Causes of peripheral neuropathy are varied, but trauma is by far the most common cause of mononeuropathy. Direct pressure to a peripheral nerve is the cause of some of the more common mononeuropathies that we know including tarsal tunnel syndrome, anterior tarsal tunnel syndrome and carpal tunnel syndromes. Particular activities can contribute to direct pressure neuropathies such as sitting on a wallet (back pocket sciatica), habitual crossing of the legs (peroneal palsy), gardening, stooping or working in jobs with repetitive mechanical duties. Mononeuropathies are very common in foot care and can be the result of lacing your shoes too tight or wearing shoes that cut into the top of the foot such as clogs. Direct pressure to the top of the foot can inhibit normal nerve conduction and result in sensory loss on the top of the foot and in the toes.

Other forms of trauma that may contribute to mononeuritis include sprains or dislocations. The use of power tools, such as routers, saws and jack hammers has been known to cause single or multiple mononeuritis. Micro-organisms may cause mononeuritis as seen with conditions such as herpes zoster, or shingles. TB, leprosy, diptheria and malaria may be other causes of mononeuritis.

Polyneuropathy may be caused by a host of conditions. It may be symmetrical or asymmetrical and may effect the feet, the hands or both the feet and hands together.

Causes of polyneuropathy

Collagen vascular conditions - Systemic lupus, scleroderma, sarcoidosis, diabetes or Lyme's Disease

Toxic agents - Chemicals and drugs include emetine, hexobarbital, barbital, chlorobutanol, sulfonimides, phenytoin, nitrofurantion, vinca alkyloids, heavy metals, carbon monoxide, triorthocresylphosphate, orthodinitrophenol

Nutritional deficiencies and metabolic disorders - Vitamin B deficiency, malabsorption syndromes, hypothyroidism, porphyria

Diabetes - diabetic peripheral neuropathy.

Peripheral arterial disease (PAD) - advanced PAD results in ischemia of the peripheral nerves.

Peripheral nerves function by the in-flow and out-flow of sodium (Na) and potassium (K). As the content of these two chemicals changes in the nerve, the electric potential shifts sending an electric charge through the nerve. Any external influence, such as trauma, diabetes etc, will influence the normal distribution of charge through the nerve.

The stage of peripheral neuropathy (including both mononeuropathy and polyneuropathy) can be categorized in three stages;

Stages of peripheral neuropathy

Stage 1- Slight loss of vibratory sensation, proprioception light touch and sharp/dull differentiation. Patient may or may not perceive sensory loss. EMG studies typically negative for change. Onset and duration varies.

Stage 2 - Apparent loss of vibratory sensation, proprioception light touch and sharp/dull differentiation. Patient does perceive sensory loss but does not typically experience severe pain. EMG studies typically positive for change. Onset and duration varies.

Stage 3 - Advanced loss of vibratory sensation, proprioception light touch and sharp/dull differentiation. Patient does perceive sensory loss and experiences sharp shooting or dull achy severe pain. EMG studies show advance change. Onset and duration varies.

The onset and duration of peripheral neuropathy varies in each individual case. As an example, the onset, severity and duration of peripheral neuropathy secondary to diabetes would vary based upon many factors including fluctuations in blood sugar levels and how compliant the patient has been over the course of treatment for their disease. In cases of traumatically induced peripheral neuropathy, similar variables apply such as the severity of the injury, the duration of injury prior to seeking care, etc.

Neurological testing for peripheral neuropathy may include testing for the ability to sense vibration, differentiation between warm and cold, differentiation between sharp and dull touch and the ability to tell where one is in space (proprioception). A Semmes Weinstein monofilament testing device is a common tool used today. This tool looks like a ball point pen and contains a 5mil monofilament wire. The monofilament wire is touched to the skin to determine the amount of sensory loss. Individuals with peripheral neuropathy will loose the ability to sense the touch of the monofilament wire.

