Lyme Disease Support Group

Off-the-Charts Anxiety: Is a Tick Bite Making You Nuts?

Tick-borne infections aren't just causing sore joints and swollen knees.

Some cause psychiatric symptoms that often go untreated, some experts say.

By Leah Zerbe

Finding an engorged, blood-sucking tick attached to your skin can cause anxiety in and of itself.

After all, Lyme disease, an infection that causes multi-systemic, waxing-and-waning symptoms, and a disease that isn't always detected or effectively treated early on, is on the rise.

But researchers are starting to realize that, although getting bitten may be stressful, tick-borne infections could actually trigger panic attacks and other psychiatric disorders in some people.

"After treating thousands of patients with tick-borne disease in the past 20 years, it appears psychiatric symptoms are more commonly seen when there is a co-infection," explains psychiatrist Robert Bransfield, MD, former president of the International Lyme and Associated Diseases Society (ILADS) and president of the New Jersey Psychiatric Association.

Co-infections (when a tick passes along more than one disease) most often involve Lyme, babesiosis, a malaria-like infection that can cause fever, night sweats, and anemia; and bartonella (cat scratch fever), a bacterial infection that causes fever, headache, and raised skin rashes.

Co-infections are most often culprits in tick-related panic attacks and anxiety, and these multiple infections from tick bites are quite common, occurring in an estimated 30 percent of cases.

Dr. Bransfield, who is also associate director of psychiatry at Riverview Medical Center in New Jersey (a state with a high prevalence of Lyme disease), points out that 240 peer-reviewed scientific articles demonstrate an association between Lyme and other tick-borne diseases and mental illness.

For instance, a small study published in The Clinical Journal of Pain in 2005 found that patients experiencing panic attacks also suffered other symptoms not typical of standard panic attacks—extreme sensitivity to light, touch, and sounds, joint pain, mental fogginess, and migrating pain, all of which can be symptoms of Lyme disease—and those people tested positive for Lyme and babesiosis, which, like Lyme, is on the rise in the U.S.

Once treated with antibiotics for both diseases, the patients no longer experienced panic attacks.

Another study published in the American Journal of Psychiatry in 1994 found that 40 percent of patients with Lyme disease develop neurological impairment, which may not surface for months or years after a tick bite.

Psychiatric reactions included not only panic attacks, but also bipolar disorder, schizophrenia, dementia, obsessive-compulsive disorder, anorexia, and depression.

"Many of the psychiatric symptoms of Lyme and associated tick-borne diseases are mediated by immune mechanisms," Dr. Bransfield explains, adding that the in Lyme sufferers, the immune system gets thrown out of whack.

Furthermore, things like infection and stress can weaken and provoke the immune system, causing chronic inflammation, which has been linked to mental disorders.

Ultimately, there needs to be better interaction between infectious disease specialists, immunologists, and mental health practitioners, Dr. Bransfield says.

Tick-borne diseases could, quite literally, push you over the psychological edge.

And although other insect-borne diseases like West Nile virus may garner more headlines, you're far more likely to be sickened by a tick, according to U.S. Centers for Disease Control and Prevention statistics.

For instance, 2009 saw 720 cases of West Nile virus, while nearly 40,000 probable cases of Lyme disease occurred that year.

(Many doctors specializing in Lyme treatment believe Lyme disease numbers could be much higher because tests detecting the disease are not very reliable.)

Here's how to gauge whether your anxiety is linked to Lyme disease or other tick-borne diseases:

• Know how different panic attacks work.

Panic attacks spurred by Lyme disease or other tick-borne infections are generally different than non-infectious-based panic attacks, explains Dr. Bransfield.

A regular panic attack lasts a few minutes, but he says those brought on by tick-related ailments can go on for more than a half hour.

If your panic attack symptoms grow worse while on once-effective anti-anxiety treatment, it's another sign that Lyme or a related infection could be causing the attacks.

• Know when to consider tick-borne diseases.

Don't rely on finding a tick attached to your body to gauge your Lyme disease risk:

Many people don’t recall being bitten at all, while others notice migrating rashes or red or black-and-blue splotches shortly after being bitten.

Other early Lyme symptoms sometimes pop up a few days to a month after infection and include fatigue, fever, and chills. If the disease becomes more established in your body, it could cause cardiac and neurological problems.

If you think you've been recently infected with Lyme, ask your doctor to perform blood tests, and if negative, have them repeated about six weeks later.

If the results are still negative and you still suspect Lyme, you may want to see a doctor who specializes in treating Lyme aggressively.

Doctors should first test to rule out other conditions with similar symptoms.

• Fight with your doctor if you need to.

Lyme disease is a contentious subject, with two different schools of thought:

Some consider to be a short-term infection, others believe it can be chronic.

Some doctors take the threat of chronic Lyme seriously, and believe it should be treated with longer courses of antibiotics; others believe chronic Lyme doesn't exist.

(Read Lyme Hearing Highlights a Broken System and Lyme Disease Treatment Guidelines:

All Wrong? for more background.)

