Goleta Deep Tissue, Best Sports Massage Santa Barbara

Can Sports Massage Really Flush Out Lactic Acid?

It was long believed that lactic acid build up was the main reason your muscles got sore and tired shortly after a heavy workout (delayed onset muscle soreness- DOMS).  It was also thought that sports massage was the magic bullet for flushing out that lactic acid.

As it turns out, lactic acid (or blood lactate) is a natural by-product of any muscular activity, such as running or cycling.  It provides an energy source for working muscles and helps in the process of wound repair and regeneration.

By the time the athlete is lying on the massage table, the lactic acid has already left the muscles.  So how does one explain all that post-exercise muscle soreness?  According to Sports Medicine specialist, Dr. Gabe Mirkin, “next day muscle soreness is caused by damage to the muscle fibers themselves.”  He suggests that one should stop exercising before their muscles start to hurt. That burning sensation is the nervous system’s way of alerting you that your muscles are running out of energy, and if you push them anymore, you will inevitably experience DOMS.

However, if you do experience the muscle fatigue and soreness, there’s good news! Current research supports that massage can be effective in reducing DOMS.

Goleta Deep Tissue -Sports Massage Doesn’t Flush Toxins, but May Help You Recover

Should you spring for a stint in the post-marathon massage tent? Get a regular rubdown to help your recovery as you train? Research shows that sports massage doesn’t always do what you think it does—but it may still help you recover from a tough workout.

Most importantly: Sports massage doesn’t flush lactic acid, or other “toxins,” from your muscles. Lactic acid is produced during exercise, and you might associate it with a burning feeling during hard work, but it’s not a problem, isn’t responsible for next-day soreness, and doesn’t need help to be removed from the muscles.

Go to this link for:

10 Stubborn Exercise Myths that Won’t Die, Debunked by Science

Massage does help to relax muscles, though, which can help to relieve tight muscles. The same action can break up adhesions, a type of scar tissue that sometimes forms in muscle.

Where massage shines, though, is in promoting recovery. Studies testing massage as a recovery technique are inconsistent. Sometimes it helps, sometimes it doesn’t, and the differences may come from the different types and timing of massage that the studies use. Still, recent studies have shown that massage, in humans and in rabbits, improves the ability of muscles to repair themselves after a workout. If you can’t afford regular sports massage from a professional, a good strategy may be self-massage with tennis balls and foam rollers.

Flushing Out Myths

Great article from Massage Today
December 2002, Vol. 02, Issue 12

By Keith Eric Grant, Ph.D., NCTMB

“The tragedy of science is a beautiful hypothesis slain by an ugly fact.”

-Thomas Huxley

There’s a statement, seemingly pervasive throughout massage education and massage books, that unspecified toxins accumulate in the body, and that these toxins can be flushed out by massage.

A more significant issue is whether metabolic wastes and cellular debris can significantly accumulate and be flushed out by massage. To elucidate a negative response to this, I turn to a consideration of the circulation of blood and lymph. If the tissue is to accumulate wastes in a static manner, i.e. not as an instantaneous balance between production and removal, the tissue must be isolated. If we assume that the tissue is isolated from blood circulation, then necrosis (cellular death) is the rapid consequence. Such gangrene is, for example, one of the results of the vascular pathology of diabetes. We have to conclude that non-gangrenous tissue must be receiving oxygen and nutrients via circulation and that, for this to continue, venous return flow must also be occurring. If the toxins are accumulating, they cannot be doing so within the reach of the circulatory system. Perhaps we should look instead in the interstitial spaces served by the lymphatic system.

As noted by Bruno Chikly, the lymphatic system is a second pathway back to the heart, parallel to the blood system [2, pg. 27]. Chikly further notes that “about 1.5 to 3.5 liters of lymph per day circulate through the thoracic duct, although the total volume of the flow of lymph has yet to be precisely measured” [2, pg. 51] and expands on the process of lymphatic circulation.

