Hyperbaric Oxygen Therapy reverses tissue
hypoxia, reduces edema by vasoconstriction, stimulates neovascularization and
reduces reperfusion injury by enhancing the activity of oxygen scavengers. It
increases white-blood-cell killing activity, has direct antibacterial effects
and, by regulating receptor production and sites, modulates cytokine and
metalloproteinase effects to reduce inflammation.
(For a more thorough review of the subject, refer to "Textbook of Hyperbaric Medicine," 4th Edition, KK Jain, Hogrefe and Huber, Cambridge, MA 2004.)
(For a more thorough review of the subject, refer to "Textbook of Hyperbaric Medicine," 4th Edition, KK Jain, Hogrefe and Huber, Cambridge, MA 2004.)
Hyperbaric oxygen therapy effects the blood flow:
Normal Blood Flow:
There is 21% oxygen in the air that we breathe, and our lungs transfer this oxygen to our red blood cells (via hemoglobin). These oxygen-filled red blood cells are carried around the body by the plasma (fluid), which travels through the blood vessels. The oxygen diffuses into the surrounding tissue ensuring that it is delivered to where it is needed most.
Restricted Blood Flow:
When there is a restriction (occlusion) in blood flow due to surgery, illness, or injury, the red blood cells block the blood vessel and are unable to transfer oxygen to the cells on the other side of the occlusion. This causes swelling and starves the area of oxygen, causing hypoxia (a lack of oxygen); when this occurs the tissue begins to break down.
Hyperbaric Oxygenation:
Breathing 100% oxygen under pressure causes the oxygen to diffuse into the blood plasma. This oxygen-rich plasma is able to travel past the restriction, diffusing up to 3 times further into the tissue. The pressurized environment helps to reduce swelling and discomfort, while providing the body with at least 10-15 times its normal supply of oxygen to help repair tissue damaged by the original occlusion or subsequent hypoxic condition. Hyperbaric Oxygenation (HBOT) directly increases the saturative effects of tissue oxygenation slowing and reversing hypoxic induced apoptosis – restoring blood supply to the compromised region by the development of new capillary networks (angiogenesis) enabling the body to alter the course and impact of the disease process.
Neurovascular Regeneration:
HBOT mobilizes the body’s circulating stem cells. American Journal Physiology – Heart and Circulatory Physiology (Nov 05)] reports a single 2-hour exposure to HBOT at 2 ATA doubles circulating CD34+ progenitor stem cells (primordial cells targeted to salvage and restore damaged structures); and at approx. 20-hours of HBOT; circulating CD34+ cells increases eight fold (800%).
Courtesy:
Blood flow diagram prepared by
Malcolm R Hooper - HyperMED, Australia
Hyperbaric Oxygen Therapy Mechanism & Effects:
1. HBOT increases Stem Cell Growth:
According to a study to be published in the American Journal of
Physiology-Heart and Circulation Physiology, a typical course of hyperbaric
oxygen treatments increases by eight-fold the number of stem cells circulating
in a patient’s body. Stem cells, also called progenitor cells are crucial to
injury repair.
Stem cells exist in the bone marrow of human beings and animals
and are capable of changing their nature to become part of many different
organs and tissues. In response to injury, these cells move from the bone
marrow to the injured sites, where they differentiate into cells that assist in
the healing process.
The movement, or mobilization, of stem cells can be triggered by a
variety of stimuli — including pharmaceutical agents and hyperbaric oxygen
treatments. Where as drugs are associated with a host of side effects,
hyperbaric oxygen treatments carry a significantly lower risk of such effects.
The safest method in stem cell mobilization than any other pharmaceutical option.
2. HBOT significantly reduces swelling:
The safest method in stem cell mobilization than any other pharmaceutical option.
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| https://www.physiology.org/doi/full/10.1152/ajpheart.00888.2005 |
Dilation or blood vessel widening following damage to tissue results
in decreased blood flow. That increase in blood flow couples with revascular
permeability (movement of fluid in and out of blood vessels) to increase
protein and fluids outside blood vessels reducing tissue swelling. HBOT
significantly reduces swelling, and reduces the pain associated with it.
As the oxygen supply reduces, blood flow increases which will only
serve to exacerbate the swelling and impede the inflammatory process that
assists the commencement of healing.
3. HBOT significantly reduces Edema (Swelling)
The development of edema (swelling) is caused by a number of
factors such as an increase in local blood flow and also damage to local blood
and lymphatic vessels.
The pressure exerted by edema on surrounding structures can
compromise circulation. When this pressure approaches or exceeds that in the
blood vessels, then blood flow will slow or cease altogether.
Swelling also contributes to tissue hypoxia (a shortage of
oxygen in the tissues) by increasing the distance between the capillary
(smallest blood vessels) and the cells, which impedes cell function, metabolism
and the inflammatory process by increasing the diffusion distance
(movement of particles from an area of high concentration to an area of low
concentration).
Hyperbaric oxygen therapy is able to combat the increased distance
for oxygen diffusion from blood vessel to cells by increasing the oxygen
content within the blood which will result in an increased oxygen delivery to
cells and tissues, shortening the inflammatory process, thereby speeding the
healing and repair of tissues.
