Archive for the ‘Lyme’ Category

Why What’s on a Death Certificate Matters So Much

https://www.lymedisease.org/touched-by-lyme-why-whats-on-a-death-certificate-matters-so-much/

TOUCHED BY LYME: Why what’s on a death certificate matters so much

Oct. 22, 2020

By Dorothy Kupcha Leland

Carl Hamrin

Carl Hamrin was born in Sweden, emigrated to the United States, and became a US citizen. His family settled in Maine, where he worked in the field of computer sciences. He had years of good health, as he and his wife Jeannie led an active outdoor life.

However, nine years ago, things changed for Carl. That’s when he started experiencing troublesome symptoms, including partial paralysis. He couldn’t move his arms to feed himself, shave, or push himself up out of a chair. So, Jeannie started taking him to doctors.

“Since 2011, Carl was in five different hospitals, three rehabs, saw over 55 MDs, DOs, NDs – GPs, Neurologists, cardiologists, hematologists, Infectious Disease MDs, oncologists, dermatologists, allergists, hand specialists, NPs, PTs, OTs, from Boston to Bangor, as well as in four different countries,” she wrote me in an email.

A diagnosis of Lyme

At one point, a neurologist thought to test him for Lyme disease—no one else had!—and he was positive. But that didn’t settle things for most of the doctors they saw.

“He was consistently subjected to both verbal and written microaggressions. Some ‘micros’ were due to ignorance, some to systemic failures, some to inability to think outside of algorithms and protocols, some to poor social skills,” Jeannie said. “But all were due to the outdated politics of CDC, IDSA and insurance companies.

Some of the treatments Carl received helped somewhat. Others, not so much. Yet, Carl always had a sharp intellect, says Jeannie, and he worked hard to understand Lyme disease and what it was doing to him.

“He chewed through libraries, medical journals and Kindle at an alarming rate to plan his attack on the issue at hand. He did not want to be outsmarted by a tick!” (For the record, Jeannie says they were never aware of a tick bite.)

The final insult

Last year, Carl succumbed to his illness at age 86, passing away on August 14, 2019. According to Jeannie, the final insult from the medical establishment was the failure to list Lyme disease on his death certificate as an underlying condition that began the chain of events or to list it in Part II (other significant conditions) of Carl’s death.

Hamrin death certificate

The cause of death on his certificate is listed as acute leukemia for one week and myelodysplastic syndrome for six years.

Jeannie has been trying to get that certificate amended, to indicate that Lyme disease was a major factor in her husband’s death. So far, she keeps running into brick walls.

In one document she shared with me, a hospital official stated: “At the time of Carl’s last hospitalization, he did not have active Lyme disease and this is the reason for not including the diagnosis on the death certificate.”

(Well, that’s pretty much the whole Lyme controversy in a nutshell, isn’t it—the question of what constitutes an “active infection”? The Infectious Diseases Society of America sets the Lyme agenda followed by most hospitals in the US. And despite lots of scientific research to the contrary, the IDSA still insists that the Lyme bacteria cannot survive a short course of antibiotics. Ergo, Carl had no active infection.)

Jeannie has asked the hospital to release Carl’s cerebrospinal fluid (CSF) sample, his bone marrow core biopsy, clot section and aspirate smears collected eight days prior to his death, which might shed some light on the subject.  “They will not release them,” she says.

Death certificates matter

Why is this so important? As an article from Today’s Geriatric Medicine puts it:

“Despite its title, a death certificate is a living document. The submitted data impact patients and families with regard to issues of life insurance, estate settlement, genetic risk factors, and closure. The certificate exists as a medical-legal document and can stand alone in a court of law. It lives at the state level, is purchased by the National Center for Health Statistics, and is then entered into the National Vital Statistics System under the Centers for Disease Control and Prevention. It subsequently merges under the statistical umbrella of the World Health Organization to inform comparisons of international mortality rates. Death certificate data therefore inform health care policy,prevention campaigns, funding streams, and research projects from the local to international levels.”

Why should the entire Lyme community care about this issue? Because severe under-reporting of Lyme-related deaths contributes to the “Lyme blindness” that afflicts so much of the medical establishment.