Until more doctors recognize the severity of the disease, if you believe you have Lyme it's best to advocate for a clinical diagnosis using the strategy above.

Here are three steps to keep Lyme disease from driving you crazy in the first place:

• Scan daily.

You slash your risk of developing Lyme disease if you scan your body daily for ticks.

Use a mirror or a partner to check hard-to-see places, and pay special attention to areas where ticks like to hide—armpits, bra and panty lines, and the groin.

And don't forget to keep your pet free of ticks naturally, too.

• Scrub-a-dub-dub.

Bath time presents a great opportunity for Lyme prevention because of these three things:

1. It's another chance to focus on your body and check for ticks.

2. You can wash off ticks that haven't attached yet.

3. You may take off clothing ticks were hanging onto.

For the best protection, take a shower within two hours of being outside.

• Don't rely on a bull's eye or blood tests.

While many people associate a bull's eye rash with Lyme disease, only about 30 percent of people who contract the infection show the telltale symptom.

Blood tests are also unreliable, and many doctors specializing in Lyme treatment believe clinical diagnosis is more effective than blood tests alone.

"The science surrounding testing and the interpretation of currently available tests is a complex subject," says Dr. Bransfield.

"Negative tests may occur when infection is present; there is no currently available test that can reliably rule out the presence of tick-borne disease."

If your family doctor has ruled out other health issues and you still believe you have Lyme disease or another tick-borne disease, join Lyme support groups and ask for doctor recommendations.

http://www.rodale.com/lyme-disease-panic-attacks?

2009-2012 Copyright Rodale.

Post edited by: Bettyg, at: 05/15/2012 11:26 PM

i did NOT take the time to see if this is in the earlier pages of this bart thread.

http://flash.lymenet.org/scripts/ultimatebb.cgi? ubb=get_topic;f=1;t=065655;p=0#000000

bettyg, iowa activist

Bartonella: A New Frontier in Chronic Disease[/u]

Written by medmonthly on July 2, 2012 in No comments

By Edward B. Breitschwerdt DVM, CEO/CSO Galaxy Diagnostics

& B. Robert Mozay

New research recently published in the journal of Emerging Infectious Disease supports an association between Bartonella infection and rheumatological symptoms.

The researchers tested 296 immunocompetent patients for evidence of Bartonella infection.

Bacteremia with one or more Bartonella species was found in

(41 percent) of patients with a prior diagnosis of Lyme disease (47 percent),

arthralgia/arthritis (21 percent),

chronic fatigue (20 percent) and

fibromyalgia (6 percent).

This study follows two decades of medical case series research implicating Bartonella infection in chronic diseases affecting the joints, neurological and vascular systems.

Bartonella are highly fastidious, immune-evasive, gram-negative bacteria which infect at very low levels of detection.

As a result, conventional serological and polymerase chain reaction (PCR) testing technologies are of limited value for the confirmation of infection.

These surprising new findings were made possible by a new testing technology developed by researchers at the North Carolina State University College of Veterinary Medicine (NCSU-CVM).

The NCSU research team discovered a way to overcome past testing challenges through the development and use of a propriety enrichment media (Bartonella alpha-proteobacteria growth medium or BAP-G-M).

When paired with highly sensitive PCR testing, the BAPGM media increases the sensitivity of detection by 4 to 5 times over conventional methods.

Popularly known as the key agents in cat scratch disease (CSD), trench fever, and carrion’s disease, Bartonella were essentially rediscovered in the 1990s with the emergence of HIV and the clinical application of DNA testing technologies.

There are now over 25 characterized species of Bartonella, 12 of which have been documented as pathogenic for humans.

A wide range of animals serve as natural hosts for this zoonotic bacteria, most significantly the cat and rodent populations, which may be transmitted by a number of different vectors including fleas, lice, ticks, and biting flies.

A 2004 Nature article describes Bartonella as one of the most important pathogens in emerging infectious disease along with Helicobacter pylori (H. pylori).

Unlike H. pylori, however, Bartonella is not localized to the gastrointestinal (GI) tract, but can infect multiple systems in the body.

Well-established as life-threatening in patients with compromised immune systems, the emerging research indicates that Bartonella are also a problem in patients with competent immune systems.

Research on HIV patients, suggests a pattern of progressive presentations of bartonellosis from mild CSD symptoms to peliosis hepatitis and bacillary angiomatosis.

Bartonella has also been documented as a cause of culture-negative endocarditis, osteomyelitis, meningitis, encephalitis, neuroentinitis and vasculitis.

Mounting case evidence indicates that atypical presentations of cat scratch disease may not be nearly as uncommon as previously thought, especially in high-risk patient populations.

Symptoms may range from

recurring fever, headaches, insomnia, joint/muscle aches and pains to arthropathy, myalgia, neurocognitive and neuromotor dysfunction, seizures, vasculitis, and vaso-proliferative tumors or lesions, as well as the more common lymphadenopathy and splenomegaly.

Risk factors associated with Bartonella infection include high levels of animal contact and vector exposure.