4. HBOT significantly shortens the inflammatory process:
The body’s initial response to any injury involves inflammation.
Inflammation is the process by which cells such as phagocytes (white blood
cells) gain access to the damaged/injured tissues to prevent infection and
enable healing to commence. Decreased oxygen supply greatly impacts the
inflammatory process as the cells involved in inflammation are oxygen
dependent. Should oxygen supply be decreased, the inflammatory process and
healing will be impaired.
Increased oxygen availability promotes vasoconstriction when blood
vessels in the body become smaller which causes fluid reabsorption and helps
reduce edema while keeping the tissue well oxygenated. This supports the cells
of the inflammatory process in removing cell debris and micro-organisms that
impede infection. White blood cells have an increase in cellular energy that
speeds up their activity and reduces the time of the inflammatory process.
5. HBOT improves range of motion:
Following hyperbaric oxygen therapy, swelling is also decreased
and resolved more rapidly. As a result, pain will be less allowing for the return
of range of motion as the healing process gains momentum and inflammation is
decreased.
6. HBOT increases the production of collagen:
Following the initial healing process of the inflammatory
response and the prevention or removal of infection, comes the next chapter in
tissue/wound healing.
Collagen is the connective tissue developed and laid down by
fibroblasts, the repair cells of the body. Collagen acts as a base layer in the
healing wound and assists the wound to close and repair. The formation of
collagen and hence wound healing/recovery is highly dependent on the presence
of adequate amounts of oxygen. The actual production of collagen by fibroblasts
is also extremely dependent on oxygen availability.
As hyperbaric oxygen therapy markedly increases the oxygen
available within the blood this in turn enables for a cross-linking or
strengthening of the tissues, and fibroblasts to produce increased amounts of
collagen required for healing of wounds and tissue damage.
7. HBOT increases growth of cells that form reparative tissue
(Fibroblastic proliferation)
Clinical research has demonstrated that a number of days
following injury there occurs a migration of fibroblasts (connective tissue
cells responsible for collagen production) into the area of damage. These cells
then divide and replicate producing large amounts of collagen (connective
tissue used to repair damage to tissue) that acts as the building block for the
healing of tissue and wounds.
The development and migration of fibroblasts is assisted by the
influx of oxygen resulting from hyperbaric oxygen therapy, this then supports
the development and action of these particular cells which play a vital part in
the healing/recovery process.
8. HBOT supports scar tissue rehabilitation:
A decrease in oxygen available to cells such as fibroblasts
impairs their action, impacting upon the healing of tissue, causing healing to
take longer, and inhibiting the quality of scar tissue developed or
rehabilitated, which in turn greatly decreases tissue strength.
Healing occurs both faster and stronger in wounds/injuries that
are treated with hyperbaric oxygen therapy due to the demands of oxygen
availability by the cells and tissues responsible for the healing process being
met.
9. HBOT promotes greater tissue strength:
As the oxygen concentration of the blood increases during
hyperbaric oxygen therapy, cells further from blood vessels are more adequately
oxygenated. Hyperbaric oxygen therapy allows for increased oxygen availability
in more extensive areas enabling fibroblasts to carry out their part of the
healing process for tissue damage and injury, more rapidly covering larger
areas.
Hyperbaric oxygen therapy saturates the blood plasma with oxygen,
this in turn reaches the areas of damage/injury with greater efficiency than
red blood cells, providing all cells and tissues with the much needed agent for
healing, oxygen. The cells responsible for the development of scar tissue for
healing are then able to carry this out more rapidly and the resulting tissue integrity
is stronger.
10. HBOT enhances the growth of new blood vessels (Angiogenesis)
Injury or damage to tissues also results in damage and
destruction of the supporting blood vessel structures. The healing process is
reliant on these structures for supply of the blood containing the cells and
nutrients that carry out and enable healing as well as the removal of damaged
cells, debris and foreign micro-organisms.
Research has demonstrated that treatment with hyperbaric oxygen
therapy significantly increases the number and actual size of blood vessels in
damaged tissues and wounds. This allows the healing process to occur faster
speeding the recovery of the injury or wound.
11. HBOT increases oxygen levels in tissues (Hyperoxia)
With an increase in oxygen availability resulting from both
blood that is highly saturated in oxygen dissolved in the plasma, and an
increase in the number of blood vessels due to new vessels being created as
well as the healing of damaged blood vessels, tissues and cells become highly
saturated in oxygen.
12. HBOT increases oxygen perfusion area around wounds:
Oxygen perfusion around wounds and damaged tissues is greatly
increased when the blood supply to these areas possesses greater than normal
levels of oxygen within blood plasma as well as carried on red blood cells. The
oxygen contained in the blood plasma is more easily accessible than that
carried to the tissues and cells of the wound/damaged area on red blood cells,
and this method of oxygen supply is less labour intensive and energy taxing.
The cells involved in the healing process are highly dependent on
oxygen to carry out their healing function and this increased demand for oxygen
in the area around wounds by the increased number of healing cells in that
location is met by the increased oxygen saturation of the blood following
hyperbaric oxygen therapy.