This CDC study published in 2011 looked at death certificates from 45 states over a four-year period. Guess what? Researchers only found 114 that mentioned Lyme disease, leading them to conclude that Lyme disease is rarely fatal. But, as Carl Hamrin’s case shows, what’s actually written on the death certificate is far from the complete story.

How do we get a better count?

In search of a clearer picture of Lyme-related deaths, the MyLymeData patient registry includes a decedent survey. It allows family members to register the cause of death for their loved one and information about that person’s Lyme experience.

Click here for information about MyLymeData.

The Lyme Disease Biobank, a project of the Bay Area Lyme Foundation, also allows Lyme patients to plan to donate organs and tissue after death from any cause. It is the only national program to collect postmortem samples from individuals with tick-borne infections.

Click here to learn more about the Lyme Disease Biobank.

Jeannie Hamrin continues her quest to have her husband’s certificate amended. “Like a canary in the coal mine, I want to honor Carl’s legacy to be a sentinel case that gets Lyme recognized as a major public health issue, so hospitals will train their staff on listing Lyme as a contributing cause of death, rather than misdiagnosed as something else or totally ignored.”

TOUCHED BY LYME is written by Dorothy Kupcha Leland, LymeDisease.org’s Vice-president and Director of Communications. She is co-author of When Your Child Has Lyme Disease: A Parent’s Survival Guide. Contact her at dleland@lymedisease.org.

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**Comment**

Great article that brings up a very important issue – how death certificates are recorded.  This, in light of COVID-19 over counting, and in light of Lyme/MSIDS undercounting clearly shows how numbers matter.

The problem, as always, is the CDC rigs everything for their own lucrative patent interests:  

I fully believe after years of living in ‘Alice in Lymeland,’ that the only way we make forward progress is to do it ourselves.  Our public ‘authorities’ are not to be trusted and are often the very problem, and this is a very old 40 year problem.

Both the biobank for specimens and MyLymeData help by being independently led and frankly for just not dodging the truth. The problem with working with the government (CDC/NIH/IDSA/NIAID/FDA) is their entire premise is wrong, therefore all outcomes will be wrong.  This is a case where truth will only be found outside the system, and in the hands of those who are truly transparent and are who are searching/looking hard.  From my layman’s understanding, most of these pathogens are very difficult to study and require specific elements and procedures to be seen, tracked, and experimented upon.  Lazy and/or bought out researchers need not apply.  

Many, many more are succumbing due to the complications of Lyme as well as numerous other tick-borne illnesses but are not being tracked.  Some pathogens like B. miyamotoi aren’t even reportable diseases yet!

Similarly to COVID-19, autopsies are desperately needed to shed light on infectiousness & destruction caused by pathogens.

For more:  https://madisonarealymesupportgroup.com/2018/04/13/chronic-lyme-post-mortem-study-needed-to-end-the-lyme-wars/

https://madisonarealymesupportgroup.com/2018/07/09/with-unexpected-death-autopsies-should-look-for-lyme-carditis/

Regarding COVID-19:  https://madisonarealymesupportgroup.com/2020/05/11/what-are-sars-covid2-patients-really-dying-from/  In short, those dying from SARS COVID2 are not dying from interstitial pneumonia (which is why ventilators aren’t working and often cause more harm than good) but rather from DIC (disseminated intravascular coagulation) – a medical term for blood clotting causing a lack of oxygen. This was discovered from autopsies.

Imagine what we could find from autopsies from patients who have Lyme/MSIDS!
 

Category:

Activism, Lyme

Lyme & Tick-born Disease Symptom Checker

https://igenex.com/tick-talk/symptom-checker  (Go here for Symptom Checker)

Lyme and Tick-borne Disease Symptom Checker

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If you’ve been sick and aren’t getting better, use this IGeneX symptom checker to determine your likelihood of having Lyme disease or other associated tick-borne illnesses.