“Part of the constituents of the blood will filter out of the blood capillaries. This blood capillary filtrate will join the surrounding tissues, passing through the interstitial environment (interstitium) – the interstices between each cell, to be further reabsorbed in the lymphatic capillaries. The lymphatic system fine tunes the drainage of the interstitium (connective tissue) and thus constitutes a sort of “overflow” for the water and excess substances in the interstitial environment. In fact, if the lymphatic system did not recover the protein-rich liquid (a large part of which the venous system cannot recover), the body would probably develop major systemic edemas (protein loss), auto-intoxication and die in 24 to 48 hours [2, pg. 27]… About 75 to 100 g. proteins per day can escape from the blood circulation; this is about 50% of the protein circulating in the blood plasma per day. These proteins are transported in the lymphatic vessels. Proteins which have escaped into the interstitium are recovered by the lymph circulation [2, pg. 29].”

What arises is a picture of tissue far from being in static isolation. If neither necrosis nor severe edema is to result, the tissue environment must be continually bathed in the fluid circulations of blood and lymph, ruling out the accumulation of free toxins. Where there are restrictions, such as adhesions between fascial planes, they must be of a more macroscopic nature, still allowing for the microscopic flow of circulation, just as water can flow through cheesecloth.

Based on the above considerations, I can only conclude that the flushing of toxins is yet another persistent myth. However, this does not imply that massage is powerless to benefit the body. While massage does not appear to directly increase overall blood flow [4], it can be used to relax muscle hypertonicity. Lowering the level of muscle activity will locally reduce the need for energy and oxygen and the rate of production of metabolic wastes. It will also reduce the muscular pressure on surrounding tissues, effectively improving circulation and recovery from use. This, however, is not massage moving out toxins, but massage facilitating a better homeostasis. It is just this improvement in homeostasis by which, I believe, massage facilitates recovery from exercise and allows a higher level of training to occur.

In cases of excess lymphatic fluid production (overloading a normally functioning lymphatic system), or partial lymphatic system compromise, lymphatic drainage massage may be helpful in promoting the process of lymphatic filtering. The key sign here is the existence of edema. Normally, local muscle contractions promote sufficient lymph drainage. A notable exception exists with breast tissue. Since there is no contractile tissue within the breast to assist lymphatic drainage, overall tissue movement becomes important [3, pg. 101].

There remains a consideration that some clients respond to a message with reactions of flu-like aches and malaise. Such symptoms have often been attributed to the toxins released. Dispelling the concept of toxins means that we must seek other explanations for such post-massage malaise. Chaitow notes that fibromyalgia syndrome (FMS) and chronic fatigue syndrome (CFS) are the distant ends of spectrums of dysfunction that can include aches, malaise, and flu-like symptoms [1, pg. 6]. He believes that a great many people are somewhere on those spectrums. Some of the models of dysfunction that Chaitow presents include a sort of systemic allergic reaction characterized by a great deal of pain, either muscular and/or joint-related [1, pg. 33]. Chaitow also notes the hypothesis that the inability to produce an adequate cortisol response to a stress can result in symptoms: “Deficiency in cortisol is characterized by fatigue, weakness, muscle, and joint pain, bowel symptoms, nausea, increased allergic reactions, mood disturbance” [1, pg. 68]. I tend to think of a body’s neurochemical system on the edge of its ability to adapt being pushed temporarily beyond the edge by accommodating to the work being done. This reaction may be exacerbated by effects of athletic overtraining or by a genetic metabolic predisposition [5,6].

“When people are very ill, as in FMS/CFS, where adaptive functions have been stretched to their limits, ANY treatment (however gentle) represents and additional demand for adaptation (i.e. it is yet another stressor). It is therefore essential that treatments and therapeutic interventions are carefully selected and modulated to the patient’s current ability to respond, as best as this can be judged. – Leon Chaitow [1, pg. 240]”

To explain the effects of massage, think not of flushing out toxins, but flushing out tensions – not just in the sense of emotional holding, but in the basic sense of muscles “idling” with the throttle open. As with good mechanics, we’re simply readjusting the throttle to a reasonable idle rate. Underlying this way of looking at things, however, is a fundamental shift in orientation from mechanically moving something that accumulates to changing a dynamic balance within the living human body. It is, I believe, an important shift away from mythology and toward a better understanding of our work.


