Lyme disease: what we know and what we don’t know
Lyme Disease: What We Know and What We Don’t Know
An Editorial by Tom Grier, Lyme Writer In 1975 the term “Lyme Arthritis” first entered the vocabulary of the physicians in America. Since that time Lyme disease and Lyme-like diseases have become
recognized worldwide. But in the 28 years since “Lyme Arthritis” was first described: What do we actually know? And what do we yet need to learn about
Why is it that in the three decades since Lyme disease was first described that it still perplexes us and vexes us with controversy and puzzlement?
In a nutshell it comes down to the inescapable fact that victims of Lyme disease all too often have lingering symptoms that remain or return even after aggressive
and multiple antibiotic treatments. They remember wellness, but with each passing year the fog that fills their brain, the palpitations that shake their hearts,
and the fatigue that plagues their bodies becomes the ever present reminder that they were stricken with a poorly understood and often underestimated pathogen.
Here are some things we know:
The pathogen that causes Lyme disease is
Borrelia burgdorferi and it is a highly motile spirochete that belongs to a genus
of bacteria that are notorious for giving rise to variant strains. Borrelia are bacteria that are associated with dozens of tick and louse-borne Relapsing
Fevers that are found throughout the world. These related illnesses range in symptoms from cases of mild fevers to rapidly fatal encephalitis’. The hallmark
attribute that most Borrelia bacteria have in common is their ability to adapt, change and infect host animals that in turn infect many species of ticks and lice.
We know for example that if you rank all the known Borrelia pathogens in a phylogenetic tree based on related genetics, you will find many disease causing
pathogens that cause similar symptoms will often end up close together in related groups on the phylogenetic family-tree.
In other words Borrelia burgdorferi, Borrelia afzellii and Borrelia garinii that
cause Lyme disease in America and Europe are all genetically similar to each other and have similar tick vectors. It is believed that they are closely related
and variations occurred as separate tick populations over thousands of years migrated with animal populations and the bacteria became isolated populations. At one time all Borrelia had a common ancestor.
Exactly how long ago we don’t know, but the evidence of common ancestry is
in their related and similar genes. This year when the genomic sequence of Borrelia burgdorferi was determined, it came as quite a shock that most of
the genes in this large bacterium had no known counterparts or similarities to other known bacterial genes. This means the function of the majority of
the genes in the Borrelia species has yet to be determined. What we don’t know:
The Lyme bacteria Borrelia burgdorferi likes to
preferentially express certain genes and suppress others. This allows the bacteria to adapt to new environments. But what does it take for Borrelia
burgdorferi to express one of the suppressed genes of an ancient pathogen cousin? Borrelia burgdorferi like all Borrelias have genes that are latent
but intact. If a gene is expressed or triggered by the environment as it is suggested by research done of Relapsing Fever strains, then could a latent
but deadly gene be triggered in one individual with unique genetic markers and not expressed in another patient? Could pathogen-host interactions
based on patient genetic markers explain why some Lyme patients have
What we know:
Dr. Andrew Pachner infected mice with Borrelia burgdorferi
and later extracted the bacteria from the blood and from the brains of the
infected mice. What he found was basically that the Bacteria in the brain changed: they now expressed a new set of genes. The result was bacteria so
different from what he started with, that the antibodies from the peripheral blood could no longer detect the bacteria isolated from the brain.
This is bad news as the CNS is isolated from the rest of the body. If the Lyme
spirochete can adapt to the human brain and circumvent the immune system, it is less likely to be inhibited by our natural immune defenses. Further studies by Pachner in primates using PCR suggested persistent infection post-antibiotic
treatment. This is more bad news as this suggests that the CNS of primates is an isolated and protective incubator for Borrelia bacteria.
What other gene expressions of these bacteria do we need to understand better?
What we need to find out:
Occasionally patients infected with Relapsing
Fever will report a Bull’s-Eye rash identical to Lyme disease, and experience symptoms similar to Lyme without a recurring febrile states (Recurring fevers). If Relapsing Fevers can behave like Lyme disease, does this mean Lyme could
suddenly cause an aggressive encephalitis in a patient similar to East African Relapsing Fever? Since we don’t know or understand the reasons for patient
variation in symptoms, it is something we need to investigate and learn. We know for instance from early work done by Dr. Patricia Coyle M.D. PhD that the Lyme
bacteria can get into the CNS of a lyme patient very early , but only a small fraction of these patients develop serious mennigo-encephalopathies.