The Lyme and Tick-Borne Disease Symptom Checker is for informational purposes only and should not be considered, or used as a substitute for, medical advice, diagnosis, or treatment. By using this website and the Symptom Checker, you agree that this website and the Symptom Checker is not intended to and does not replace the advice of your own physician or other medical professional and that this website does not constitute the practice of any medical or other professional healthcare advice, diagnosis, or treatment. You are solely responsible for your own health care decisions regarding the use of this website and the Lyme and Tick-Borne Disease Symptom Checker and your use is entirely at your own risk. You should consult a medical professional for all questions or concerns you may have relating to your health. If this is an emergency in the United States, call 911.

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**Comment**

A very helpful online quiz. You can also read about common symptoms for Lyme disease, Babesia, Tick-borne Relapsing Fever, Bartonella, Ehrlichiosis, Anaplasmosis, and Rickettsiosis.

My only caution is that there are other symptoms omitted from this quiz. My own case is a perfect example.

All my initial symptoms were gynecological and I believe strongly were my first signs of Lyme/MSIDS infection, obtained from my husband who is also infected. You can read about that here: https://madisonarealymesupportgroup.com/2017/02/24/pcos-lyme-my-story/

Those infected congenitally will also find fault with this quiz which is why you need to see an experienced Lyme literate physician.

It is quite common to have an initial 90 minute appointment with these ILADS trained doctors as you fill out medical history forms going back to infancy. The doctor then discusses these with you to further ascertain the potential of early infection (perhaps in utero). Often, many health issues can be traced back to infancy if you were infected congenitally. For more: https://madisonarealymesupportgroup.com/2018/06/19/33-years-of-documentation-of-maternal-child-transmission-of-lyme-disease-and-congenital-lyme-borreliosis-a-review/

https://madisonarealymesupportgroup.com/2018/11/11/gestational-lyme-other-tick-borne-diseases-dr-jones/

While sexual transmission of Lyme/MSIDS has not been admitted to by ‘authorities,’ congenital transmission recently has been:  https://madisonarealymesupportgroup.com/2020/02/01/cdc-website-updated-today-possibility-of-mother-to-fetus-transmission-of-lyme-disease/

It is also quite common for ‘authorities’ to first admit something is ‘rare’ only to have to admit later it’s more common than first thought.  This is their modus operandi.  For years I’ve watched them state Lyme doesn’t exist in certain geographical locations because the ticks that transmit it aren’t there, only to have to update that information later on. This has happened repeatedly.  But before the information gets updated, infected patients are told “it’s all in their heads,” left to rot, and are denied treatment.  These patients only go on to worsen, making their cases far more difficult to treat:  https://madisonarealymesupportgroup.com/2017/09/21/its-all-in-your-head-until-finally-a-lyme-diagnosis/

Rather than admit a patient could be infected, despite prior findings in the literature or of ticks in certain locations, patients are handed from doctor to doctor like a football, and are more likely to be given an anti-depressant than life-saving antimicrobials.

This must end.  Using entomology maps to diagnose has hurt patients.  While maps are interesting, they should never keep patients from getting diagnosed.

For the Horowitz symptom questionnaire, which has been validated:  https://madisonarealymesupportgroup.com/wp-content/uploads/2016/01/symptomlist.pdf  Print, fill out, and tally up the points.  

Just remember that while these checklists are helpful, and in fact probably far better than current testing, they are not perfect.  Lyme/MSIDS is wiley – with waxing and waning symptoms. Your best hope of correct diagnosis and treatment remain in the hands of an experienced Lyme literate doctor, although nothing replaces learning all you can to be a helpful partner in your own healing.

 

Category:

Anaplasmosis, Babesia, Bartonella, Ehrlichiosis, Lyme, Tickborne Relapsing Fever

Virtual Hackathon: Educate & Elevate For Tick-Borne Illness Team Pitches & Awards

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Virtual Hackathon: Educate & Elevate For Tick-Borne Illness Team Pitches & Awards

Innovative teams are competing for grant funding to shift existing paradigms in Tick-Borne Illness.

The goal of this virtual program is to create projects that educate the public and institutions that hold the keys to meaningful change. By taking on this challenge, they will contribute to easing senseless suffering that is caused by a simple tick bite.

Speakers, entertainment, and a chance to make a difference.