In an earlier study using the Bartonella ePCR™ test, the NCSU research team found that 23.9 percent of 192 patients with occupational animal contact or extensive arthropod exposure were bacteremic with one or more Bartonella species when blood, serum and BAPGM enrichment culture PCR results were combined.

Although this high prevalence of bacteremia is biased by testing at-risk, sick individuals, it clearly demonstrates that intravascular infection with Bartonella species is much more common in immunocompetent patients than was previously suspected.

Importantly, Bartonella infection may also represent a safety concern in the blood supply in transplant medicine and chronic disease management.

Of particular concern are medical conditions managed with therapeutic regimens that cause immune suppression, including rheumatologic diseases such as rheumatoid arthritis or lupus, or organ transplantation.

Other conditions, such as cancer, may involve the use of medications that cause immune suppression, such as high-dose steroid components of lymphoma protocols.

Blood banking practice must also consider the potential for the transmission of Bartonella through transfusion of blood products.

These safety issues indicate the need for better prevalence studies to determine the cost-benefit of screening for safety reasons, including the screening of blood products.

Recommendations for medical practitioners:

•Consider testing patients at high risk who present with general rheumatic or neurological symptoms for Bartonella infection.

•Make clinical protocols involving immune suppression, including transplantation and cancer treatments, safer by testing high-risk patients for Bartonella infection.

•Advise patients to exercise routine precautions to avoid animal bites and scratches when dealing with domestic or wild animals and to avoid exposure to arthropod and insect vectors.

The emerging research on Bartonella is very compelling and the need for clinical research that directly addresses the role these bacteria play in human and animal health is clear.

Because the genus Bartonella involves multiple animal reservoirs, animal and human disease, arthropod and insect vector transmission, and an environmental impact on human health, multidisciplinary research efforts following the One Health Initiative are needed to effectively address the far-reaching implications and the redefinition of “bartonellosis” as an emerging infectious disease of the 21st century.

The Bartonella ePCR™ test is now commercially available at Galaxy Diagnostics.

Galaxy Diagnostics holds an exclusive license to the BAPGM technology from North Carolina State University.

For more information, see www.galaxydx.com.

More information on the One Health Initiative may be found at www.onehealthcommission.org/

eni, MD, CMO, Galaxy Diagnostics

http://medmonthly.com/2012/07/bartonella-a-new-frontier-in- chronic-disease/

© 2012 medmonthly.com

Post edited by: Bettyg, at: 07/09/2012 03:32 PM

Volume 18, Number 5—May 2012 -- LENGTHY!! broken up by bettyg

Research

Article Contents

Materials and Methods

Results

Discussion

Acknowledgments

References

Figure 1

Figure 2

Table 1

Table 2

Table 3

Table 4

Suggested Citation

Ricardo G. Maggi, B. Robert Mozayeni, Elizabeth L. Pultorak, Barbara C. Hegarty, Julie M. Bradley, Maria Correa, and Edward B. Breitschwerdt

Author affiliations:

North Carolina State University, Raleigh, North Carolina, USA

(R.G. Maggi, E.L. Pultorak, B.C. Hegarty, J.M. Bradley, M. Correa, E.B. Breitschwerdt);

Translational Medicine Group, PC, North Bethesda, Maryland, USA (B.R. Mozayeni)

Suggested citation for this article

Abstract

Bartonella spp. infection has been reported in association with an expanding spectrum of symptoms and lesions.

Among 296 patients examined by a rheumatologist, prevalence of antibodies against Bartonella henselae, B. koehlerae, or B. vinsonii subsp. berkhoffii (185 [62%]) and Bartonella spp. bacteremia (122 [41.1%]) was high.

Conditions diagnosed before referral included Lyme disease (46.6%), arthralgia/arthritis (20.6%), chronic fatigue (19.6%), and fibromyalgia (6.1%).

B. henselae bacteremia was significantly associated with prior referral to a neurologist, most often for blurred vision, subcortical neurologic deficits, or numbness in the extremities, whereas B. koehlerae bacteremia was associated with examination by an infectious disease physician.

This cross-sectional study cannot establish a causal link between Bartonella spp. infection and the high frequency of neurologic symptoms, myalgia, joint pain, or progressive arthropathy in this population; however, the contribution of Bartonella spp. infection, if any, to these symptoms should be systematically investigated.

The genus Bartonella comprises at least 26 species or subspecies of vector-transmitted bacteria, each of which has evolved to cause chronic bacteremia in >1 mammalian reservoir hosts (1–4).

Among these, bartonellae of 14 species or subspecies have been implicated in zoonotic diseases (5,6), including cat-scratch disease, which is caused by B. henselae transmission during a cat bite or scratch and characterized by acute onset of self-limiting fever and regional lymphadenopathy (7–9).

Recent observations, however, are causing a paradigm shift from the assumption that infection with a Bartonella sp. consistently induces an acute, self-limiting illness to the realization that subsets of infected, immunocompetent patients can become chronically bacteremic (10–15).

After B. henselae was confirmed as the primary cause of cat-scratch disease in the early 1990s, several reports described an association between the newly identified bacterium and rheumatic disease manifestations, variously described as rheumatoid, reactive, or chronic progressive polyarthritis (16–20).