Understanding the recently sequenced genomic sequence of Borrelia burgdorferi and gene _expression is essential to understanding both chronic
and acute Lyme disease. In patients with HLA-DR4 tissue type, are there markers in the joints responsible for chronic Lyme arthritis ? We need to study
the role of genetics, and receptor sites in both humans and within the Lyme spirochete. How the bacteria interacts with one person may be radically
different than how it acts in another patient.
What we don’t know:
One of the most frequent complaints from Lyme patients
is the loss of cognitive abilities. Their minds are fuzzy, foggy and they complain
of short term memory loss and poor word retrieval. Their fear is: How permanent
is this memory impairment? And will it progress? We don’t know why so few bacteria can cause such a profound affect on conscious thought, but unlike
Syphilis a related and similar spirochetal infection, the Lyme bacteria is found in the human body in extremely low numbers?
Why are there so few bacteria in a Lyme infection? Are their other forms
(sphereoplasts or cell-wall deficient forms) of the bacteria in greater numbers that we just aren’t recognizing? How can so few bacteria cause such horrible symptoms like cardiomyopathy, encephalitis, hepato-spleenamegaly, heart
arrhythmias, rheumatoid-like arthritis, optical neuritis, Bell’s Palsy, muscle spasms, fibromyalgia, and multiple sclerosis-like presentations. Can it be that a small
number of bacteria initiate cascade responses of inflammation and autoimmunity in the human body? If autoimmunity is playing a role, how does it affect the
What we know:
Since 1911 dozens of papers have associated spirochetes with
Multiple Sclerosis. The most dramatic and convincing of these papers were all published prior to 1954 which was decades before the numerous controversies of Lyme disease would appear. Recently in experiments using a rat-brain model,
one researcher showed that Borrelia burgdorferi was directly neuro-toxic to neurons and caused the death of brain cells on contact. This happened rapidly
and consistently. This means there is an evolved mechanism within the Borrelia bacteria when in contact with the CNS to not only change it’s antigenic identity
but to paralyze and destroy neurons and glial cells.
In recent years the incidence of Alzheimer’s disease has risen sharply. Even more recent research has shown that the incubation of Borrelia burgdorferi
in mouse brain cultures for eight weeks resulted in creating many of the laboratory markers for Alzheimer’s disease. We see the synthesis of amyloid precursor protein and the rapid conversion to amyloid and beta sheet amyloid.
We see the hyperphosphoralation of Tau protein, we see similar fibrillary tangles and fibrin deposits. In other words we can essentially create a
laboratory model of Alzheimer’s in-vitro simply by virtue of adding Borrelia to living brain cells. An animal model of Alzheimer’s was something researchers
dreamed of for decades, and now that it is within our technical abilities almost no one is exploring this model of Alzheimer’s pathology.
What we need to know:
What receptors are on the Borrelia membrane that
triggers neuron destruction? What causes the cascade of Amyloid synthesis in
brain-cell cultures? If we knew these things we could develop potential new treatments to prevent amyloid production in Alzheimer’s patients, and perhaps
a way to stop neurological damage in Lyme patients.
What we need to do?
If even a few percent of the cases of M.S. and
Alzheimer’s disease were caused by spirochetes, we could save countless people
from the morbidity and disability of these diseases, and millions in health care dollars. But we need much more money and research to explore a link between Borreliosis and dementia in humans. Clearly if it turns out that spirochetal
infections are playing a role in some dementias, we need to find out Who to treat? and How to treat?
The first is advanced and thorough research to establish whether a link between
M.S. and Lyme disease does or does not exist. Even a 1 % incidence would be an important finding. But before we can give M.S. and Alzheimer’s patients that
1 in 100 chance of an effective treatment, we need to do the basic research, and frankly while monies are currently being spent on more Deer studies, almost nothing with respect to Lyme disease is being spent on Dementia research .
We need millions of dedicated research dollars to study a link between
Lyme-related-spirochetes and Alzheimer’s disease and M.S. To do these studies we need more than just money. We need human brain tissue from dementia patients and
M.S. patients. To obtain these samples we would need to pre-enroll affected patients into a nationwide autopsy study and create a tissue bank for the tissues, and then
make them available to researchers to specifically look for spirochetes and the markers of Borrelia. Prior to this however we need to train pathologists in techniques to detect spirochetes. Unfortunately if you don’t know how to detect
them, the spirochetes are virtually invisible on a normal autopsy.