EMG (electromyelogram) studies help to quantify the degree of neuropathy and can be used to establish a base line or monitor change in the progression of peripheral neuropathy. This test uses an electrical signal which is sent along the course of the nerve and timed. When compared to normal values, any variation, such as delay in the normal conduction rate may indication a form of damage that the peripheral nerve has sustained.

Treatment of mononeuropathy and multiple mononeuropathy

The first step in treating mononeuropathy and multiple mononeuropathy is attempting to identify a source of entrapment. A thorough history and physical exam by your doctor should include evaluation of lumbar disc disease, back and leg pain and focal evaluation of specific peripheral nerves. It's important to evaluate peripheral nerves from their origin in the spine to the site of pain.

Focal entrapment of peripheral nerves is common. Entrapment can be caused by adjacent tissue structures that impinge upon the nerve. Impingement can be caused by normal anatomy including ligaments, veins or muscles. Soft tissue tumors such as a ganglionic cyst are a common reason for impingement of a peripheral nerve in an enclosed space. Varicose veins and soft tissue tumors can also be a contributing factor in tarsal tunnel syndrome. If soft tissue tumors or varicosities are suspected, these tumors should be removed. Removal of the tumor should be performed in conjunction with a peripheral nerve release.

Painful mononeuropathy can be treated with several methods that focus on the destruction of the contents of the nerve. Destruction of the nerve contents is accomplished by a technique called neuroablation. Neuroablation can be performed in a number of ways. These methods include chemical ablation, radiofrequency ablation or cryoablation. The most common method of chemical ablation employes 4% absolute alcohol. A series of 5-7 injections are performed over a period of time, separated by 1 week intervals. Radiofrequency neuroablation and cryoablation are typically performed in a surgical center of hospital on an outpatient basis.

Transection and transposition of painful mononeuritis is uncommon. Transection and transposition is performed in cases of reclacitrant pain. The individual nerve that is contributing to mononeuritis is cut and transposed into living tissue. This tissue is typically muscle or bone. Transposition is used to inhibit the growth of stump neuromas following transection.  The following images show transection of the sural nerve with transposition of the nerve into the soleal muscle of the lower leg.  This procedure was performed for recalcitrant pain of the lateral foot following a crush injury.

Treatment of polyneuropathy

The single most important step to be taken in the treatment of peripheral neuropathy is the identification and elimination of the primary cause of the neuropathy. For instance, in diabetes, the single most important issue affecting DPN is serum glucose levels. Controlling the onset of DPN is best managed by decreasing serum blood sugar levels. Once the primary contributing factors are removed, the nerve may have an opportunity to regenerate. Supportive efforts are helpful during this phase of repair and include nutritional support and the use of anti-oxidants. The following are some of the supportive measures that can be used in stages 1-3 of peripheral neuropathy;

Pyridoxine (B6) has been used for years as a method of nutritional support following peripheral nerve damage. Vitamin B6 is water soluble and can therefore be eliminated by your body. Common doses range as high as 250mg/day.

Exciting new treatment modalities for peripheral neuropathy includes the used of anti-oxidants. These scavengers of the body are used to eliminate toxins which may contribute to peripheral neuropathy. Anti-oxidants used to treat peripheral neuropathy include gamma-linoleic acid and alpha lipoic acid (thiotic acid). Alpha lipoic acid increases glucose uptake in muscle and fat cells to improve both the symptoms of DPN and diabetes. It has also been suggested the alpha lipoic acid may help treat insulin resistance. A study by Tankova et al. showed up to a 65% reduction in the symptoms of DPN with high doses of alpha lipoic acid.

Other treatment may include the use of metabolic factors or medications such as aldose reductase inhibitors or aminogunidine. Autoimmune therapies and nerve growth factors have also been tried. Oral dextromethorphan, a N-methyl-D-aspartate (NMDA) receptor antagonist has also been used for chronic peripheral neuritis. Dextromethorphan is widely available over the counter in non-narcotic cough preparations such as RobitussinDM and Benylin DM. It is believed that dextromethorphan has the chemical ability to relieve peripheral neuritis pain by blocking pain sensation. Studies have shown as much as a 24% reduction in peripheral neuritis pain as compared to a placebo. Typical dosing for these tests were 120mg/day or 3 tsp. every six hours with some ranging up to 3 tbsp every six hours.