  1. Chaitow, Leon, 2000: Fibromyalgia Syndrome — A Practitioner’s Guide to Treatment, Churchill Livingstone, ISBN 0-443-06227-7.
  2. Chikly, Bruno, 2001: Silent Waves – Theory and Practice of Lymph Drainage Therapy. I.H.H. Publishing, Scottsdale, AZ, ISBN 0-970-05305-3.
  3. Curties, Debra, 1999: Breast Massage. Curties-Overzet Publications, ISBN 0-968-52561-X, (www.sutherland-chan.com/copi/breast.htm).
  4. Shoemaker, JK, PM Tiidus, and R.Mader, 1997: Failure of manual massage to alter limb blood flow: measures by Doppler ultrasound. Medicine & Science in Sports & Exercise, 29(5), 610-614.
  5. Tarnopolsky, Mark A., 2002: Metabolic myopathies and physical activity. The Physician and Sportsmedicine, 30 (6), (www.physsportsmed.com/issues/2002/06_02/tarno.htm).
  6. Uusitalo, Arja L.T., 2001: Overtraining – making a difficult diagnosis and implementing targeted treatment. The Physician and Sportsmedicine, 29 (5), (www.physsportsmed.com/issues/2001/05_01/uusitalo.htm).
  7. Walsh, William J., 1996: Metal-Metabolism and Human Functioning. Pfeiffer Treatment Center, (www.hriptc.org/metal_metabolism.html).
  8. World Bank Group, 2001: What Are Persistent Organic Pollutants (POPs)? (http://lnweb18.worldbank.org/ESSD/essdext.nsf/50ByDocName/

Benefits of Sports Massage & Recovery Time – Goleta Deep Tissue

Sometimes a “truth” is not what it seems. Take lactic acid. For years, many massage therapists have been taught that lactic acid can and should be flushed from the muscles of athletes after intense activity. This truism has been passed on to clients who have also accepted it as fact. Both therapist and client thus have established and perpetuated a mutual belief system that purging of lactic acid is not only necessary but also efficiently accomplished with the assistance of massage. Some beliefs die hard. This one and others related to lactic acid have been holding their own, not only in some massage schools and practices but also in the community at large, despite emerging research to the contrary. Pass the word. There’s no need to mess with Mother Nature.

Lactate accumulated from intense exercise actually fuels the body, according to Dr. Owen Anderson, exercise physiologist, and editor of Running Research News. In a recent interview from his office in Michigan, Anderson explained the facts.

Lactic acid levels will return to homeostasis quickly post-exercise without any “hands-on” assistance. “Muscles don’t need help from massage in removing lactate,” said Anderson. “Massage will probably have the biggest effect on venous blood,” and by the time massage is administered, lactate has already left the muscle. This is not to say massage isn’t beneficial to the athlete. “Massage is good for relaxing,” said Anderson, “and provides help increase the flexibility of muscles.”

Whitney Lowe, owner and director of Orthopedic Massage Education and Research Institute and author of Functional Assessment in Massage Therapy concurs with Anderson’s statements.

“Lactic acid is a natural by-product of any muscular activity. There are elevated levels of lactic acid in muscle tissues after exercise, but that is going to subside either with time or with any type of movement activity, even just walking around the room.”

In addition, lactic acid does not cause muscle soreness, fatigue or the “burn” of intensive exercise, noted Anderson. His comments and those of Lowe are backed by valid scientific research. Several studies conducted in the 1980s by exercise physiologist Dr. George A. Brooks ushered in a new perspective on this supposed “demon.” Brooks noted that lactic acid is a key substance for providing energy, disposing of dietary carbohydrate, producing blood glucose and liver glycogen and promoting survival in stress situations.1

Nature’s Magic Tricks
Just as the body’s intelligence keeps our hearts pumping and our intestines digesting without any intervention on our part, in like manner it maintains the chemical process of glycolysis to provide energy on a 24-hour basis. In Anderson’s book, Lactate Lift-off, he writes, “Glycolysis is actually a series of 10 different chemical reactions…that break down glucose, the simple six-carbon sugar which is your body’s most important source of carbohydrate fuel, into something called pyruvic acid.”2 From pyruvic acid, with the help of the enzyme lactate dehydrogenase, we get lactic acid. But it’s not quite that simple.

