Gastrodia elata Blume (tianma) mobilizes neuro-protective capacities in Parkinsons.

Tianma (Gastrodia elata Blume) is a traditional Chinese medicine (TCM) often used for the treatment of headache, convulsions, hypertension and neurodegenerative diseases. Tianma also modulates the cleavage of the amyloid precursor protein App and cognitive functions in mice. The neuronal actions of tianma thus led us to investigate its specific effects on neuronal signalling. Accordingly, this pilot study was designed to examine the effects of tianma on the proteome metabolism in differentiated mouse neuronal N2a cells using an iTRAQ (isobaric tags for relative and absolute quantitation)-based proteomics research approach. We identified 2178 proteins, out of which 74 were found to be altered upon tianma treatment in differentiated mouse neuronal N2a cells. Based on the observed data obtained, we hypothesize that tianma could promote neuro-regenerative processes by inhibiting stress-related proteins and mobilizing neuroprotective genes such as Nxn, Dbnl, Mobkl3, Clic4, Mki67 and Bax with various regenerative modalities and capacities related to neuro-synaptic plasticity.

Discussion

Orchids and their derivatives have been used for many years in clinical studies to treat various neuronal disorders and demonstrated a powerful effect [4,6]. In our previous study, we could demonstrate the effect of tianma on cognitive functions in mice [12]. Here, we provide an additional interesting insight into the molecular and cellular mechanisms of herbal medicine by disclosing the effect of tianma on the full neuronal proteome changes upon stimulation of differentiated mouse neuronal N2a cells. In the following sections we briefly discuss the identified proteins that were found to be altered upon neuronal tianma stimulation and we hypothesize potential applications of tianma that may emerge from our data obtained:

Increased neuro-protective protein levels in differentiated neuronal N2a cells upon tianma activation

Nxn: Nucleoredoxin is a novel thioredoxin family member that is involved in cell growth and differentiation where it sustains Wnt/β-catenin signalling by retaining a pool of inactive dishevelled protein [27-29]. Its activation by tianma allows the herb to influence pivotal neuronal differentiation pathways. In fact, we observed slightly enhanced neurite extension formation after adding tianma to the neuronal cells (Figure 2C).

Dbnl: Similarly, tianma partakes in cell differentiation processes by mobilizing Dbnl [30]. Dbnl deficiency leads to tissue and behavioral abnormalities and impaired vesicle transport [31]. It is a cytoskeletal protein that may serve as a signal-responsive link between the dynamic cortical actin cytoskeleton and regions of membrane dynamics such as neurite-outgrowth processes and synaptic plasticity [32].

Mobkl3: Mobkl3 is both a member and a putative substrate of striatin family-protein phosphatase 2A (PP2A) complexes [33], an enzyme that belongs to a highly regulated family of serine/threonine phosphatases implicated in cell growth and signalling [34] which has been shown to participate in various signalling events crucially involved in neurodegenerative processes [35,36]. This adds a further interesting aspect on tianma’s potential application for a possible treatment of neurological diseases [4,12].

Clic4: Clic4 (chloride intracellular channel 4) is a multifunctional protein that localizes to the mt and cytoplasm and also traffics between the cytoplasm and nucleus while it interacts with Schnurri-2, a transcription factor in the bone morphogenetic protein (BMP) signalling pathway. Transforming growth factor beta (TGF-beta) promotes the expression of Clic4 and Schnurri-2 as well as their association in the cytoplasm and their translocation to the nucleus. In the absence of Clic4 or Schnurri-2, TGF-beta signalling is abrogated. Direct nuclear targeting of Clic4 enhances TGF-beta signalling and removes the requirement for Schnurri-2. Nuclear Clic4 associates with phospho (p)-Smad2 and p-Smad3, protecting them from dephosphorylation by nuclear phosphatases. These result in newly identified Clic4 as modifier of TGF-beta signalling through its function as stabilizer of p-Smad2 and 3 in the nucleus which is essential for Clic4-mediated growth-arrest and differentiation [37]. In addition, Clic4 mediates TGF-beta1-induced fibroblast-to-myofibroblast transdifferentiation [38] and is required for Ca2+-induced keratinocyte differentiation [39]. Proteomic analysis of vascular endothelial growth factor-induced endothelial cell differentiation reveals a role for Clic4 in tubular morphogenesis also hinting at its involvement in neuronal differentiation processes [40]. Furthermore, Clic4 could be involved in mt-membrane potential generation in mtDNA-depleted cells, a feature required to prevent apoptosis and to drive continuous protein import into mt [41]. Besides, in response to cellular stress Clic4 translocates to the nucleus for the control of apoptotic processes [42] making it another pivotal protein of the tianma-activated signalling cascade.

Mki67: The up-regulation of Mki67 (though rather considered as a proliferative marker) has also been observed previously for ginkgo biloba during the stimulation of neurogenesis [43]. The significance of this finding, however, still needs further detailed investigations.

Bax: Bax is a nuclear-encoded protein present in higher eukaryotes that is able to pierce the mt-outer membrane to mediate cell death by apoptosis [44]. However, a recent report demonstrated a non-apoptotic function of Bax in long-term depression of synaptic transmission with caspase-3 activation and Bax modulation as pivotal elements during synaptic plasticity [45]. Thus, fine tuning of bax and caspase-3 may contribute to tianma-mediated synaptic plasticity as part of tianma’s effect on cognitive functions [12].