With a national annual budget of a mere seven million dollars to study Lyme disease and to educate the public, we are about 100 million dollars short of an effective
Lyme disease research program in America.
What we know:
We know that many Lyme patients with established disease can test
negative on serology tests. Seronegative Lyme has been reported in the medical literature and has been confirmed in patients with Erythema Migrans rashes, it has been confirmed by PCR, it has been confirmed by culture, and even by biopsy and
staining of surgically removed tissue. So we know antibodies do not always manifest in all Lyme patients and cannot be the sole determinant of diagnosis. We also know
by all the same methods of confirmation that some patients remain actively infected with the live bacteria even despite antibiotic treatment. Treatment failures have
been reported in all treatment studies that required a follow-up of patients.
What we don’t know?
Why do some patient’s not express adequate antibodies
against this bacteria? If a patient is infected and has low or no detectable
antibodies are they more sick than patients with a high natural immunity? Why do some patients maintain an active infection when they receive the identical treatment as patients who recover? Why do symptoms remain in so many Lyme
What we need to do:
To answer these questions we need research that includes
a budget for extensive pathology and histology. We need studies that look at the
modes of action of the various antibiotics against spirochetes. We need more pharmacological studies and newer and better antibiotics. We need studies that
investigate adjunct therapies that address patients lingering symptomatic sequela post treatment. If nothing else we need better delivery systems for the medicines we already have.
In the 1950s it was recognized that penicillin did not consistently get into the
brains of Tertiary Syphilis patients. Only when the CNS was extremely inflamed or if the drug was given in gigantic single doses did penicillin enter the brain in
therapeutic levels. So some clinicians in desperation tried to inject penicillin directly into the brain only to discover that this induced seizures. Now fifty
years later we are faced with a very similar dilemma. How do we get amoxicillin and other inexpensive and readily available drugs
into the CNS? One potential answer is more research in better delivery systems to deliver the drug into the CNS. Another option is to add fat soluble carrier
molecules or to use micronized antibiotics encapsulated in lipids. Of course there is no guarantee of success with these and other methods, but drug companies do
not pursue this area of research, the market is perceived as being too limited. But if you expand these delivery systems beyond Lyme for such diseases as fungal
infections of the brain, then the market is much larger! Once again the World Health Organization may be a source to stimulate this kind of research.
To do these studies that have never been done, we need to put
a stop to the impediments hindering good research. Until the studies are done no one has the answers. And we won’t find the answers if we don’t invest more
money into more and better designed studies. What Lyme disease has lacked in the past twenty five years has been research dollars that focus on the
“What Lyme Disease Research Needs To Be Done And Why”
Lyme disease is a perplexing illness. Early in 1970s in Old Lyme Connecticut, Lyme disease was first described as a rheumatological
syndrome called “Lyme Arthritis”. The symptoms of “ Lyme Arthritis” mimicked Juvenile Rheumatoid Arthritis (JRA) and many kids with
Lyme disease were misdiagnosed as having JRA. It was only a matter of a few years before “Lyme Arthritis” was associated not only with arthritis but also with causing a host of
serious neurological symptoms. Further investigation soon showed that the characteristic bull’s-eye rash was associated with the bite of a new species of tick named the Ixodes dammini tick. (The I. dammini tick
turned out to be the same species as the I. scapularis deer tick.) In 1981 when the culprit of the illness was isolated both from the suspect tick and from human Lyme rashes, it was all but decided by
the medical community that while Lyme disease was a real concern, it was easily treated. This assumption was based on the fact that
“Lyme Arthritis” was caused by a bacterium: and with few exceptions bacterial pathogens are all successfully treated with just a few weeks of antibiotics.