The process of glycolysis converts each glucose molecule into two pyruvic acid molecules, releasing energy in the form of adenosine triphosphate (ATP). From there, pyruvic acid enters the mitochondria, where more ATP is produced through the Krebs cycle.3 “In addition to ‘handling’ the pyruvic acid produced from glucose,” states Anderson, “the Krebs cycle also metabolizes fats, overall, it furnishes more than 90 percent of the energy you need to exercise in a sustained manner.”4

As exercise intensity increases, glycolysis speeds up and pyruvic acid is produced at an increasing rate. When it can no longer be processed through the Krebs cycle as quickly as it is generated, some of the pyruvic acid is converted to lactic acid, which rapidly dissociates into a lactate anion and a free hydrogen ion (H+). Lactate can then be quickly transported from the muscle into the blood, where it is circulated throughout the body. If an excessive amount of pyruvic acid were allowed to build up, glycolysis would come to a halt, thus blocking energy production. The conversion to lactic acid allows the body to continue its exertion of energy. Once the lactate enters other tissues, it can be converted to pyruvate, which is processed by the Krebs cycle into ATP for even more energy. Lactate can also be converted by the liver and other tissues into glucose, boosting depleted stores of glycogen needed for future activity.5,6,7

Although the focus here is to examine excessive lactic acid accumulation during intensive activity, it’s important to clarify that lactic acid production is a normal and continuous part of the body’s energy cycle. According to Anderson, lactate is produced even at rest and “…its concentrations can rise rather dramatically whenever you take in a carbohydrate-containing meal.” Lactate plays an important role in processing carbohydrate and facilitating its availability to the liver and muscles.8

Lactic acid reaches excessive levels when the body can no longer clear it as quickly as it is being produced. “When you begin a moderate to difficult workout,” states Anderson, “lactate levels in your blood initially rise, simply because glycolysis is working away to provide quite a bit of the energy you require.” At this point, there is minimal blood and oxygen flow to the muscles. This limits the breakdown of pyruvate in the Krebs cycle and increases its conversion to lactate. With continued activity, heart rate increases and oxygen becomes more readily available to the muscle cells, allowing pyruvate and lactate to be oxidized for energy. The entry and exit rates of lactate then become stabilized and will remain so even with gradually intensified activity.9

“However,” states Anderson, “once you get up to a point (actually a speed) at which glycolysis is tearing along so fast that your leg muscles have problems converting most of the pyruvate and lactate being formed to carbon dioxide and water, the lactate-spilling process may accelerate so much that lactate levels in the blood may really begin to lift off.” This can be a result of oxygen debt inside the muscle cell, inadequate concentrations of enzymes necessary for oxidation at high rates or a lack of sufficient cell-mitochondria, where the Krebs cycle takes place. The point at which this occurs is referred to as the lactate threshold (LT). According to Anderson, the LT is simply an indicator of how effectively your tissues utilize lactate as an energy source. For athletes, a high LT means increased endurance – the longer the athlete can perform before reaching this point, the longer lactate production and extraction is kept in balance and energy is maintained.10

At the completion of exercise, lactate levels will return to normal within 30-60 minutes, being quickly converted back to pyruvate or glucose.11 Research supports the claim that active recovery (light exercise) is the most effective approach to speed up this process,12,13 and that massage is no more effective than passive rest.14 This does not discount other potential benefits of massage in sports recovery. A study by Monedero and Donne showed while active recovery proved best in removing lactic acid, a combined approach (active recovery and massage) did increase recovery rate during short intervals between maximal efforts and was most efficient for maintaining maximal performance time in subsequent performance. Recovery rate was determined by blood lactate levels and heart rate during recovery, and performance times in tests of maximal efforts.15