One study, however, failed to isolate B. henselae from synovial fluid of 20 patients with chronic arthritis (21).

Because epidemiologic evidence supports an association between rheumatic symptoms and cat-scratch disease and because arthritis is a primary disease manifestation of Borellia burgdorferi infection (Lyme disease), we explored whether antibodies against and bacteremia with Bartonella spp. can be detected in patients examined for arthropathy or chronic myalgia.

Our primary objective was to determine the serologic and molecular prevalence of Bartonella spp. bacteremia in patients referred to a clinical rheumatologist.

We also compared self-reported symptoms, health history, and demographic factors with Bartonella spp. bacteremia as determined by an enrichment blood culture platform combined with PCR amplification and DNA sequencing, when possible, to determine the Bartonella species and strain.

This study was conducted in conjunction with North Carolina State University Institutional Review Board approval (IRB# 164–08–05).

Materials and Methods

Study Population

For this cross-sectional study, we enrolled only patients examined by a rheumatologist in the Maryland–Washington, DC, USA, area from August 25, 2008, through April 1, 2009.

Because Bartonella spp. are known to primarily infect cells within the vascular system, including erythrocytes, endothelial cells, and potentially circulating and tissue macrophages (1,5,6), selection was biased by patients who had historical, physical examination, or laboratory evidence of small vessel disease, including a subset of patients with a prior diagnosis of Lyme disease or chronic post–Lyme syndrome.

We also included patients with chronic joint pain, prior documentation of synovial vascular inflammation, or a diagnosis of rheumatoid arthritis.

A standardized 5-page questionnaire was mailed to each participant for self-report.

The questionnaire collected information about demographics, animal/arthropod exposure, history of visiting a medical specialist, outdoor activity, self-reported clinical symptoms, and concurrent conditions.

Questionnaires were returned to the Intracelluar Pathogens Research Laboratory at North Carolina State University, College of Veterinary Medicine, Raleigh, North Carolina, USA, where results were entered into an electronic database.

Sample Collection

From each patient, the attending rheumatologist aseptically obtained anticoagulated blood samples (in EDTA tubes) and serum samples and shipped them overnight to the laboratory.

Patient variations included timing of sample collection relative to onset of illness, duration of illness, current illness severity, and prior or recent use of antimicrobial drugs.

The samples were then processed in a limited-access laboratory.

Sample Processing

Immunofluorescence Antibody Assay

To determine the antibody titer to each Bartonella species or subspecies, we used B. henselae, B. koehlerae, and B. vinsonii subsp. berkhoffii (genotypes I, II, and III) antigens in a traditional immunofluorescence antibody (IFA) assay with fluorescein conjugated goat anti-human IgG (Pierce Antibody; Thermo Fisher Scientific, Rockford, IL, USA) (10,12,22).

To obtain intracellular whole bacterial antigens for IFA testing, we passed isolates of B. henselae (strain Houston-1, ATCC #49882); B. koehlerae (NCSU FO-1–09); and B. vinsonii subsp. berkhoffii genotypes I (NCSU isolate 93-CO-1, ATCC #51672), II (NCSU isolate 95-CO-2), and III (NCSU isolate 06-CO1) from agar-grown cultures into Bartonella-permissive tissue culture cell lines:

AAE12 (an embryonic Amblyomma americanum tick cell line) for B. henselae, DH82 (a canine monocytoid cell line) for B. koehlerae, and Vero (a mammalian fibroblast cell line) for the B. vinsonii genotypes.

Heavily infected cell cultures were spotted onto 30-well Teflon coated slides (Cel-Line; Thermo Fisher Scientific), air dried, acetone fixed, frozen, and stored.

Serum samples were diluted in a phosphate-buffered saline solution containing normal goat serum, Tween-20, and powdered nonfat dry milk to block nonspecific antigen binding sites and then incubated on antigen slides.

All available patient serum was screened at dilutions from 1:16 to 1:64.

Samples reactive at a 1:64 dilution were further tested with 2-fold dilutions to 1:8192.

As in previous studies, we defined a seroreactive antibody response against a specific Bartonella sp. antigen as a threshold titer of 64 (10–15,23,24).

Bartonella α Proteobacteria Growth Medium Enrichment Culture

Each sample was tested by PCR amplification of Bartonella spp. DNA before and after enrichment of blood and serum in Bartonella α Proteobacteria growth medium (BAPGM) (10–14,23–26).

The BAPGM platform incorporates 4 PCR steps, representing independent components of the testing process for each sample, as follows:

step 1) PCR amplifications of Bartonella spp. after DNA extraction from whole blood and serum;

steps 2 and 3) PCR after whole blood culture in BAPGM for 7 and 14 days; and

step 4) PCR of DNA extracted from subculture isolates (if obtained after subinoculation from the BAPGM flask at 7 and 14 days onto plates containing trypticase soy agar with 10% sheep whole blood, which are incubated for 4 weeks).

