B-Vitamins Prove Effective In Relieving Chronic Pain
New findings reveal that
this treatment could be highly effective in alleviating neuropathic pain
caused by injury to the nervous system
April 9, 2003 (San Diego) – Chronic pain affects
some 86 million Americans a year, and is the cause of
business and industry loses about $90 billion
annually to sick time, reduced productivity, and direct medical and other
benefit costs. Many who suffer from chronic pain are told to learn to “live
with it.” Now new research indicates that relief could be provided in the
vitamin counter at the neighborhood grocery story.
B-vitamins, such as thiamin (B1), pyridoxine (B6), and
cyanocobalamin (B12), have been proven to be clinically effective in
treating various painful conditions such as lumbago, sciatica, trigeminal
neuralgia, facial paralysis and optic neuritis as acting as an analgesia
(pain reliever). Past research has explored the analgesic and
anti-inflammatory effects of vitamin B1, B6 and B12. For example, vitamin
B1, B6, and B12 and combinations inhibited chemical- and heat-induced pain
evidenced by writhing test, heat coil test, or hot plate test (although some
negative results have also been reported).
Nociceptive pain comes from sprains, bone fractures, burns, bumps,
bruises, inflammation (from an infection or arthritic disorder),
obstructions, and myofascial pain (which may indicate abnormal muscle
stresses). The pain originates from the nociceptors, nerves which sense and
respond to parts of the body which suffer from damage. They signal tissue
irritation, impending injury, or actual injury. When activated, they
transmit pain signals (via the peripheral nerves as well as the spinal cord)
to the brain. One of the research studies found that noxious heat evoked
nociceptive responses of spinal dorsal horn neurons were suppressed by
compound of B1, B6 and B12. These studies indicate that the B-vitamins
possess the capability to block physical distress in some painful
conditions.
Recently, several animal models of painful sequelae in
humans after the primary sensory neurons injury have been developed such as
the model of chronic compression of dorsal root ganglion (DRG). However,
this antinociceptive efficacy of B-vitamins has not been evaluated in
animals with neuropathic pain, that is result of an injury or malfunction in
the peripheral or central nervous system. The pain is often triggered by an
injury, but this injury may or may not involve actual damage to the nervous
system. Researchers recently found that intraperitoneal (i.p.)- or
intrathecal (i.t.)- injection of B1, B6 and B12 or their combination
significantly reduced thermal hyperalgesia in CCD rats. On the other hand,
mechanisms underlying the B-vitamins-induced analgesia remain unknown. It
has been reported that B complex vitamins can activate potently the soluble
guanylyl cyclase (sGC), and cyclase guanosine monophosphate (cGMP) in a wide
variety of tissues. cGMP plays an antinociceptive activity in nociceptive
processing. Others have suggested that B1 could produce antinociception by
the activation of GC mediated by cGMP in p-benzoquinone-induced mouse
writhing model.
A New Study
To provide experimental evidence that supports clinical
use of the B-vitamins in aiding in the treatment of chronic pain especially
neuropathic pain due to primary sensory neuron injury, the present study
examined antinociceptive effect of vitamin B1, B6 and B12 using the
neuropathic pain model of chronic compression of DRG (CCD, Song et al. J
Neurophysiol 1999, 82: 3359-3370), and the possible contributions of
cGMP-PKG signaling pathway to B1 induced antinociception. The authors of
“Antinociceptive Effects of Thiamin, Pyridoxine and Cyanocobalamin in Rats
with Primary Sensory Neuron injury” and “Activation of cGMP-PKG Signaling
Pathway Mediates Thiamin Induced-Inhibition of Thermal Hyperalgesia in Rats
with Primary Sensory Neuron Injury” are Xue-Jun Song MD, PhD, Associate
Professor and Associate Director of Basic Science Research Department of
Neurobiology, and Zheng-Bei Wang, MD, both from the Parker Research
Institute, Dallas, TX. They are presenting their findings at the American
Physiological Society conference, Experimental Biology 2003, being
held April 11-15, 2003, at the San Diego Conference Center, San Diego, CA.
Methodology
Experiments were performed on
adult, male Sprague-Dawley rats weighing
200-250 g. CCD was produced by surgically implanting stainless steel rods
unilaterally into the intervertebral foramen at L4 and L5 as we previously
described. In brief, the rats were anesthetized with sodium pentobarbital
(40mg/kg, i.p.), the paraspinal muscles were separated from the mammillary
and transverse processes and the intervertebral foramina of L4
and L5 exposed. A stainless steel L-shaped rod, 4 mm in length
and 0.6 mm in diameter, was implanted into each foramen, one at L4
and the other at L5. Each insertion was guided by the mammillary
process and transverse process. As the rod was moved over the ganglion, the
ipsilateral hind leg muscles typically exhibited one or two slight
twitches. After surgery, the muscle and skin layers were sutured. An oral
antibiotic, Augmentin, was administered after surgery in the drinking water
for each rat (7.52 g in 500 ml) for seven days.