For post-exercise recovery, Anderson recommends a cool-down of about 10 minutes or running a few miles followed by stretching and strengthening exercises, nutrition (carbohydrates) to restock energy and a good night’s sleep. Improving the body’s ability to break down pyruvate, use oxygen and extract lactate from the muscle during activity will raise the LT and increase an athlete’s endurance. This can be accomplished with proper training, such as methods recommended in Lactate Lift-off.16 An effective training approach can increase the supply of mitochondria, enzymes and capillaries needed to enhance the body’s ability to rapidly use lactate as an energy source.17

Soreness, Fatigue and the ‘Burn’
Is lactic acid to blame? “There has been a strong suggestion,” said Lowe, “that delayed onset muscle soreness (DOMS) occurring 12-24 hours after exercise is caused by excess levels of lactic acid, but the onset of soreness does not at all coincide with the levels of lactic acid. This is still a very rampant misconception.”

Anderson indicates there are two likely causes of muscle soreness: tears in the muscle associated with the stress of exercise and free radical attack on the muscle membranes. According to physician Dr. Gabe Mirkin,”Next-day muscle soreness is caused by damage to the muscle fibers themselves. Muscle biopsies were taken on the day after exercising show bleeding and disruption of the z-band filaments that hold the fibers together as they slide over each other during a contraction.” Mirkin suggests ceasing exercise when muscles start to burn and hurt as this is likely an indication that DOMS will occur.18

The free hydrogen ions produced by dissociation of lactic acid can present a problem. Bicarbonate buffers H+ to maintain homeostasis in pH, but an increase of H+ during intensive exercise can overwhelm the buffering system, resulting in acidity (low pH) of muscle and blood. If the pH goes below 7.00, the athlete may experience nausea, headache, dizziness, and pain in the muscles. But with cessation of exercise the pH, like lactate returns to normal.19 “The muscle will slow down if there is a great enough lowering of pH,” said Anderson, “and this may cause fatigue.” He noted there can be a lowering of pH in muscles even while sedentary. “We don’t know if it can cause a burn,” he added, “but the burn is the nervous system’s way of telling you you’re exercising at a too high intensity and you need to cut back. There is nothing wrong. It’s just a message.”

Heavy legs or fatigue can occur in an all-out sprint, said Anderson, but if it occurs at the 20-mile point in a marathon, it’s a sign the muscles are running out of energy. To combat these problems, Anderson emphasizes the importance of training. “If you are really strong,” he said, “you have less stress and damage.”

So What About Massage?
Although the effectiveness of massage to flush out lactic acid after exercise has been disproven, there are benefits to validate its use in sports. “In my own experience,” said Keith Grant, head of Sports and Deep Tissue Massage Department at McKinnon Institute, “I’ve seen that massage is effective. How our body reacts to things depends on both the state our body is in (state of memory), as well as the input.” Grant combines his knowledge as a scientist with personal experience as a massage instructor and runner to support his conclusions.

Pointing to a study by Tiitus and Shoemaker (1995) in which effleurage did not increase local blood flow, Grant said, “This is a mechanistic way of looking at what’s going on.” The difficulty, he noted, in interpreting research results comes from looking for direct, mechanical effects. “Clinically, we see a different story,” he said. “Through our techniques, we work with the nervous system to relax muscles, but that’s not a direct mechanical effect. “I believe the effects of massage also involve the neurological and emotional. My reason for that is the neurological side controls the current (base) state of the muscle activation. The emotional controls the chemical messengers that affect the immune system. What seems likely is massage acts as a new input to a system with a memory. Massage stimulates the mechanoreceptors and can gate off pain receptors. It floods the body with new sensory input. We are using the nervous system to reset the muscle to greater relaxation.

“In my observation, fatigued muscles tend to remain hypertonic and shortened. When we cajole specific muscles to relax and lengthen via mechanical and neurological input, we reduce their metabolic activity. When the muscle relaxes, it’s not using energy as much, not metabolizing as fast, not producing waste products and because it’s more relaxed, it’s not compressed and not exerting pressure on surrounding tissues. This means circulation is better. It’s not because we’re pushing fluid around. It’s because we’ve put the body in a more optimum state, so the body naturally increases circulation on its own. By massaging muscles and adding input to the nervous system, we are facilitating the body in recovering faster from exercise. It’s not the massage that’s doing the healing, it’s the person’s body.”