While in the test tube the Lyme bacteria Borrelia burgdorferi
responded to many common antibiotics including erythromycin, tetracycline, doxycycline, penicillin and amoxicillin, the truth was
that in the early days of treatment, in every human trial of antibiotic drug treatment, some patients either did not respond at all, or their
symptoms quickly relapsed. The unfortunate fact of Lyme disease is that more than twenty
years later medical science has not developed any significant breakthroughs in either diagnosis of or the treatment of this
disease. Despite all of what we have learned about Borrelia burgdorferi , our diagnostic tests are still poor, and our treatment
regimens are for the most part unchanged for the last two decades. The early Lyme tests that were developed made heavy assumptions that a patient’s level of antibody was a consistent marker of exposure and active infection. More distressing is that most early treatment
studies considered a drop in antibody levels during antibiotic treatment as a quantitative marker for indicating a cure. Researchers
inappropriately accepted a negative antibody titer as an absence of active infection. It was not considered that the bacteria was surviving
beyond the reaches of the bloodstream’s immune system. Despite the overwhelming evidence that seronegative Lyme is common and that infection can persist despite treatment, today’s researchers and manufacturers of these tests still squabble over
patents and royalties and spend more time thinking up clever ways of making their indirect tests more competitive in the drug market
rather than creating better direct tests. An example of this was when a new PCR test by the U of MN was compared not to other PCR tests but to culturing Lyme rashes.
Assuming only a 4 % success rate of culturing rashes the press
release for the new test was complete with cost for the test and
boldly stated that this test was 4 times more accurate than culturing. To the lay person this sounds good but it really meant the new PCR test was accurate only in 1 out of every 5 patients with a bull’s eye
rash. This kind of research is not in the best interest of the patient. So what research needs to be done that isn’t being done? In the last twenty years the goal of medical research has become so economically competitive that so much of the work being done
is secretive and proprietary, many institutions won’t even pursue research that doesn’t look economically rewarding. In today’s bottom
line medical system, most institutions will not do work in an area that might duplicate the work of a competitor who may already own patents on the end product. Yet work on endless “me-too” versions
of existing tests continues simply because manufacturers see more money in patient testing and vaccines than in treatment.
I have said it many times before and still believe that Lyme patients
would be better off if no test had ever been developed, and Lyme treatments were based entirely on symptom response to therapy. I
don’t have a quick solution to the problem of the current patent-or- parish mentality of universities, but I do think more time needs to be spent on some old technologies such as blood smears and tissue
stains before we listen to any more press releases from universities and drug companies telling us how their new test is better than that
of their competitors. In truth I have little hope in ever developing a quick easy reliable blood test for Lyme and feel we are better off without the ones
currently being demanded by insurance companies and HMOs. My first suggestion for research is to spend less money developing
tests for the living, and spend more money investigating the disease process in the dying. Understanding the pathology of this disease is
paramount to making any significant advances in the treatment of this illness.
We have seen in animal models going back to the 1980s that the
blood brain barrier of mammals is quickly breached by this bacterium. (4) What role does early invasion of the Lyme spirochete into the human brain mean to patients? Is there
long-term sequela to CNS invasion? These are questions are left wholly unanswered and require a deeper commitment to
research than what has been allocated to Lyme disease! In the 1990s we learned that the Lyme spirochete has a predilection for and attaches to the lining of blood vassals. When this occurs the
endothelial cells break down and creates blood vessel holes. No one has suggested or pursued any receptor site research. Perhaps one form of treatment might be finding a way to block these attachment
sites? Drug Therapy: While we have in the past twenty years explored the use of dozens of antibiotics and combinations of antibiotics,
we have not made any real advancement in antibiotic therapy. The quick and easy answer is to say we should develop newer and
better antibiotics. While this is obviously true it still falls far
short of what else can be done. One of the problems of treating Lyme disease is that the bacteria is
known to penetrate difficult to reach and difficult to treat areas of the body. While the argument still persists on whether Lyme disease
is an intracellular disease, there is no argument that the bacteria can get inside the joint, connective tissue and the brain which are tissues
difficult to treat. In most cases you must overdose the rest of the body in order to penetrate these tissues.
A solution not currently being pursued is better drug delivery systems.
In 1991 I proposed to the company I worked for at the time, Wyeth labs, that research be done on better CNS delivery systems for amoxicillin.