The presence of
thermal hyperalgesia was determined by measuring foot withdrawal latency to
heat stimulation of surface of hindpaw. The rats were tested on each of 2
successive days prior to surgery. Postoperative tests were conducted 1, 3,
5, 7, 10, 14 days after surgery and then once weekly for ~10 weeks in some
rats for examining the long-term effects of B vitamins. For examining
short-term effects, tests were conducted for up to 14 days and additional
tests 2, 6, 12, 24 and 36 hours after injection of B vitamins on the third
day after surgery.
The rats in different groups each received one of the
following treatments via i.p. or i.t. I.p. treatments (0.1 ml/100g): (1)
saline (0.9% NaCl); (2) B1 (5, 10 and 33 mg/kg, respectively);
(3) B6 (5, 10 and 33 mg/kg, respectively); (4) B12 (0.05, 0.2 and
0.5 mg/kg); (5) complex B vitamins (CBV) (B1+ B6 + B12
at different doses); (6) CBV for 7 consecutive days after surgery. I.t.
treatments (20 μl): (1) saline; (2) B1 (33, 66 and 132 μg); (3)
PKG inhibitor Rp-8pCPT-cGMPS (0.1 and 1 μM) +B1 (66 μg); (4)
guanylyl cyclase inhibitor ODQ (0.02 and 0.2 μM) + B1; (5) cGMP
analog 8Br-cGMP (0.1 and 1 μM); (6) PKG activator SP-cGMP (0.1 and 1 μM);
(7) Rp-8pCPT-cGMPS + 8Br-cGMP; (8) Rp-8pCPT-cGMPS + SP-cGMP; (9) B1
66 μg for 7 consecutive days after surgery. Additional rats were used as
sham or unoperated control.
Results
B1, B6, B12 and their combination, i.p. or i.t.,
significantly inhibited thermal hyperalgesia (pain) evidenced by reversal of
the shortened latency of foot withdrawal to noxious heat stimulation
ipsilateral to CCD. This inhibition was in dose-dependent manner.
Hyperalgesia was inhibited about 20-100 percent at 2, 6 and 12 hr, and
recovered at 24 or 36 hr test dependent on different doses. Repetitive
application of CBV for seven days produced long-term inhibitory effects on
thermal hyperalgesia. The extreme sensitivity to stimuli disappeared four
to five weeks after injury in rats with CBV treatment. In contrast,
hyperalgesia lasted for eight to ten weeks in rats with saline or without
any treatment. In addition, we found that combination of threshold doses of
individual of the vitamins produced a synergetic inhibitory effect on
thermal hyperalgesia.
B1, i.t., induced-inhibition of hyperalgesia
was reversed by inhibitors of cGMP-PKG signaling pathway ODQ (guanylyl
cyclase inhibitor) and Rp-8pCPT-cGMP (PKG inhibitor). cGMP analog 8Br-cGMP
and PKG activator SP-cGMP inhibited thermal hyperalgesia, respectively.
Such inhibition is similar to that produced by B1. Rp-8pCPT-cGMP again
reversed 8Br-cGMP and SP-cGMP induced- inhibition of thermal hyperalgesia.
B1 and the activators and inhibitors of cGMP-PKG pathways did not alter the
foot withdrawal latency in unoperated control rats.
Summary
The present studies demonstrate that spinal application
as well as intraperitoneal injection of vitamin B1, B6, B12 their
combination can produce short- and long-term inhibition of hyperalgesia
following chronic compression of dorsal root ganglion neurons produced by
artificial intervertebral foramen stenosis. Both severity and duration of
hyperalgesia are significantly reduced. These results strongly support
clinical use of B-vitamins in aiding in treatment of chronic pain and/or
other diseases due to similar injuries to the nervous system.
The data also show that vitamin B1 induced-inhibition
of hyperalgesia can be reversed by the inhibitors of cGMP-PKG signaling
pathway, suggesting that vitamin B1 induced- inhibition of hyperalgesia due
to spinal ganglion compression may involve, at least in part, in activation
of the cGMP-PKG signaling pathway in the spinal cord.
-end-
The American
Physiological Society (APS) is one of the world’s most prestigious
organizations for physiological scientists. These researchers specialize in
understanding the processes and functions underlying human health and
disease. Founded in 1887 the Bethesda, MD-based Society has more than
10,000 members and publishes 3,800 articles in its 14 peer-reviewed journals
each year.
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Editor’s
Note: For receive a copy of the abstract, or to schedule an interview with a
member of the research team, please contact Donna Krupa at 703.967.2751
(cell), 703.527.7357 (office) or at
djkrupa1@aol.com.