In a British study of boxers, massage was reported to have a significantly positive effect on the perception of recovery, giving scientific credence to its benefits as a recovery strategy. According to the authors, their results support arguments by some researchers that “the benefits of massage (in sports recovery) are more psychological than physiological.”20 Grant takes that a step farther. “As a trained scientist, I use what I observe and what I know about physiology to come with a hypothesis. From my own experience in running, when you exert to the point of substantial fatigue, you come back feeling more fragile, in an emotionally vulnerable spot. To have the sense that someone is nurturing, in a sense taking care of you, is a very psychologically emotional thing. In supporting the person, we improve their immune function and their ability to heal, by influencing the chemical environment of their body. It has to do with psychoneuroimmunology, the whole chemical homeostasis of their body — neurochemicals and the relationship between mood, or feelings, and the immune system.

Originally published in Massage & Bodywork magazine, October/November 2001.
Copyright 2003. Associated Bodywork and Massage Professionals. All rights reserved.

“There is some evidence that following heavy exercise, both L-glutamine (an amino acid manufactured by the body) and the immune system take a dip. I look at the healing effect of massage as, in some way, counteracting that dip. When you provide support it has a positive effect on immune function. If the person doesn’t feel supported and nurtured, it will have a negative effect on the chemical environment, opening them more to catching colds, not healing as fast and decreasing their ability to train. It ties into the whole emotional state of a person. The athlete has to stay healthy in order to continue training. With massage, they can train harder because they are able to recover faster.”

Facts vs. Myths
Remember the old theory about the earth being flat? The more we learn, the more we realize how much we don’t know. That’s why research in massage is so important. “These concepts and ideas are firmly entrenched in our early training, and in the medical profession, said Lowe. “Things that have been disproved continue to persist. It takes a long time to trickle down. If we say there is no research that supports massage works for inflammation, there may not be research – or it may not be true. We don’t really know yet and we need to investigate that further. This lactic acid concept illustrates the perpetuation of misinformation that can happen if we don’t have the research base. When we are looking for credibility with others in health care, they want to know what we base our opinions. A lot is passed along on hearsay, not on scientific information. What we need to keep our eyes on is how to reduce that as much as possible so we do have accurate information.”

Trigger Points

What is a Trigger Point? from Goleta Deep Tissue

Trigger points, also known as trigger sites or muscle knots, are described as hyperirritable spots in skeletal muscle that are associated with palpable nodules in taut bands of muscle fibers.[1]

The trigger point model states that unexplained pain frequently radiates from these points of local tenderness to broader areas, sometimes distant from the trigger point itself. Practitioners claim to have identified reliable referred pain patterns which associate pain in one location with trigger points elsewhere. There is variation in the methodology for diagnosis of trigger points and a dearth of theory to explain how they arise and why they produce specific patterns of referred pain.[2]

Compression of a trigger point may elicit local tenderness, referred pain, or local twitch response. The local twitch response is not the same as a muscle spasm. This is because a muscle spasm refers to the entire muscle contracting whereas the local twitch response also refers to the entire muscle but only involves a small twitch, no contraction.

Among MDs, many specialists are well versed in trigger point diagnosis and therapy. These include physiatrists (physicians specializing in physical medicine and rehabilitation), family medicine, and orthopedics. Osteopathic, as well as chiropractic schools, also include trigger points in their training.[3]Other health professionals, such as occupational therapists, physiotherapists, acupuncturists, massage therapists and structural integrators are also aware of these ideas and many of them make use of trigger points in their clinical work as well.

Please visit this link for more information.

From Wikipedia


Trigger Points



*Disclaimer: This information is not intended to be a substitute for professional medical advice. You should not use this information to diagnose or treat a health problem or disease without consulting with a qualified healthcare provider.
Please consult your healthcare provider with any questions or concerns you may have regarding your condition.
The information provided is for educational purposes only and is not intended as diagnosis, treatment, or prescription of any kind. The decision to use, or not to use, any information is the sole responsibility of the reader.

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