the acidity of the blood (decreases its pH). Hydrogen ions, H⁺, then react with oxyhemoglobin to release bound oxygen and reduce the acidity of the blood. This buffering action allows large quantities of carbonic acid to be carried in the blood without major changes in blood pH.

Hb.4O₂ + H⁺     HHb+ + 4O₂

(Hb.4O₂ is sometimes written HbO₈.)

It is this reversible reaction that accounts for the Bohr effect. Carbon dioxide is a waste product of respiration and its concentration is high in the respiring cell and so it is here that hemoglobin releases oxygen.

Now the hemoglobin is strongly attracted to carbon dioxide molecules. Carbon dioxide is removed to reduce its concentration in the cell and is transported to the lungs were its concentration is lower. This process is continuous since the oxygen concentration is always higher than the carbon dioxide concentration in the lungs. The opposite is true in respiring cells.

Figure 2:17 The Bohr effect and its consequence on oxygen tension.  When blood is less alkaline, more oxygen is released from haemoglobin and received by the tissues.

SOURCES

http://rsc.org/Education/Teachers/Resources/cfb/transport.htm

References

1. ^ Murray, Robert K.; Darryl K. Granner, Peter A. Mayes, Victor W. Rodwell (2003). Harper’s Illustrated Biochemistry (LANGE Basic Science) (26th ed.). McGraw-Hill Medical. pp. 44–45. 
2. ^ ^{a b} Voet, Donald; Judith G. Voet, Charlotte W. Pratt (2008). Fundamentals of Biochemistry: Life at the Molecular Level (3rd ed.). John Wiley & Sons. pp. 189–190. 
3. ^ Olson, JS; Gibson QH, Nagel RL, Hamilton HB (December 1972). "The ligand-binding properties of hemoglobin Hiroshima ( 2 2 146asp )". The Journal of Biological Chemistry 247 (23): 7485–93. PMID 4636319.