With the advent of diseases like AIDS and Lyme it seemed that
we needed a better way to get drugs safely into the brain in higher concentrations where they were needed. While old drugs like
amoxicillin can no longer be patented, the drug delivery systems can be patented for more than a decade. This could give new life
to many old drugs. Better delivery systems make dozens of drugs available rather than just concentrating on a singly new drug option. Devises that optimize direct infusion of antibiotics into joint and brain is one method of accomplishing this, and the use of fat soluble
carrier molecules conjugated to or surrounding the drugs is another method (lipo-spheres, DMSO etc). The response to a 28 page
proposal that I drafted in 1991 to my employer, was a single sentence in a short letter. “ Dear Mr. Grier: At this time there
is no interest or economic feasibility in developing new treatments for Lyme disease .there are not enough new cases of Lyme annually to warrant development of clinical treatments. ”
Since economic interests seem to be the main concern in researchers
developing better tests for diagnosis and better drugs for the treatment of Lyme disease, it appears that Lyme disease research may be left in
the hands of foundations still willing to fund research directed by need and not economics. The bonus is that almost any new treatments will
be economically viable because of use in Lyme and other emerging infectious diseases. Here is a list of areas of research that have not been aggressively pursued and that I believe have potential in producing useful
breakthroughs in diagnosis and treatment. First we need to devote less monies to tick studies and urban exposure studies and more monies to basic pathology and microbiology studies.
In a world filled with people traveling via SUVs and airplanes, Lyme disease can occur to anyone who travels through Lyme endemic areas. We need to put research money into science and
not into the politics of boundaries. I care less about which counties have Lyme, and more about what long term untreated Lyme is doing to our medical system? If Lyme
patients have been misdiagnosed as having M.S. how many Lyme patients have in the last 50 years been draining insurance companies
out of money for long term care of patients with M.S-like disorders
caused by Lyme. We don’t know the answer and we will only find out by doing autopsies on enough dementia patients to establish an accurate percentage. Even if just a few percent of dementia patients
are found to have spirochetes in the brain at the time of death, this translates to billions of health care dollars wasted on caring for sick
patients when it would take just a fraction of that money to treat patients caught earlier.
A very simple study that has never been done but would be quite
revealing about tick-borne illnesses is a quality of retirement-life study that looks at the differences between the quality of health of
retirees in professions that are at high risk for tick-borne illness compared to lifestyles with professions at a low risk of contracting tick-borne illnesses. Previous studies have shown a higher incidence
of M.S. among agricultural workers, owners of large dogs, and in Europe M.S. is highest in areas of high rodent infestations. Perhaps
a large-scale quality of life study would tell us if outdoor living is really a healthy lifestyle? Is there a greater risk for forestry workers
to get M.S. than say a secretary? A survey of this type would be simple and cheap to do.
Pathology: I am sorry to say it but the only way to get a definitive answer to the question of whether Lyme can still be an active
infection post treatment, is to do autopsies and recover and test biopsies done on chronic Lyme patients that die of any other cause
(cancer, heart attack etc) and do labor intensive searches for the bacteria using immuno-fluorescent tissue stains and silver stains of
selected tissues. If we find it in the brain after treatment then all the arguments for not treating patients who respond to antibiotics
becomes moot! Borrelia burgdorferi has been found in so many tissues that it makes sense that any autopsy study that is undertaken should investigate many tissues to determine what tissues are target
tissues and are most resilient to successful antibiotic therapy. Receptor site research : It appears that the Lyme spirochete has an affinity for certain tissues. It seeks out connective tissue and may
use N-Acetyl Glucasamine as a food source. Borrelia burgdorferi also attaches to specific cells in animal models of Lyme disease
including endothelial cells, B-cells, fibroblasts, peripheral nerves, and specific brain cells. It may be that the bacteria has receptor sites that can be blocked by new and specialized therapies? If so this may
be both an effective treatment and a preventative. To do this we need more and better animal models including mammalian brain models that investigate the pathologic
mechanisms of Borrelia. In Switzerland a Neuropathologist Judith Miklossy showed that when she looked for spirochetes in the brains of Alzheimer patients that she found them in an alarming percentage of Alzheimer’s
patient’s brains. Since this is a bacteria that is invisible in human tissue unless you look for it and stain for it post-mortem, we need
to do more dementia based autopsies to determine the role and frequency of spirochetes in debilitating neurological, and
neuromuscular diseases. Part of Miklossy’s work showed an association of the location of the spirochetes in the patient’s brain
with amyloid plaques. What role can this bacteria or other bacterial
pathogens play in producing amyloid in mammalian brains? Better animal models of brain cell metabolism and infection are needed to find out.