To avoid DNA carryover, we performed PCR sample preparation, DNA extraction, and PCR amplification and analysis in 3 separate rooms with a unidirectional work flow.

All samples were processed in a biosafety cabinet with HEPA (high-efficiency particulate air) filtration in a limited-access laboratory.

Methods used to amplify Bartonella DNA from blood, serum, and BAPGM liquid culture and subculture samples included conventional PCR with Bartonella genus primers targeting the 16S-23S intergenic spacer region (ITS) and a second PCR with B. koehlerae ITS species-specific primers, as described (13,25–29).

Amplification of the B. koehlerae ITS region was performed by using oligonucleotides Bkoehl-1s: 5′-CTT CTA AAA TAT CGC TTC TAA AAA TTG GCA TGC-3′ and Bkoehl1125as: 5′-GCC TTT TTT GGT GAC AAG CAC TTT TCT TAA G-3′ as forward and reverse primers, respectively.

Amplification was performed in a 25-µL final volume reaction containing 12.5 µL of Tak-Ex Premix (Fisher Scientific), 0.1 µL of 100 µM of each forward and reverse primer (IDT; DNA Technology, Coralville, IA, USA), 7.3 µL of molecular grade water, and 5 µL of DNA from each sample tested.

Conventional PCR was performed in an Eppendorf Mastercycler EPgradient (Hauppauge, NY, USA) under the following conditions: 1 cycle at 95°C for 2 s, followed by 55 cycles with DNA denaturing at 94°C for 15 s, annealing at 64°C for 15 s, and extension at 72°C for 18 s. The PCR was completed by a final cycle at 72°C for 30 s.

As previously described for the Bartonella ITS genus and B. koehlerae–specific PCRs, all products were analyzed by using 2% agarose gel electrophoresis and ethidium bromide under UV light, after which amplicon products were submitted to a commercial laboratory (Eton Bioscience Inc., Research Triangle Park, NC, USA) for DNA sequencing to identify the species and ITS strain type (13,15,28,30).

To check for potential contamination during processing, we simultaneously processed a noninoculated BAPGM culture flask in the biosafety hood in an identical manner for each batch of patient blood and serum samples tested.

For PCR, negative controls were prepared by using 5 µL of DNA from the blood of a healthy dog. All controls remained negative throughout the course of the study.

Statistical Analysis

Descriptive statistics were obtained for all demographic variables, self-reported clinical symptoms and concurrent conditions, previous specialist consultation, and self-reported exposures.

The χ2 test was used to assess associations between self-reported clinical symptoms and previous specialist consultation separately with PCR results for B. henselae; B. koehlerae; and B. vinsonii subsp. berkhoffii genotypes I, II, and III.

The Fisher exact test was used when expected cell value was <5. For the initial analysis, a liberal α value (α<0.10) was selected.

The effect of each significant variable on the outcome variables was adjusted in separate multivariate logistic regression models controlling for age, sex, and health status. The models were repeated for different possible outcomes: PCR results for B. henselae or PCR results for B. koehlerae.

Variables maintaining p<0.05 were considered significant.

For some comparisons of potential interest, we were unable to estimate associations with the outcome(s) of interest because of low numbers (e.g., B. vinsonii subsp. berkhoffii genotypes I, II and III).

Statistical analyses were performed by using SAS/STAT for Windows version 9.2 (SAS Institute Inc., Cary, NC, USA).

Results

Patient Characteristics

Figure 1

Figure 1. . . Bartonella spp. PCR results for the 15 most frequently reported previous diagnoses. OA, osteoarthritis; RA, rheumatoid arthritis.

The age range of the 296 patients was 3–90 years; median ages were 46 years for women and 36 years for men (Table 1).

Women made up ≈70% of the study population. Most (68.2%) patients reported that they felt ill, whether chronically or infrequently, and 27.7% considered themselves to be generally healthy.

The most common animal exposure reported was dog (n = 252; 85.1%), followed by cat (n = 202; 68.2%) and horse (n = 86; 29.0%).

Most patients reported having been bitten or scratched by an animal (n = 202; 68.2%) or exposed to ticks (n = 229; 77.4%) and biting flies (n = 160; 54.0%).

Hiking was the predominant outdoor activity reported (52.0%).

Most (273 [92.2%]) patients reported having had a condition diagnosed before visiting the rheumatologist.

Previously diagnosed conditions included Lyme disease (46.6%), arthralgia/arthritis or osteoarthritis/rheumatoid arthritis (20.6%), chronic fatigue (19.6%), and fibromyalgia (6.1%) (Figure 1).

Serologic and BAPGM Findings

Figure 2

Figure 2. . . Bartonella PCR amplification results from blood, serum, and enrichment blood culture with the Bartonella α Proteobacteria growth medium.

Of 296 patients, 120 had positive PCR results in 1 component....

Of the 296 patients, 185 (62.5%) were seroreactive to >1 Bartonella sp. antigens and 122 (41.1%) were infected with B. henselae, B. koehlerae, B. vinsonii subsp. berkhoffii, or Bartonella spp. Of the 122 patients with Bartonella spp. infection, PCR results were positive but DNA sequencing was unsuccessful or did not enable species identification for 29 (23.7%).