13. HBOT stimulates new capillary growth:
During the time of injury and damage the microcirculation and
the blood vessels of this circulation (capillaries) are vital to the healing
process through the supply of nutrients and oxygen and the removal of waste and
debris to enable the cells responsible for healing to successfully complete
their function.
Growth of new, and repair of damaged capillaries are stimulated
within the damaged tissues by hyperbaric oxygen therapy, providing increased
oxygen availability to these areas. The increased oxygen supply and increased
pressure employed by hyperbaric oxygen supply are both responsible for the
stimulation of new capillary growth and the repair of existing capillaries.
14. HBOT improves the survival of tissues in the ‘grey area’ of
crush injuries
The ‘grey area’ of crush injuries can be defined as the area
between the tissues that are obviously irreversibly damaged and those tissues
that are undamaged. The tissues of the ‘grey area’ benefit greatly from
increased oxygen supply, improved circulation and blood supply. These are the
aspects that will allow the tissues of the ‘grey area’ to be saved, salvaged
and repaired.
Hyperbaric oxygen therapy has been shown to support and maintain
tissue oxygenation within the ‘grey area’ resulting in a better outcome for the
tissues, wound or injury.
15. HBOT increases production and improves the action of
Osteoblasts and Osteoclasts
Osteoblasts are the cells responsible for bone formation and
osteoclasts are the cells responsible for bone reabsorption. Both these cells
work together to form bones and control the amount of bone tissue.
The provision of increased levels of oxygen allows for increased
production of these cells and enables them to conduct bone repair and formation
more adequately through the reduction of edema and growth of new blood vessels
in the micro-circulation.
16. HBOT improves bone regeneration for faster recovery
When the inflammatory process, swelling and edema is rectified
more rapidly the repair and regeneration of bone is able to commence sooner.
With the increase in blood supply and oxygen availability, the
tissues and cells responsible for bone regeneration are able to carry out their
task of healing more efficiently, resulting in accelerated recovery and a
better result in the healing tissues.
17. HBOT helps prevent infection
Research has demonstrated that having lower oxygen levels in
tissues and wounds increases the possibility of infection. Changes in wound and
tissue oxygenation impacts greatly upon the wound immune mechanism.
Having an improved or increased tissue oxygen supply reduces the
incidence of wound infection as the cells responsible for prevention and
recovery from infection are dependent on oxygen, therefore additional oxygen
benefits the healing process.
18. HBOT increases white blood cell production
The major players in the bodies immune response are the white
blood cells. Providing the body with increased oxygen availability increases
the production of white blood cells providing benefit to the bodies immune
response.
High-dose oxygen delivered under pressures greater than sea level
(hyperbaric oxygen therapy), stimulates and enables the bodies immune
response
19. HBOT enhances ability of white blood cells to remove
bacteria and debris (Leukocyte activity)
Without oxygen or in a hypoxic (shortage of oxygen in the body)
environment the function of white blood cells becomes diminished. This in turn
provides a significant threat of infection as the bodies immune response is
impaired.
The increased oxygen supply offered by hyperbaric oxygen therapy
assists in bacterial killing through improving leukocyte (type of white blood
cell) function.
Research has demonstrated that periods of hyperoxia (increased
oxygen levels in tissues) and hyperbaric oxygen therapy has influenced the
activity of some antibiotics, enhancing their effectiveness. This enables the
presenting infection to resolve quicker.
21. HBOT destroys harmful bacteria (Antimicrobial effect)
Hyperbaric oxygen therapy provides direct bactericidal
(substance that kills bacteria) and bacteriostatic (hampers the growth of
bacteria) effects against bacteria due to the generation of oxygen free
radicals. These free radicals are able to damage the membranes and make up of
the bacteria rendering them ineffective or killing them.
Anaerobic (without oxygen) organisms find an increased oxygen
environment toxic and are unable to survive.
22. Hyperbaric Oxygenation Effects the Blood Flow
Normal blood flow: There is 21% oxygen in the air that we breathe, and our lungs transfer this oxygen to our red blood cells (via hemoglobin). These oxygen-filled red blood cells are carried around the body by the plasma (fluid), which travels through the blood vessels. The oxygen diffuses into the surrounding tissue ensuring that it is delivered to where it is needed most.
Normal blood flow: There is 21% oxygen in the air that we breathe, and our lungs transfer this oxygen to our red blood cells (via hemoglobin). These oxygen-filled red blood cells are carried around the body by the plasma (fluid), which travels through the blood vessels. The oxygen diffuses into the surrounding tissue ensuring that it is delivered to where it is needed most.
Veterinary Hyperbaric oxygen therapy often called VHBOT can be of great help to veterinary patients by speeding up the healing process and may reduce or eliminate the need for more invasive procedures such as surgery, oftentimes resulting in a net savings of time and cost of treatment for pet owners.
HELPING YOUR VETERINARY PATIENTS
HEAL FASTER & LIVE LONGER.
Affordable to pet owners
Profitable to your center
Profitable to your center
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