Integrative Approach and Patient Perspective in Chronic Lyme Disease: A Case Report


By Gisell García, MD,¹ and Mitzu Fajardo, MD, MSc2*

Abstract
A case of a 57-year-old woman who has a five-year history of previously treated chronic Lyme disease (CLD-PT) is described. Her condition was characterized by severe chronic fatigue, blurred vision, difficulty thinking, depression, and severe joint pains that markedly impaired her quality of life. Blood serology indicated IgM antibodies to Borrelia burgdorferi and IgG antibodies for Babesia microtii. Since 2015 the patient was treated with several drug therapy schemes with no clinical improvement. After receiving an integrative approach at Sanoviv Medical Institute with multidisciplinary specialists, followed by an intensive treatment protocol that focused on resetting her redox homeostasis with oxidation, whole-body hyperthermia (WBH), and antioxidation treatments, the patient demonstrated noticeable clinical improvement. The treatment of CLD patients is very challenging. However, a careful and detailed examination by multidisciplinary specialists followed by an intensive treatment offers a thorough approach to reducing the burden of illness posed by CLD.


Introduction

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Lyme disease (LD) is a multisystem illness caused by infection of several members of the Borrelia burgdorferi sensu lato complex. At least twenty genospecies have been described, whereas three of them (B. burgdorferi, B. garinii, and B. afzelii) are well-recognized human pathogens; this heterogeneity, along with coinfections, is presumed to be responsible for the extensive clinical and temporal spectrum of LD.1,2 It is estimated that up to one-third of patients with LD develop symptoms of chronicity for more than six months; this condition is referred to as chronic Lyme disease (CLD).3

The Centers for Disease Control and Prevention (CDC) estimates that 300,000 people are diagnosed with LD annually in the United States, and its incidence trend is continuously increasing.4 However, very little is known about CLD epidemiology and its burden of disease due to underdiagnosed or misdiagnosed cases. LD diagnosis is a complex challenge per se. Within the CDC meeting criteria based on the two-tier test, it has been reported that more than half of patients are underdiagnosed, mainly due to microbial burden of coinfections.5 Though serology tests are indispensable for diagnosing LD, clinical status must be the guideline for CLD diagnosis, even if the patient is unaware of erythema migrans lesions or if they presented months or years earlier. Commonly, patients with CLD suffer from unspecific symptomatology for several years. Chronic fatigue and neurologic disturbances are the chief complaints in CLD patients.6 These mild but persistent symptoms are due to several organic imbalances impacting various body systems, ranging from the immune system to the nervous system.7

The proposed pathophysiological mechanism of action of B. burgdorferi relies on mitochondrial dysfunction. Borrelial infection disrupts intracellular calcium homeostasis and increases pro-inflammatory cytokines, which promotes mitochondrial oxidative stress. B. burgdorferi also depletes intracellular cysteine, an essential amino acid for glutathione synthesis, one of the most potent antioxidants that scavenges excessive reactive oxygen and nitrogen species.8

Besides the mitochondrial dysfunction, B. burgdorferi has a significant ability to avoid the immune system. CLD patients in particular, exhibit an imbalance of pro-inflammatory cytokines, mainly interferon-gamma and interleukin-4.9 Also, B. burgdorferi disrupts dendritic cell migration and stimulates neutrophil chemotaxis; which promotes impairment of host defense mechanisms and induces symptomatology chronicity.10,11

Currently, the only approved treatment for LD is antibiotics,12 despite B. burgdorferi infection affecting several systems. However, “unorthodox” therapeutic options exist to treat CLD, such as whole-body hyperthermia, hyperbaric oxygen therapy, and a combination of efficacious natural supplements.13

Here, we discuss an integrative treatment program for CLD patients that results in almost 95% clinical improvement, according to our preliminary analysis and anecdotal experience. This case report aims to present a personalized treatment approach for CLD patients to restore redox status and well-being recovery by combining multidisciplinary therapeutic expertise.