In summary we are still essentially diagnosing and treating patients
in the same manner as we did in the 1980s and the bulk of Lyme disease research seems to be oriented around everything except
pathology, and treatment. I believe to make significant strides in patient treatment we need to devote more time and money to
pathology, better drug treatments and better drug delivery systems. I also believe privately funded foundations are the best hope of
directing and funding these kinds of projects. Tom Grier
(Steere AC, Gibofsky A, Patarroyo ME, Winchester RJ, Hardin JA, Malawista SE. Chronic Lyme Arthritis: clinical and immunogenetic
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Murray, Polly. The Widening Circle: The Woman Who First Suspected JRA Was Somehow a Contagious Entity- A Lyme
Disease Pioneer Tells Her Story. St. Martin’s Press, 321 pages) (Pachner AR, Steere AC. The triad of neurologic manifestations of Lyme Disease: Meningitis, cranial neuritis, and radiculoneuritis.
Neurology 1985;35:47-53 ) Coyle PK, Schutzer SE, Deng Z, Krupp LB, Belman AL, Benach JL, Luft BJ. Detection of Borrelia burgdorferi antigens in antibody negative cerebrospinal fluid in neurologic Lyme disease. Neurology
1995;45(11):2010-2015 Tuomanen Elaine. Breaching the Blood Brain Barrier: Development of a therapy for meningitis has revealed how bacteria penetrate the
Blood-brain barrier. Scientific American February 1993 pp 80-85 Schutzer, Steve M.D. Lyme Disease: Molecular and Immunologic
Approaches. Series 6 Current Communications in Molecular and Cell Biology, Cold Spring Harbor Press, 329 pages, 1992
Cleveland CP, Dennler PS, Durray PH. Recurrence of Lyme disease
presenting as a chest wall mass: Borrelia burgdorferi was present despite five months of IV ceftriaxone 2g, and three months of oral
cefixime 400 mg BID. Poster presentation LDF International Conference on Lyme Disease research, Stamford, CT, April 1992 *
Masters EJ, Lynxwiler P, Rawlings J. Spirochetemia after continuous high dose oral amoxicillin therapy. Infect Dis Clin
Practice 1994;3:207-208 Lawrence C, Lipton RB, Lowy FD, and Coyle PK. Seronegative Chronic Relapsing Neuroborreliosis. European Neurology.
1995;35(2):113-117 Marshall V. Multiple Sclerosis is a Chronic Central Nervous System Infection by a Spirochetal Agent.
Miklossy Judit. Alzheimer’s disease a spirochetosis? Neuro Report 1993;4:841-848 Miklossy J, Kuntzer T, Bogousslavsky J, et al.
Meningovascular form of neuroborreliosis: Similarities between neuropathological findings in a case of Lyme disease and those
occurring in tertiary Neurosyphilis. Acta Neuro Pathol 1990;80:568-572 Beard CM, Kokmen E, O’Brien PC, Kurland LT. The prevalence of dementia is changing over time in Rochester, Minnesota.
Neurology 1995;45:75-79 DeSilva D, Potters-Tilkin C. Dementia in Lyme Disease: A Case Study. Lecture Handout. LDF Lyme Conference, Atlantic City, 1993 Garcia-Monco JC, Coleman JL. Antibodies to Myelin Basic Protein in Lyme disease. J Infect Dis (Letter) September 1988;158(3):667
Garcia-Monco JC, Fernandez-Villar B, Benach JL. Adherence of
the Lyme Disease Spirochete to the Glial Cells. J Infect Dis 1989;160(3):497-506
Garcia-Monco JC, Fernandez-Villar B, Alen JC, Benach JL. Borrelia burgdorferi in the CNS: experimental and clinical evidence
for early invasion. J Infect Dis 1990;161:1187-1193 Garcia-Monco JC, Fernandez-Villar B, Rogers RC, Szczepanski A, Wheeler CM, Benach JL. Borrelia burgdorferi and other related
spirochetes bind to galactocerebroside. Neurology 1992;42:1341- 1348
Liegner Kenneth. Global Cerebral Atrophy in Lyme Borreliosis. Abstract 55B Arlington Virginia International Lyme Disease
Symposia * Reik L, Smith L, Kahn A, Nelson W. Demyelinating Encephalopathy in Lyme disease. Neurology 1985;35:267-269
Schmutzhard E, Pohl P, Stanek G. Borrelia burgdorferi antibodies
in patients with relapsing/remitting form and chronic progressive form of multiple sclerosis. J Neurol Neurosurg Psych 1988;51:1215-1218 Waniek C, Prohovnik I, Kaufman MA. Rapid progressive frontal type dementia and subcortical degeneration associated with Lyme
disease. A case report/abstract/poster presentation. LDF State of the art conference with emphasis on neurological Lyme.