When: Saturday October 24, 2020

Time: 1pm ET

Register to receive the Zoom link:

https://lnkd.in/dW9pt6C

Category:

Activism, Lyme

Senator Collins Announces $25 Million Initiative to Fight Lyme Disease

https://www.collins.senate.gov/newsroom/senator-collins’-announces-25-million-initiative-fight-lyme-disease

Senator Collins Announces $25 Million Initiative to Fight Lyme Disease

Last year, Senator Collins authored a new law that provides $150 million over five years to fight tick-borne illnesses.
Press Releases
Posted Tue, 10/13/2020

Washington, D.C.— U.S. Senator Susan Collins, a member of the Health Committee, announced the launch of LymeX, a new $25 million effort to fight tick-borne diseases.  LymeX is the largest public-private partnership to combat Lyme disease in history and will provide awards to improve data about tick-borne diseases; raise awareness; and accelerate the discovery of diagnostic tools, testing, and implementation.  Senator Collins, the author of the Kay Hagan Tick Act that became law last year, received a call today from Department of Health and Human Services (HHS) Deputy Secretary Eric Hargan, who shared this positive development.

LymeX is being led by HHS and the Steven & Alexandra Cohen Foundation and will be housed within the HHS Office of the Assistant Secretary for Health, the coordinating agency developing the National Strategy to fight tick-borne diseases that was required by Senator Collins’ Tick Act.  LymeX augments the Tick Act law and reinforces the federal focus on this priority.

“This partnership is an exciting and promising development in our fight against tick-borne illnesses such as Lyme disease that affect hundreds of thousands of Americans every year.  As the largest public-private partnership to combat Lyme disease in history, this initiative builds on the bipartisan TICK Act I authored and demonstrates that the federal government is focused on eradicating this public health threat,” said Senator Collins.  “I remain committed to slowing the spread of these devastating diseases, and I will continue my efforts to protect Mainers’ health.”

Specifically, LymeX will advance tick-borne disease innovation by incentivizing the development of next-generation diagnostics through a series of multi-million-dollar grand prize challenges. The first LymeX diagnostics prize will launch in 2021. These prizes will be open to U.S. universities, non-profit organizations, private-sector companies, and domestic organizations to improve diagnostics at all stages of Lyme disease.

The initiative will also engage stakeholders to facilitate patient-centered innovations to address tick-borne diseases and increase education to raise awareness about risk and prevention.

The incidence of Lyme and other tick-borne diseases has exploded over the past 15 years.  In 2003, Lyme disease infected around 30,000 Americans.  The latest estimates show there are nearly half a million Americans suffering from Lyme.  In Maine, there were a record 2,167 newly reported cases of Lyme disease last year, nearly triple the number of cases in 2010.  Other tick-borne diseases are also on the rise – in Maine, for example, Anaplasmosis and Babesiosis have increased several-fold in this same period.

LymeX will complement the three-pronged approach created by Senator Collins’ Tick Act law, which:

  1. Requires HHS to develop a National Strategy.  This will help expand research, improve testing and treatment, and coordinate common efforts across federal agencies including with DOD, USDA, EPA, the VA, and the Departments of Interior and Homeland Security
  2. Reauthorizes Regional Centers of Excellence in Vector-Borne Disease for five years at $10 million per year.  These Centers have led the scientific response against tick-borne diseases, which now make up 75 percent of vector-borne diseases in the U.S.
  3. Authorizes CDC Grants at $20 million per year for State Health Departments to improve data collection and analysis, support early detection and diagnosis, improve treatment, and raise awareness.  These awards will help states build a public health infrastructure for Lyme and other tick and vector-borne diseases and amplify their initiatives through public-private partnerships.

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**Comment**

Involving the HHS will almost certainly doom this project.  We should learn from history.  The anti-patient bias is clear and has remained unchanged:  https://madisonarealymesupportgroup.com/2018/02/11/anti-patient-bias-embedded-in-tickborne-disease-working-group-and-its-subcommittees/

https://madisonarealymesupportgroup.com/2020/03/11/cdcs-recommendations-for-lyme-epitomize-institutional-bias/

https://madisonarealymesupportgroup.com/2020/04/19/letter-to-chronic-lyme-denialists-from-a-microbiologist/

https://madisonarealymesupportgroup.com/2020/05/11/persistent-lyme-a-sticking-point-for-tbd-working-group/

Excerpt:

Remarks made after the vote made it clear that the abstainers felt they had defeated the measure, because “yes” votes didn’t comprise a majority of panel members. But, oops, guess what? Abstentions don’t count one way or the other. So, the recommendation passed, 5-3.