Case Presentation

A 57-year-old woman presented with a five-year history of Chronic Lyme Disease-Previously Treated (CLD-PT). Her chief complaints were chronic fatigue, blurry vision, difficulty thinking, forgetfulness, irritability, depression, joint pain, stiffness of the neck, and numbness of upper extremities. She referred to living in what is considered a Lyme-endemic area; and in December 2016, her serology testing resulted positive for B. burgdorferi and B. microtii. After lab testing confirmed LD, she underwent several drug and natural supplement therapies for almost four years with no clinical improvement. (See Figure 1)

Suspension of her PhD degree program due to disability forced her to seek alternative therapeutic options. She completed the Chronic Infections Program at Sanoviv Medical Institute in February 2018, where she received several health consultations from a physician, mind-body therapist, biological dentist, nutritionist, psychologist, chiropractor, and fitness professional. After discussing the root causes of the patient’s health problems and recommendations from every therapist, the patient underwent a personalized treatment protocol to regain her redox status. She received oxidative treatments with hyperbaric therapy, UV light and ozone autohemotherapy, intravenous artesunate, and high doses of intravenous vitamin C. This course was then followed by whole-body hyperthermia (WBH), achieving a core temperature of 41.7 °C (107.06 °F), intravenous antibiotics (based on the patient’s serology tests) and alpha-lipoic acid, with glutathione for antioxidant support. She completed the program successfully with noticeable clinical improvement. Interestingly, the night after receiving WBH, she experienced an outstanding mental health improvement that, according to the patient, boosted her to start writing her PhD thesis.

Two years later, the patient experienced another tick bite on her left leg. Immediately after, she noticed the symptoms had returned and enrolled again in the Chronic Infections Program at Sanoviv Medical Institute (January 2020). At the end of her second visit, she recognized the psychology and mind-body sessions as the most impactful therapies to empower her return to wellness. She is currently writing a book chapter recounting her Lyme disease experience.


Discussion

The redox status in CLD patients is commonly disrupted. The first step in therapy is to boost the immune system so that it can recognize B. burgdorferi and other coinfections. The next step is to recover oxidative and antioxidative homeostasis.8 In the Chronic Infections Program at Sanoviv, the pursuit of redox balance is achieved by promoting an oxidative state, followed by WBH, and ending up with antioxidation support. (See Figure 2).


Oxidation Status

Hyperbaric oxygen therapy increases the generation of oxygen free-radicals and promotes the oxygen-dependent peroxidase system. This results in inhibition of bacterial metabolic functions and enhancement of leucocyte activation against tick-borne infections.14,15

Ozone and ultraviolet blood irradiation therapies increase oxygen, glucose, and ATP delivery within tissues; upregulate antioxidant enzyme expression, and trigger a neurohumoral response. It has been suggested that ozone can reverse chronic oxidative stress due to aging, chronic infections, and degenerative processes.16 The ozonation process generates one mole of hydrogen peroxide (H2O2) and two moles of lipid oxidation products. These oxidation products result in transitory oxidative stress that triggers biological activity without toxicity, as the induction of the heme-oxygenase-1, a protective enzyme that catabolizes free heme, prevents apoptosis induction due to pro-inflammatory agonists.17,18 Ozone also induces activation of bone marrow metalloproteinases, which promotes staminal cell detachment and attracts them to sites where a previous injury has occurred.19 In CLD patients, infections of borrelial persistent forms usually persist. These forms consist of bacterial biofilm organization that allows the spirochaete evasion of antibiotics and host immune system.20,21 Ozone is directly germicidal and can cut through this bacterial biofilm.22,23

Continuing with the oxidation state promotion, after hyperbaric and ozone therapy, high doses of intravenous vitamin C (HDIVC) were administered to the patient. Vitamin C at high doses acts as a prodrug for the production of H2O2 in the extracellular space. H2O2 is a bacteriostatic agent, and its generation across the interstitial fluid is only achieved by intravenous administration of vitamin C.24,25 In this particular case, we used 25 grams of IV vitamin C.