After subculture, 6 isolates were obtained from 5 samples: 3 B. henselae isolates, 2 B. koehlerae isolates, and 1 Bartonella sp. isolate that was not fully characterized.

Of the Bartonella-infected patients, 120 (98.4%) had a positive PCR result after DNA extraction from blood, serum, or enrichment culture (Figure 2), and 2 (1.6%) had a positive PCR result only after subculture isolation.

For B. henselae, 67 (22.6%) patients were seroreactive and 40 (13.5%) had positive PCR results. Of these 40 patients, only 7 (17.5%) were concurrently B. henselae seroreactive, whereas 33 (82.5%) patients who had a positive PCR result were not seroreactive to B. henselae antigens.

There was no association between B. henselae antibodies and bacteremia (p = 0.37).

For B. koehlerae, 89 (30.1%) patients were seroreactive and 54 (18.2%) had positive PCR results. Of these 54 patients, 24 (44.4%) were seroreactive to B. koehlerae by IFA assay, whereas 29 (53.6%) were not seroreactive to B. koehlerae antigens.

One patient with a positive B. koehlerae PCR result did not have a concurrent IFA test result (serum not submitted).

There was an association between B. koehlerae seroreactivity and bacteremia (p = 0.008); seroreactive patients were more likely to be infected (odds ratio [OR] 2.25 [1.22–4.15]).

For B. vinsonii subsp. berkhoffii, 148 (50.0%) patients were seroreactive by IFA testing to at least 1 of 3 genotypes, and 10 (3.4%) had a positive PCR.

Of these 10 patients, 3 were infected with genotype I, 6 were infected with genotype II, and for 1 patient the genotype could not be defined on the basis of readable DNA sequence.

Seroreactivity to genotypes I, II, and III was found for 77 (26.0%), 102 (34.5%), and 82 (27.7%) patients, respectively.

There was no association between B. vinsonii subsp. berkhoffii seroreactivity and bacteremia. Combined PCR and IFA assay results are summarized in Table 2.

Of the patients with a positive PCR, 65% reported a prior diagnosis of Lyme disease (n = 138), bartonellosis (n = 29), or babesiosis (n = 14).

Among the 138 patients with a prior diagnosis of Lyme disease, the prevalence of Bartonella spp. antibodies and bacteremia were 93 (67.4%) and 57 (41.3%), respectively.

Factors Associated with Bartonella spp.

PCRs indicated the following:

B. henselae positivity was associated (p<0.05) with blurred vision and numbness (Table 3), patients who had visited a neurologist were more likely than those who had not to be B. henselae positive, older median age was significantly associated with B. koehlerae positivity, and patients who reported paralysis were more likely to be positive for B. vinsonii subsp. berkhoffii.

No associations were found for self-reported exposures (e.g., insect or animal exposure) and positive PCR for B. henselae, B. koehlerae, or B. vinsonii subsp. berkhoffii.

No associations were found for B. henselae, B koehlerae, or B vinsonii subsp. berkhoffii positivity and seroreactivity.

Logistic Regression Analysis

To identify factors associated with PCR positivity for B. henselae or B. koehlerae, we adjusted the models for 3 biological confounders: age, sex, and health status (Table 4).

We identified the following factors as associated with B. henselae–positive PCR result:

blurred vision (adjusted OR [aOR] 2.37, 95% CI 1.13–4.98), numbness (aOR 2.74, 95% CI 1.26–5.96), and previous consultation with a neurologist (aOR 2.76, 95% CI 1.33–5.73).

No self-reported symptoms were significantly associated with PCR positivity for B. koehlerae.

However, patients who had visited an infectious disease physician were more likely to have a. B. koehlerae–positive PCR result (aOR 1.98, 95% CI 1.05–3.75).

Discussion

We identified unexpectedly high serologic and molecular prevalence for B. henselae, B. koehlerae, and B. vinsonii subsp. berkhoffii in patients who had been examined by a rheumatologist, of whom more than half reported a prior diagnosis of Lyme disease, bartonellosis, or babesiosis.

However, the diagnostic criterion upon which these infections were based was not available for review because all prior diagnoses were self-reported.

Overall, 185 (62.5%) of 296 patients had antibodies to B. henselae, B. koehlerae, or B. vinsonii subsp. berkhoffii, and 122 (41.1%) were positive for Bartonella spp. according to PCR. In most instances, DNA sequencing of the amplified product facilitated identification of the infecting species.

The prevalence of antibodies against Bartonella spp. (93 [67.4%]) and bacteremia [57 [1.3%]) among 138 patients with a prior diagnosis of Lyme disease did not differ from that of the overall study population.

Because our analysis was restricted to patients selected by a rheumatologist practicing in a Lyme disease–endemic region, extrapolations to other regions or other rheumatology practices might not be applicable.

Also, because the survey was self-administered, objective confirmation of symptoms, conditions, and diagnoses was not always possible; therefore, responses might have been subject to respondent bias.