As that reality sank in, pandemonium broke out. Panelist Scott Commins stoutly announced that he wanted to change his abstaining vote to “no.” He was told that Robert’s Rules of Order don’t allow you to change your vote after the fact.

Things then got very bizarre very fast, with many people talking at once. Some wanted to vote on the original question again. Others didn’t. Some wanted to re-open discussion, others didn’t. It was confusing to the listener at home.

However, the five abstainers sure gave the impression they had been trying to game the system—to gain a “no” vote without having to publicly own up to it. When that ploy didn’t work, they scrambled to recoup their original objective— to deep-six the proposal regarding persistent Lyme disease.

It is truly time for a CDC/NIH/IDSA/HHS walkout movement. Our public health ‘authorities’ have vested interests which interfere with doing what is right for patients. We’ve tried working with them for over 40 years.  How many times are you going to get behind a horse that kicks you?

https://madisonarealymesupportgroup.com/2020/09/01/it-is-time-to-reboot-public-health-time-for-a-cdc-niaid-fda-walk-away-movement/  Although Weiler is discussing how ‘authorities’ have handled COVID, the exact same things could be said about how they’ve handled Lyme/MSIDS. 

Public ‘authorities’ should not be allowed to own patents on things that interfere with their ability to make public health decisions.

For more: ConflictReport

Category:

Activism, Lyme, Testing, Ticks

More Evidence of Lyme Organism Persistence. Peptidoglycan is only Produced by Metabolically-Active Spirochetes.

https://www.frontiersin.org/articles/10.3389/fcimb.2020.567252/full

OPINION ARTICLE

Front. Cell. Infect. Microbiol., 07 October 2020 | https://doi.org/10.3389/fcimb.2020.567252

Mechanisms of Dysregulated Antibody Response in Lyme Disease

Timothy J. Sellati1* and Dana M. Barberio2
  • 1Global Lyme Alliance, Inc., Stamford, CT, United States
  • 2Edge Bioscience Communications, Sherborn, MA, United States

Introduction

Lyme disease (LD), caused by the spirochetal bacterium Borrelia burgdorferi, is transmitted by the black-legged tick Ixodes scapularis (Hu, 2016). LD is the fastest growing global tick-borne disease and annually affects >300,000 people in the U.S. alone (Steere et al., 2016). The economic impact is a staggering $1.3 billion dollars per year (Adrion et al., 2015). LD can cause long-term, debilitating symptoms, including arthritis, carditis, and neurological complications (Hu, 2016; Steere et al., 2016). A longstanding question is why antibodies produced during primary infection are not able to completely clear spirochetes or confer protective immunity (Barbour et al., 2008). Antibody titers can remain for years in some LD patients while in others, they wane over time or never develop at all (Kalish et al., 2001). Herein, we describe animal studies that reveal mechanisms behind dysregulated development of adaptive immunity and provide insights that may be relevant to human immunity to B. burgdorferi infection.

Role of Lymphocytes and Antibodies in Lyme Disease Pathogenesis

Antibodies produced through B and T cell interactions either within or outside germinal centers are termed T cell-dependent (TD) whereas those produced without the aid of T cells are T cell-independent (TI). One mechanism whereby B. burgdorferi attempt to evade adaptive immunity is by continuously changing the sequence of a unique surface protein called variable major protein-like sequence (VlsE) (Norris, 2015). Such sequence variation generates a large repertoire of antigenically-distinct spirochetes that become unrecognizable to the antibodies that are mounted against a previous version of this protein. This may allow B. burgdorferi to persist for months or years if not effectively cleared through innate immune response and/or early diagnosis and treatment with antibiotics. Another defensive strategy relies on switching which immunogenic proteins are surface expressed [e.g., Outer Surface Protein A (OspA) and OspC], as spirochetes transit from one environment to another. OspA and OspC are predominately expressed when spirochetes are in the tick vs. the mammalian host, respectively. Notably, whole-proteome microarray analysis revealed that while relatively few B. burgdorferi open reading frames (~15%) encode immunogens, those that do elicit the same detectable antibodies in naturally infected humans and wild white-footed mice (Peromyscus leucopus), the predominant maintenance reservoir for B. burgdorferi (Barbour et al., 2008). Interestingly, a spectrum of disease severity has been observed in different mouse strains, reflecting their unique genetic composition, which controls the magnitude of humoral responses during B. burgdorferi infection (Weis et al., 1999).