Mentanx is a prescription medical food supplement that is used for dietary management of endothelia dysfunction in patients with diabetic peripheral neuropathy. Mentanx increases nitric oxide synthesis and offers the potential advantage of improving blood flow to peripheral nerves. The literature shows an increase of 136% blood flow to the peripheral nerves with the use of Mentanx over 8 weeks. Mentanx is only approved for diabetic peripheral neuropathy.

The success of each of the modalities mentioned above can be monitored with the use of periodic epidermal small nerve biopsies. The epidermal small nerve biopsies can be performed in a matter of minutes in your doctor's office using just a local anesthetic. Small never fiber biopsies are used to quantify nerve fiber counts. An increase in small nerve fiber counts over time indicate a positive response to the treatment modalities mentioned above.

Stage 3 peripheral neuropathy symptoms often produce severe pain. These symptoms are described as electrical sharp shooting pains, burning pain and tingling pain. These symptoms are tolerable during the day (for most patients) but become severe at night often limiting the normal sleep cycle. Neurontin (gabapentin) is a medication frequently used to suppress the symptoms of peripheral neuropathy. Neurontin was originally developed to control seizure disorders such as epilepsy. Neurontin can be taken in divided doses during the day or in a single does at bedtime. It is best to titrate Neurontin based upon the degree of symptoms. Normal daily doses range from 300mg to 2400mg. Although the use of Neurontin for the control of symptoms due to neuropathy is considered an 'off-label' use by The Food And Drug Administration, doctors use it regularly for control of symptoms.

Cymbalta (duloxetine hydrocholride) was recently introduced by Eli Lilly Co. Cymbalta is a selective serotonin and norepinephrine reuptake inhibitor (SSNRI) used for the treatment of pain and depression associated with diabetic peripheral neuropathy. Cymbalta is FDA approved for control of the symptoms of DPN. Cymbalta has been found in studies to be safe and effective. Dosage for Cymbalta is usually between 60-120 mg daily.

Lyrica (pregabalin) is a new generation of gabapentin introduced by Pfizer in 2004. Lyrica is also approved by The FDA for the treatment of symptoms secondary to DPN. The exact mechanism of action is not fully understood, but the presumed action is that pregabalin binds with the alpha2-delta subunit of protein of calcium chanels and acts to reduce the release of excitatory neurotransmitters. Lyrica also has been shown in clinical testing to be safe and effective.

Other medications for stage 3 symptoms include antidepressants such as Elavil. One of the side effects of Elavil and its' related family of medications is drowsiness. This side effect can be helpful in restoring the normal sleep cycle in patients who suffer from painful peripheral neuropathy symptoms.

Topical medications that can be used to sooth the pain of peripheral neuropathy found in stage 3 include Biofreeze and Neuragen PN.

Poorly controlled diabetes mellitus results in long term exposure of the peripheral nerve to elevated blood sugar levels.  Elevated blood sugar levels can affect peripheral nerves in a number of ways.  Elevated levels of blood glucose results in elevated levels of blood borne toxins.  These toxins tend to erode the outer sheath of the peripheral nerve, making peripheral nerves more sensitive to caustic body fluids. Many theories have been proposed to detail how long standing diabetes mellitus effects the peripheral nerves. And none of these theories are universally accepted.  The most accepted theory that has been proposed relates to elevated levels of sorbitol. Sorbital is a by-product of the metabolism of glucose. Impaired metabolism of glucose results in elevated levels of sorbital which is known to be toxic to the peripheral nerves. As a general rule, peripheral neuropathy is known to be caused by long term exposure to caustic chemicals. Long term exposure to sorbital is an established mechanism to describe the onset of diabetic peripheral neuropathy.