Similarly, because responses associated with symptoms, conditions, and exposures might have occurred over a protracted time, survey responses might also be subject to recall bias.

Despite these study limitations, B. henselae infections seemed to be more common in patients who reported blurred vision, numbness in the extremities, and previous consultation with a neurologist before referral to the rheumatologist.

In a case series of 14 patients, the following were reported by 50% of patients infected with a Bartonella species, specifically B. henselae, B. vinsonii subsp. berkhoffii, or both: memory loss, numbness or a loss of sensation, balance problems, and headaches (10).

Another 6 B. henselae–bacteremic patients reported seizures, ataxia, memory loss, and/or tremors; 1 of these patients was co-infected with B. vinsonii subsp. berkhoffii, and another was positive for B. henselae by PCR after enrichment of cerebrospinal fluid in BAPGM (23).

An enrichment culture approach also identified an association between intravascular infection with B. vinsonii subsp. berkhoffii genotype II and B. henselae and neurologic symptoms in a veterinarian and his daughter (12).

Symptoms in the father included progressive weight loss, muscle weakness, and lack of coordination;

symptoms in the daughter were headaches, muscle pain, and insomnia. For each patient, after repeated courses of antimicrobial drugs, blood cultures became negative, antibody titers decreased to nondetectable levels, and all neurologic symptoms resolved.

Although no symptoms were statistically associated with B. koehlerae infection, patients infected with B. koehlerae were more likely to have previously consulted an infectious disease physician.

Of the 54 B. koehlerae patients with a positive PCR result, 54% reported a prior diagnosis of Lyme disease (n = 25), bartonellosis (n = 3), or babesiosis (n = 1). Fatigue, insomnia, memory loss, and joint and muscle pain were frequent complaints among those with a positive PCR result for B. koehlerae, but these symptoms did not differ in frequency from those in patients with negative PCR.

Similar symptoms were previously reported in a small case series involving B. koehlerae–bacteremic patients (13).

Peripheral visual deficits, sensory loss, and hallucinations resolved in a young woman after antimicrobial drug treatment for B. koehlerae infection (30).

Because of the small number of patients with positive PCR results for B. vinsonii subsp. berkhoffii, we restricted the multivariate analysis to those with positive results for B. henselae and B. koehlerae.

Because limited sample size affected our ability to conduct multivariate analysis to control for potential confounders for B. vinsonii subsp. berkhoffii positivity, the χ2 associations with B. vinsonii subsp. berkhoffii positivity should be interpreted with caution.

Although the pathogenic relevance of the high Bartonella spp. seroprevalence and bacteremia in this patient population are unclear, these results justify additional prospective studies involving more narrowly defined patient and control populations.

Of the 92 patients infected with B. koehlerae, B. henselae, or B. vinsonii subsp. berkhoffi, 69 (75%) had at least 1 discordant IFA assay result for Bartonella spp. antigen seroreactivity and only 34 (30.6%) had a concordant species-specific PCR and IFA result.

Also, consistent with previous study findings (15), the PCRs depicted in Figure 2 illustrate an increased likelihood of positivity if blood, serum, and enrichment blood cultures are independently tested.

According to these and previous results (7,18,31,32), a subset of Bartonella spp.–bacteremic patients could be anergic and might not produce a detectable IFA response, or alternatively, the substantial antigenic variation among various Bartonella strains might result in false-negative IFA assay results for some patients.

In a study on Bartonella serology conducted by the Centers for Disease Control and Prevention, IFA cross-reactivity among Bartonella species occurred in 94% of patients with suspected cat-scratch disease (33).

Despite the lack of concordance between serologic results and BAPGM enrichment PCR results, most (185 [62.5%]) patients in our study were seroreactive to Bartonella spp., suggesting prior exposure to >1 Bartonella spp. Because serologic cross-reactivity to Chlamydia spp. and Coxiella burnettii antigens has been reported, exposure to these or other organisms might have contributed to the high seroprevalence.

In a previous study involving 32 healthy volunteers and patients at high risk for Bartonella spp. bacteremia, seroprevalence rates for B. henselae, B. koehlerae and B. vinsonii subsp. berkhoffii genotypes I and II were 3.1%, 0%, 0,%, and 50%, respectively, for the healthy population compared with 15.6%, 9.2%, 19.8%, and 28.1%, respectively, for the high-risk population (15).

Although in that study and the study reported here, the same test antigens and identical IFA assays were used and the same research technologist interpreted the results, the overall seroprevalence in the study reported here was higher than that among high-risk patients with extensive arthropod or animal contact (49.5%) and differed substantially from serologic results from healthy volunteers (15).

However, in the study reported here, a large portion of the population (34.5%) was also seroreactive to B. vinsonii berkhoffii genotype II.

Immunophenotypic properties giving rise to seroreactivity to this particular antigen among healthy control and patient populations have not been clarified but could be related to polyclonal B-cell activation, commonly found in patients with rheumatologic or chronic inflammatory diseases.

It is becoming increasingly clear that no single diagnostic strategy will confirm infection with a Bartonella sp. in immunocompetent patients.