Despite strong antibody responses in animals experimentally-infected with B. burgdorferi and in many LD patients, this does not translate to robust disease-resolving and long-term immunity (Barthold and Bockenstedt, 1993; Aguero-Rosenfeld et al., 1996). In order to explore the mechanisms through which B. burgdorferi infection impacts the immune system and gain an understanding of the role of B and T cells in LD pathogenesis, researchers have conducted studies in mice lacking either or both of these lymphocyte populations.

Pathologies associated with B. burgdorferi infection of mice often spontaneously resolve, although animals may never completely clear spirochetes. In contrast, after infection with B. burgdorferi, severe combined immunodeficient (SCID) and recombination activating gene (RAG)-deficient mice, both of which lack B and T cells, developed severe, persistent arthritis that remained unresolved (Hastey et al., 2012). While B cells regulate disease progression and resolution in wild-type mice (McKisic and Barthold, 2000), adoptive transfer of CD4+ T cells into RAG-deficient mice prior to B. burgdorferi infection increased arthritis and carditis severity (unless B cells were co-transferred), and CD8+ T cell transfer increased arthritis severity (McKisic et al., 2000). Conversely, adoptive transfer of serum from immunocompetent B. burgdorferi-infected mice into SCID mice ameliorated both arthritis and carditis (Barthold et al., 1997; McKisic and Barthold, 2000). Transfer of immune serum into naive recipient mice either prior to or at the time of inoculation also prevented B. burgdorferi infection (Barthold et al., 1997). Immunization of mice with late-stage LD patient sera that demonstrated strong antibody reactivity to several B. burgdorferi proteins, including OspA and B, provided partial protection against B. burgdorferi challenge (Fikrig et al., 1994). These findings reveal that humoral immune responses generated in experimentally-infected mice and LD patients play an important role in the resolution of some of the most commonly reported clinical manifestations (arthritis and carditis), which are driven principally by activation of inflammatory T cells and release of potent inflammatory mediators.

Researchers found unusually strong and persistent TD and TI IgM antibody production in lymph nodes during early infection and in bone marrow later on in the course of murine infection (Hastey et al., 2012; Richards et al., 2015). IgG-secreting plasma cells, on the other hand, accumulate slowly in the bone marrow. Only about 50% of the IgG response is clearly TD and, coupled with IgM, is thought to contribute to the reduction but not elimination of B. burgdorferi from tissues (Hodzic et al., 2003). This TD repertoire of IgG contributes minimally to long-term antibody-mediated immunity, unlike the typical humoral response to bacterial pathogens (Hastey et al., 2012; Tracy and Baumgarth, 2017).

Mechanism(s) of Immune Dysfunction in Lyme Disease

To dissect the mechanisms behind this dysregulated response, Hastey et al. (2012) elucidated distinct stages of altered immune response using a mouse model of LD. In the first phase of infection, B cells accumulated in lymph nodes and induced antibodies in a TI manner and in the absence of germinal centers. In other infectious diseases, such as mumps and HIV, swollen lymph nodes are a frequent early symptom of infection. Normally, the areas in which T and B cells are found in lymph nodes are well-defined. However, in B. burgdorferi-infected mice, this typical architecture was disrupted, with loss of organized B cell follicles and T cell zones (Tunev et al., 2011). Deterioration of B cell follicles, between days 5 and 10 post-infection occurred together with the presence of spirochetes within the lymph nodes (Hastey et al., 2014). In addition, B cells began to accumulate in large numbers, reaching over 70% in some instances and disrupting normal T/B cell ratios (Hastey et al., 2012).