Another factor that contributes to the onset of diabetic peripheral neuropathy is decreased arterial circulation of the peripheral nerves.  Elevated blood glucose levels tend to affect arteries and arterioles in a number of ways.  Increased levels of blood glucose make the blood viscous.  The circulatory system has a difficult time pushing a viscous fluid through the artery.  As a result, the walls of the arteries and arterioles become hard and less permeable to blood.  Peripheral nerves are significantly affected by this change.  In the presence of high circulating levels of blood glucose, peripheral nerves are essentially starved of oxygen and essential nutrients and vitamins. 

The symptoms of diabetic neuropathy are described as a 'stocking and glove' distribution, meaning that the symptoms affect the foot, leg and hand. Most symptoms begin in the feet.  Symptoms begin distally and progress proximally over time. The symptoms are described as a burning sensation and electrical shock sensation that becomes worse at night or when a patient is not on their feet.

Diabetics with advanced peripheral neuropathy experience a loss of proprioception, or the ability to determine where you are in relationship to the ground or space. As a result, diabetics with peripheral neuropathy become unsteady on their feet due to advanced loss of sensory and motor function. Falls are common which can result in additional morbidity such as broken hips.

Diabetic with advanced peripheral neuropathy also experience loss of motor control of the muscles that control the function of the feet.  It's important to remember that the task performed by peripheral nerves is to mediate both sensory information and to coordinate muscle function.  Loss of muscle function also contributes to an increased tendency to falls.

The diagnosis of diabetic peripheral neuropathy is often made based upon a history and physical exam.  In early stages of diabetic peripheral neuropathy, patients are often unaware of why their feet feel numb.  And since there is no pain, many diabetic patients fail to seek care.  A history and physical exam of a diabetic patient should include vibratory testing, sharp dull discrimination and testing of light touch of the feet.  Each of these tests help to define the location and extent of diabetic peripheral neuropathy.

Nerve conduction studies and electromyography are used to test the response time of nerve and muscle.  Delays in response time and the pattern or distribution of sensory/motor loss, helps to define diabetic peripheral neuropathy. 

Epidermal (skin) nerve biopsies are another test used to diagnose diabetic peripheral neuropathy. The total number of epidermal nerves decreases with diabetic peripheral neuropathy.  The skin biopsy serves as a means by which nerve fibers can be counted.  A decrease in nerve fiber counts suggests advancing diabetic peripheral neuropathy.  And increase in small nerve fibers suggests a response to treatment.  Epidermal nerve biopsies are currently the most sensitive testing method that is used to screen for diabetic peripheral neuropathy.

Treatment of diabetic peripheral neuropathy

The single most important step to be taken in the treatment of diabetic peripheral neuropathy is the elimination of the primary cause of the neuropathy. In diabetes, the single most important issue affecting diabetic peripheral neuropathy is serum glucose levels. Controlling the onset of diabetic peripheral neuropathy is best managed by decreasing serum blood sugar levels. Once the primary contributing factors are removed, the nerve may have an opportunity to regenerate. Supportive efforts are helpful during this phase of repair and include nutritional support and the use of anti-oxidants. The following are some of the supportive measures that can be used in the treatment of diabetic peripheral neuropathy:

Pyridoxine (B6) has been used for years as a method of nutritional support following peripheral nerve damage. Vitamin B6 is water soluble and can therefore be eliminated by your body. Common doses range as high as 250mg/day.

Exciting new treatment modalities for diabetic peripheral neuropathy includes the used of anti-oxidants. These scavengers of the body are used to eliminate toxins which may contribute to peripheral neuropathy. Anti-oxidants used to treat peripheral neuropathy include gamma-linoleic acid and alpha lipoic acid (thiotic acid). Alpha lipoic acid increases glucose uptake in muscle and fat cells to improve both the symptoms of diabetic peripheral neuropathy and diabetes. It has also been suggested the alpha lipoic acid may help treat insulin resistance. A study by Tankova et al. showed up to a 65% reduction in the symptoms of DPN with high doses of alpha lipoic acid.