Before the current study, we primarily used BAPGM enrichment blood cultures and PCR to test symptomatic veterinarians, veterinary technicians, and wildlife biologists, who seem to be at occupational risk for Bartonella sp. bacteremia because of animal contact and frequent arthropod exposure (10–15,23).

Cats are the primary reservoir hosts for B. henselae and B. koehlerae, whereas canids, including dogs, coyotes and foxes, are the primary reservoir hosts for B. vinsonii subsp. berkhoffii (4,6,29,34).

Although infrequent when compared with cat transmission of B. henselae resulting in classical cat-scratch disease, dogs have been implicated in the transmission of B. vinsonii subsp. berkhoffii and B. henselae to humans (35,36).

The predominant symptoms reported among occupationally at-risk patient populations have included severe fatigue, neurologic and neurocognitive abnormalities, arthralgia, and myalgia (10–13,23).

In the study reported here, dog (85%) and cat (68%) contact were reported by most respondents; however, no associations were found between infection with a Bartonella sp. and contact with a specific animal.

Similarly, exposure to mosquitoes, ticks, fleas, and biting flies were all reported by >50% of the study population.

The results of this study support documentation of Bartonella spp. bacteremia in patients seen by a rheumatologist in a Lyme disease–endemic area and provides the basis for future studies to ascertain the prevalence of Bartonella spp. in patients with rheumatic and neurologic symptoms.

Dr Maggi is a research assistant professor in the Department of Clinical Sciences at North Carolina State University College of Veterinary Medicine. His research has focused on the development of novel or improved molecular diagnostic and culture methods for detection of Bartonella spp. infections in animals and humans.

Acknowledgments

This study was supported in part by the state of North Carolina, a grant from the American College of Veterinary Internal Medicine Foundation, and a monetary donation from Bayer Animal Health.

E.B.B., in conjunction with Sushama Sontakke and North Carolina State University, holds US Patent No. 7,115,385, Media and Methods for Cultivation of Microorganisms, which was issued October 3, 2006.

E.B.B. is chief scientific officer for Galaxy Diagnostics, a newly formed company that provides diagnostic testing for the detection of Bartonella species infection in animals and human patients.

R.G. Maggi has lead research efforts to optimize the BAPGM platform and is the scientific technical advisor for Galaxy Diagnostics.

R. Mozayeni was the attending physician for the patients described in this study and has recently joined Galaxy Diagnostics as the chief medical officer. All other authors have no potential conflicts.

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Figures

Figure 1. . . Bartonella spp. PCR results for the 15 most frequently reported previous diagnoses. OA, osteoarthritis; RA, rheumatoid arthritis.

Figure 2. . . Bartonella PCR amplification results from blood, serum, and enrichment blood culture with the Bartonella α Proteobacteria growth medium. Of 296 patients, 120 had positive PCR results in...

Tables

Table 1. Characteristics and Bartonella spp. PCR results for 296 patients examined by a rheumatologist, Maryland–Washington, DC, USA, August 25, 2008–April 1, 2009

Table 2. Test results for Bartonella spp. in 296 patients examined by a rheumatologist, Maryland–Washington, DC, USA, August 25, 2008–April 1, 2009

Table 3. Factors associated with Bartonella spp. positivity by PCR, among 296 patients examined by a rheumatologist, Maryland–Washington, DC, USA, August 25, 2008–April 1, 2009

Table 4. Factors associated with positive PCR result for Bartonella henselae and B. koehlerae among 296 patients examined by a rheumatologist, Maryland–Washington, DC, USA, August 25, 2008–April 1, 2009

Suggested citation for this article: Maggi RG, Mozayeni BR, Pultorak EL, Hegarty BC, Bradley JM, Correa M, et al. Bartonella spp. bacteremia and rheumatic symptoms in patients from Lyme disease–endemic region. Emerg Infect Dis [serial on the Internet]. 2012 May [date cited]. http://dx.doi.org/10.3201/eid1805.111366

DOI: 10.3201/eid1805.111366

Table of Contents – Volume 18, Number 5—May 2012

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Bacillary Angiomatosis

Author: KoKo Aung, MD, MPH, FACP

Chief Editor: Burke A Cunha, MD

Overview

Clinical Presentation

Differential Diagnoses

Workup

Treatment & Management

Medication

Follow-up

Overview

Background

Pathophysiology

Epidemiology

Clinical Presentation

History

Physical

Causes

Workup

Laboratory Studies

Imaging Studies

Procedures

Histologic Findings

Treatment & Management

Medical Care

Surgical Care

Consultations

Diet

Activity

Follow-up

Further Outpatient Care

Deterrence/Prevention

Complications

Prognosis

Background

Bacillary angiomatosis (BA) is the vascular proliferative form of Bartonella infection. Bacillary angiomatosis was first described in 1983 in a patient infected with HIV.[1]

The disease has since been described in patients following organ transplants and in immunocompromised persons.

It is occasionally reported in immunocompetent patients.

Initially, bacillary angiomatosis was called epithelioid angiomatosis because of its histologic appearance.

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