In the second phase, roughly 2–3 weeks later, short-lived germinal centers developed in lymph nodes. These germinal centers gave rise to relatively few antibody-producing plasma cells within bone marrow, leading to a third phase in which plasma cells only slowly accumulated. Lymph node germinal centers disappeared about 1 month after infection, despite the continued presence of bacteria at these sites. Curiously, B cell accumulation occurred after, not before, destructive changes in lymph node morphology. This suggests that the Borrelia infection, not B cell accumulation, somehow drives lymphoid tissue atrophy (Hastey et al., 2014).

So, while B. burgdorferi infection prompts strong serum antibody levels, and titers increase over the course of infection, the antibody response is ultimately ineffective in completely eradicating spirochetes and/or establishing long-term immunity (Tunev et al., 2011; Hastey et al., 2012; Elsner et al., 2015). B. burgdorferi benefits from this maladaptive immune response. This premise is corroborated by a study of antibiotic-treated human LD patients, which included patients who had persistent symptomatology and those who had returned to health within 6 months after diagnosis and treatment (Blum et al., 2018). The researchers focused on plasmablasts, activated B cells that mature into plasma cells within germinal centers. They found that patients who ultimately recovered their health, as compared to those with persistent symptoms, had significantly more plasmablasts during early infection. The researchers determined this by comparing the percentage of plasmablasts as a total of all B cells at the initial clinic visit, during early infection (even before beginning Doxycycline therapy). In addition, patients who ultimately returned to health had significantly higher titers of antibodies to a diverse array of B. burgdorferi proteins (Blum et al., 2018). Taken together, this is evidence that B. burgdorferi infection redirects the adaptive immune system away from a long-term protective antibody response and toward a less efficacious, rapid and strong, though short-lived antibody response (Richards et al., 2015).

Interestingly, Hastey et al. (2014) also provided evidence that Borrelia infection itself may have broader immunosuppressive effects. They tested this by using influenza virus vaccination as a tool to study TD antibody responses. Two groups of mice were influenza-vaccinated, with one group being infected with B. burgdorferi while the other was not. For the first 3 weeks, both groups of mice produced similar amounts of influenza-specific IgG. However, by 4 weeks, and until the study ended at 26 weeks, the B. burgdorferi-infected animals made significantly less influenza-specific IgG than the uninfected mice. By 9 weeks post-infection, there were far fewer influenza-specific antibody-secreting cells in the bone marrow of the Borrelia-infected animals compared to uninfected influenza-vaccinated mice (Elsner et al., 2015). This finding engenders an intriguing question about whether LD might negatively impact vaccination efficacy.

Implications for Diagnostics

There is more to be done in exploring these mechanisms of dysregulated antibody response in LD patients and there are clear implications for development of improved diagnostic tests. Physicians often follow the CDC-recommended two-tiered testing algorithm to detect B. burgdorferi-specific antibodies in patients suspected of having LD (Marques, 2015). The first-tier test is an enzyme-linked immunosorbent assay or ELISA, and if results are positive or borderline, a confirmatory second-tier test is done; a Western immunoblot analysis to detect IgM and IgG antibodies that are specific for B. burgdorferi proteins. In theory, this test determines if a B. burgdorferi infection is active (Marques, 2015). However, this CDC-recommended serodiagnosis may be misleading. In a small study of 79 patients who no longer had symptoms, but had a history of LD with and without arthritis 10–20 years ago, researchers examined antibody titers using the CDC two-tiered test (Kalish et al., 2001). They found that 10 individuals (13%) currently had IgM responses (reflecting initial exposure) to B. burgdorferi and 34 (43%) had IgG reactivity (reflecting longer term exposure) to B. burgdorferi. Antibody titers were even higher for patients who had LD with arthritis (but were currently asymptomatic), as six of 39 (15%) currently had IgM responses and 24 of 39 (62%) had IgG reactivity. This trend also is seen in infected mice, where IgM antibody levels do not wane but stay relatively high along with the increased IgG response (Hastey et al., 2012).