After HDIVC, our patient received artesunate, a water-soluble semi-synthetic derivate from artemisinin.26 Artesunate is of fundamental importance in patients with CLD and coinfection with B. microtii, as occurred in our patient. Artesunate disturbs the mitochondrial membrane of the parasite, which generates reactive oxygen species (ROS) thus enhancing the oxidation state and carbon-centered radical molecules that modify central regulatory proteins of the parasite.27 Furthermore, artesunate has demonstrated an improvement in short-term memory for CLD patients.28


Whole-Body Hyperthermia

Once achieving this intensive oxidation state, our patient received WBH along with intravenous antibiotics. WBH, as part of this multimodal approach, aims to eradicate borrelial infection and further coinfections. The body temperature is raised to about 42°C in WBH and this induction of hyperthermia is beneficial for our patient but deleterious for the pathogen. The mechanism of the latter works by disturbing the architecture of the borrelial membrane, altering its fluidity and organization, making the borrelial infection less severe. LaRocca et al. demonstrated that bactericidal activity against B. burgdorferi increases with temperature elevation.29

The numerous beneficial effects of WBH against borrelial and coinfections begin with an improvement of antibiotics-tissue-perfusion due to systemic vasodilatation. WBH also directly modulates the immune system by increasing mobility, proliferation, enzymatic activity, and phagocytic and bactericidal properties of leucocytes, leading to eradication of borrelial infection and other coinfections. 30–32

Other important benefits of WBH are its analgesic and antidepressant effects. The analgesic effect of WBH comes from its elimination of inflammatory factors that stimulate nerve endings, which permits the relaxation of skeletal muscles and reduction of tendon and soft tissue tension.32 The antidepressant-like response promoted by WBH occurs by activation of temperature-sensitive ion channels in the skin. That signal is then directed to brainstem serotonergic neurons, producing a sense of relaxation and wellbeing in response to warm temperatures.33,34 The stimulation of warm-sensitive thermosensory pathways projecting from the skin to cortical and subcortical regions of the brain may affect neural activity relevant to mood improvement.35


Antioxidation Status

Following WBH sessions, alpha-lipoic acid (ALA) and glutathione were administered to promote an antioxidative state. ALA is a cofactor in the mitochondrial enzyme system. In vivo experiments demonstrate that ALA plays a fundamental role in preventing inflammatory response in the liver and antioxidant support against bacterial endotoxins.36 Glutathione is the most abundant cellular antioxidant and serves as a sulfhydryl buffer. Both ALA and glutathione have hepatoprotective actions associated with the amelioration of mitochondrial oxidative stress and prevention of the induction of genes that trigger hepatic inflammation. Also, glutathione can react with H2O2 and has detoxifying properties.36,37

After utilizing the combined therapeutic approach of oxidation, WBH, and antioxidation; the oxidative homeostasis was achieved, and the patient’s immune system was strengthened to recognize and eliminate tick-borne pathogens.


Patient Perspective

According to our patient, besides her medical treatment, psychology sessions were vital in her healing process. Her personality is normally very enthusiastic and proactive. When LD symptoms arose, frustration, anger, and disappointment appeared as well. Psychology sessions focused on emotion recognition and renewing her life purpose with psychotherapy of forgiveness, mindfulness, brain spotting, and neuro-emotional techniques. CLD patients have a range of circumstances that can increase the severity of the disease and are not usually considered or explored. Hence, it is necessary to identify them and be treated comprehensively.

Conclusion Tick-borne diseases, mainly CLD, are very challenging to diagnose and treat. We firmly suggest that CLD be addressed with an integrative and personalized approach following multidisciplinary therapeutic expertise. The redox balance establishment, with oxidation, WBH, and antioxidation, is focused on tick-borne infection eradication by strengthening the immune system. Moreover, the patient perspective is crucial for the healing process because the relationship between mind and body of CLD patients sets the path for healing and wellness.

¹Chronic Infections Program Coordinator, Sanoviv Medical Institute, Baja California, Mexico.
²Research Department, Sanoviv Medical Institute, Baja California, Mexico.
*Correspondence to M. Fajardo, Mitzuko.Fajardo@sanoviv.com


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