Other treatment may include the use of metabolic factors or medications such as aldose reductase inhibitors or aminogunidine. Autoimmune therapies and nerve growth factors have also been tried. Oral dextromethorphan, a N-methyl-D-aspartate (NMDA) receptor antagonist has also been used for chronic peripheral neuritis. Dextromethorphan is widely available over the counter in non-narcotic cough preparations such as RobitussinDM and Benylin DM. It is believed that dextromethorphan has the chemical ability to relieve peripheral neuritis pain by blocking pain sensation. Studies have shown as much as a 24% reduction in peripheral neuritis pain as compared to a placebo. Typical dosing for these tests were 120mg/day or 3 tsp. every six hours with some ranging up to 3 tbsp every six hours.

Mentanx is a prescription medical food supplement that is used for dietary management of endothelia dysfunction in patients with diabetic peripheral neuropathy. Mentanx increases nitric oxide synthesis and offers the potential advantage of improving blood flow to peripheral nerves. The literature shows an increase of 136% blood flow to the peripheral nerves with the use of Mentanx over 8 weeks. Mentanx is only approved for diabetic peripheral neuropathy.

The success of each of the modalities mentioned above can be monitored with the use of periodic epidermal small nerve biopsies. The epidermal small nerve biopsies can be performed in a matter of minutes in your doctor's office using just a local anesthetic.

Advanced diabetic peripheral neuropathy symptoms often produce severe pain. These symptoms are described as electrical sharp shooting pains, burning pain and tingling pain. For many patients, these symptoms are tolerable during the day but become severe at night often limiting the normal sleep cycle. Neurontin (gabapentin) is a medication frequently used to suppress the symptoms of diabetic peripheral neuropathy. Neurontin was originally developed to control seizure disorders such as epilepsy. Neurontin can be taken in divided doses during the day or in a single does at bedtime. It is best to titrate Neurontin based upon the degree of symptoms. Normal daily doses range from 300mg to 2400mg. Although the use of Neurontin for the control of symptoms due to diabetic peripheral neuropathy is considered an 'off-label' use by The Food And Drug Administration, doctors use it regularly for control of symptoms.

Cymbalta (duloxetine hydrocholride) was introduced by Eli Lilly Co. Cymbalta is a selective serotonin and norepinephrine reuptake inhibitor (SSNRI) used for the treatment of pain and depression associated with diabetic peripheral neuropathy. Cymbalta is FDA approved for control of the symptoms of diabetic peripheral neuropathy. Cymbalta has been found in studies to be safe and effective. Dosage for Cymbalta is usually between 60-120 mg daily.

Lyrica (pregabalin) is a new generation of gabapentin introduced by Pfizer in 2004. Lyrica is also approved by The FDA for the treatment of symptoms secondary to diabetic peripheral neuropathy. The exact mechanism of action is not fully understood, but the presumed action is that pregabalin binds with the alpha2-delta subunit of protein of calcium channels and acts to reduce the release of excitatory neurotransmitters. Lyrica also has been shown in clinical testing to be safe and effective.

Other medications for advanced diabetic peripheral neuropathy include antidepressants such as Elavil. One of the side effects of Elavil and its' related family of medications is drowsiness. This side effect can be helpful in restoring the normal sleep cycle in patients who suffer from painful peripheral neuropathy symptoms.

Topical medications that can be used to sooth the pain of peripheral neuropathy include Biofreeze and Neuragen PN.

Surgical decompression of peripheral nerves may be used to treat diabetic peripheral neuropathy.  This technique is called external neurolysis.  How does external neurolysis help diabetic peripheral neuropathy?  One school of though believes that elevated levels of glucose tend to draw water into the nerve.  As the sugar content within the nerve increases, water is drawn in as an osmotic gradient.  Increased intra-neural pressure that results from this osmotic gradient, places pressure on the nerve resulting in diabetic peripheral neuropathy.  This internal pressure is called crush syndrome.  External neurolysis relieves this pressure, restoring normal function to the nerve.

The following images show what is called a triple crush release (3 separate compressed nerves).  The first row of images show external neurolysis of the deep peroneal nerve.  The second row shows surgical external neurolysis of the posterior tibial nerve.  And the third row shows external neurolysis of the common peroneal nerve, lateral aspect of the knee.