Theoretically, it would be expected that all recovered patients would lack evidence of IgM and many or all would continue to have circulating IgG. The presence of IgM in 13% of patients would be cause for confusion for physicians as the presence of this class of antibody typically wanes with clearance of the pathogen and recovery from infection. Larger studies need to be done to confirm and to explain the reasons for the continued presence of IgM. Another consideration is that high antibody levels, as discussed, may only offer transient protection, with alterations in germinal center architecture and defective production of long-lived plasma cells and memory cells leading to poor immunoprotection in the long-term (Hastey et al., 2012; Elsner et al., 2015).

Future efforts in Lyme disease diagnosis need to focus on distinguishing between active and inactive infection and improving sensitivity in detecting early disease while maintaining high specificity. Diagnosis would be greatly enhanced with the development and broad adoption of point-of-care testing, and simplified diagnosis. Addition of antigen targets expressed very early in LD (e.g., VlsE1 and pepC10) to current antibody-based diagnostic testing procedures have enhanced performance of the diagnostic assays (Porwancher et al., 2011; Marques, 2015). Additionally, direct detection of B. burgdorferi antigens or nucleic acid rather than antibody testing may eventually be possible with the development of advanced technologies (Branda et al., 2018). Not only might direct detection of spirochetal components be indicative of active infection, but the presence of nucleic acids and certain antigens coincides with the earliest stage of infection, when B. burgdorferi-specific antibodies have yet to be produced. Examples include B. burgdorferi DNA detected using PCR (Mosel et al., 2019) and antigens such as OspC (Ohnishi et al., 2001) or peptidoglycan (Jutras et al., 2019). OspC is expressed on spirochetes as they transit from tick to mammalian host (Ohnishi et al., 2001) while peptidoglycan has been shown to persist in patients long after antibiotic treatment has ceased and patients are theoretically cured of active infection (Jutras et al., 2019).

The latter observation strongly supports the notion of persistence of B. burgdorferi after antibiotic treatment as peptidoglycan is only produced by metabolically-active spirochetes.

Discussion

There has been significant progress in deciphering the mechanistic foundation of B. burgdorferi’s impact on the adaptive immune response, specifically the B cell response and antibody production. While B. burgdorferi initially elicits a strong immune response, the end result is a failure by the immune system to clear the infection. This could set the stage for B. burgdorferi’s persistence (Tracy and Baumgarth, 2017), which may underlie chronic symptoms such as arthritis, carditis, and skin and neurological complications. The many animal studies conducted to date reveal that B. burgdorferi relies upon multiple strategies to evade and disrupt the normal functioning of the immune system. The end results are inhibition of effective B cell responses, disruption of the formation of stable germinal centers, and dampening the production of optimally protective antibodies and establishment of long-term memory cell populations. Importantly, many of these same evasion strategies appear to be employed by B. burgdorferi in LD patients, particularly those suffering from persistent or chronic disease. These intriguing observations provide an excellent foundation and springboard for further animal and human studies, with the goal of increased understanding of LD pathogenesis, better diagnostics, and ultimately novel and more effective therapeutic options for long-suffering patients.

Author Contributions

DB and TS contributed to the writing of this manuscript. All authors contributed to the article and approved the submitted version.

Funding: Publication of this manuscript was financially supported by Global Lyme Alliance, Inc.

Conflict of Interest

DB is the owner of Edge Bioscience Communications, a freelance, contract scientific/medical writing and consulting company.

The remaining author declares that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

We would like to acknowledge Drs. Mayla Hsu and Nicole Baumgarth for thoughtful review of this manuscript prior to its submission for review.

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Citation: Sellati TJ and Barberio DM (2020) Mechanisms of Dysregulated Antibody Response in Lyme Disease. Front. Cell. Infect. Microbiol. 10:567252. doi: 10.3389/fcimb.2020.567252

Received: 29 May 2020; Accepted: 02 September 2020;
Published: 07 October 2020.

Edited by:  John M. Leong, Tufts University School of Medicine, United States

Reviewed by:  Rachel Maurie Gerstein, University of Massachusetts Medical School, United States, Ronald Mark Wooten, University of Toledo, United States

Copyright © 2020 Sellati and Barberio. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Timothy J. Sellati, timothy.sellati@globallymealliance.org

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