April 1994, Stamford, CT* Abstract #D646 - 1995 Rheumatology Symposia Texas chaired by Alan Steere P.K. Coyle, et al, Multiple Sclerosis vs. Lyme disease a diagnostic dilemma. Forty-seven patients were identified as possible
MS patients. Many had brain lesions on their MRIs, consistent with MS 61%. CSF was constant with MS in 46 % of the patients. The
final breakdown of the 47 patients was: 21 MS, 15 LD, 7 had findings constant with both LD and MS. Thirteen patients responded to
antibiotics but only those who had CSF findings consistent with LD.
Abstract # D657 - 1995 Rheumatology Symposia Texas
chaired by Alan Steere J. Cimperman, F. Strle, et al, Repeated Isolation of Borrelia burgdorferi from the CSF of two patients treated for Lyme neuroborreliosis. Patient 1, was a twenty year
old woman who presented with meningitis but was sero-negative for Bb. Subsequently six weeks later, Bb was cultured from her
CSF and she was treated with IV Rocephin 2 grams a day for 14 days. Three months later the symptoms returned and Bb was
once again isolated from the CSF. Patient 2 was a 51 year old female who developed an EM rash after tick bite. Within two
months she had severe neurological symptoms, her serology was negative. She was denied treatment until her CSF was culture
positive nine months post tick bite. She was treated with 2 grams of Rocephin for 14 days. Two months post antibiotic treatment Bb was once again cultured from her CSF. In both these cases the
patients had negative antibodies, but were culture positive, suggesting that the antibody tests are not reliable predictors
of neurological Lyme Disease. Also standard treatment regimens are insufficient when infection of the CNS is established, and Bb
can survive in the brain despite Intra venous antibiotic treatment. Goodman JL, Sonnesyn SW, Holmer S, Kubo S, Johnson RC.: Seroprevelence of Borrelia burgdorferi in patients with severe heart failure, evaluated for cardiac transplantation at the University of MN.
Abstract # 49, presented at the Fifth International Symposia on Scientific Research on Lyme Borreliosis, Arlington, VA, 1992 *
The presence of Lyme antibodies is present in a large percentage of myocardopathy patients awaiting heart transplants.
Preac-Music V, Pfister HW, Spiegel H, et al. First isolation of
Borrelia burgdorferi from an iris biopsy. J Clin Neuro-ophthalmology 1993;13:155-161 Steere AC, Durray PH, Danny JH et al. Unilateral Blindness Caused by Infection with the Lyme Disease Spirochete Borrelia
burgdorferi. Annals of Internal Med, 1986;103:382-384 Suttorp-Schulten MS, Luyendijk L, VanDam AP, et al. Birdshot chorioretinopathy and Lyme Borreliosis. Amer J Ophthalmol
1993;115(2):149-53 Winward KE, Lawson-Smith J, et al. Ocular Lyme Borreliosis.
American Journal of Ophthalmology 1989;108:651-657 Winterkorn, Jaqueline. Lyme Disease: Neurologic and Ophthalmic Manifestations. Survey of Ophthalmology 1990;35(3):191-203
DeKoning J, Hoogkamp-Korstanje JAA, van der linde MR, Crjins HJGM. Demonstration of spirochetes in cardiac biopsies of patients
with Lyme disease. J Infect Dis 1989;160:150-153 Gasser R, Dusleag J, Beisinger E, et al. Reversal by ceftriaxone of dilated cardiomyopathy caused by Borrelia burgdorferi infection.
[Letter/Comments] Lancet, August 1, 1992;340(8814):317-18, From Lancet May 9, 1992;339(8802):1174-5
- Schmutzhard E, Pohl P, Stanek G. Borrelia burgdorferi antibodies
in patients with relapsing/remitting form and chronic progressive form of multiple sclerosis. J Neurol Neurosurg Psych 1988;51:1215-1218
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