Decreased levels of GTPases and stress-related proteins in differentiated neuronal N2a cells upon tianma stimulation

Sept2: Septins are an evolutionarily conserved group of GTP-binding and filament-forming proteins that belong to the large superclass of Ploop GTPases. Their expression is tightly regulated to maintain proper filament assembly and normal cellular functions. Septins perform diverse cellular functions according to tissue expression and their interacting partners. Functions identified to date include cell apoptosis, DNA damage response and alterations of these septin scaffolds, by mutation or expression changes, have been associated with a variety of neurological diseases such as AD and Parkinson’s disease (PD) [46,47]. As other Rho GTPases [48,49], Sept2 is crucially involved in modeling neurite outgrowth during neuronal differentiation and a tight regulation of its expression is necessary [50].

Dnm2: Dynamin 2 (Dnm2) is a large GTPase mainly involved in membrane trafficking through its function in the formation and release of nascent vesicles from biological membranes. Additionally, it tightly interacts with and is involved in the regulation of actin and microtubule networks, independent from membrane trafficking processes. Functional data on Dnm2 reveals the possible pathophysiological mechanisms via which Dnm2 mutations can lead to two distinct neuromuscular disorders. Dnm2 mutations cause autosomal dominant centronuclear myopathy, a rare form of congenital myopathy, and intermediate and axonal forms of Charcot-Marie-Tooth disease, a peripheral neuropathy [51,52]. Furthermore, altered expression of Dnm2 has been observed in AD [53].

Wnk1: Wnk1 is a Ser/Thr protein kinase and mutations in the nervous system-specific HSN2 exon of Wnk1 cause hereditary sensory neuropathy type II [54]. Moreover, Wnk1 was identified to interact with Rho-GDI1 to regulate Lingo1-mediated inhibition of neurite extension [55].

Prdx2: Peroxiredoxins are antioxidant enzymes involved in protein and lipid protection against oxidative injury and in cellular signalling pathways regulating apoptosis. In the CNS, Prdx2 has been shown to be expressed in neurons and its de-regulation has been associated with several neurodegenerative diseases such as AD and PD [56-59].

Tianma modulates (ER-resident) molecular chaperone proteins in differentiated neuronal N2a cells

Skp1a: Decreased expressions of the ubiquitin-proteasome/E3 ligase component Skp1a and the chaperone Hsc-70 can lead to a wide impairment in the function of an entire repertoire of proteins in neurons [60] suggesting a new structural role of Skp1a in dopaminergic neuronal functions besides its E3 ligase activity [61]. The close relation between apoptotic and neuronal differentiation pathways raises the question about the significance of tianma-mediated inhibition of Skp1a protein expression in differentiated neuronal N2a cells [62,63].

Hsp90aa1, Hsp90ab1, Hspa4, Hspa5: The heat shock protein (HSP) family has long been associated with a generalized cellular stress response, particularly in terms of recognizing and chaperoning misfolded proteins. HSPs are induced in response to many injuries including stroke, neurodegenerative diseases, epilepsy, and trauma. Hsp70 has a multifaceted role in neurons. It serves a protective role in several different models of nervous system injury. For instance, Hsp70 functions as a chaperone and protects neurons from protein aggregation and toxicity (in PD, AD, polyglutamine diseases, and amyotrophic lateral sclerosis), protects cells from apoptosis (PD), is a stress marker (temporal lobe epilepsy), and also protects cells from cerebral ischemic injury. However, it has also been linked to a deleterious role in some diseases [64,65]. In particular, it has been shown very recently that Hsp70 can suppress AD phenotypes in mice [66]. The main function of Hsp90 complexes is to maintain protein quality control and to assist in protein degradation via proteasomal and autophagic-lysosomal pathways. As such it plays a major role in the pathology of AD where it is crucially involved (with co-chaperones such as the immunophilins FKBP51 and FKBP52) in the control of aberrant phosphorylated tau protein [67]. Thus, alongside Mobkl3 and PP2A, tianma can eventually influence aberrant tau phosphorylation by modulating Hsp90 action [35,36,68].

Canx: Calnexin is an ER-resident molecular chaperone that plays an essential role in the correct folding of membrane proteins and a component of the quality control of the secretory pathway. Canx gene-deficient mice showed that Canx deficiency leads to myelinopathy [69]. In addition, Canx (-/-) cells have an increased constitutively active unfolded protein response (UPR). Importantly, Canx (-/-) cells have significantly increased proteasomal activity, which may play a role in the adaptive mechanisms addressing the acute ER stress observed in the absence of Canx [70]. Besides, caspase-3 or caspase-7 cleaves Canx, whose cleaved product, very interestingly, leads to the attenuation of apoptosis [71].

Trim28: In neurons disruption of Trim28, a key component of transcriptional repressor complexes in the brain, results in increased anxiety-like behavior and sensitivity to stress [72].

Calr: Calreticulin is a soluble calcium-binding chaperone of the ER that is also detected on the cell surface and in the cytosol. The protein is involved in the regulation of intracellular Ca2+ homeostasis and ER Ca2+storage capacity. Calr is also an important molecular chaperone involved in quality control within secretory pathways. As such, it is involved in the folding of newly synthesized proteins and glycoproteins and, together with calnexin (an integral ER membrane chaperone similar to Calr) and Pdia3 (ERp57, an ER protein of 57 kDa; a PDI (protein disulfide-isomerase)-like ER-resident protein), it constitutes the ‘calreticulin/calnexin cycle’ that is responsible for folding and quality control of newly synthesized glycoproteins. In fact, during recent years, Calr has been implicated to play a pivotal role in many biological systems, including functions inside and outside the ER, indicating that the protein is a multi-process molecule [73-75] that might be involved as an ER-resident chaperone in AD and PD [76-78].

Pdia3: Pdia3 is an ER-resident thiol-disulfide oxidoreductase which is modulating Stat3 (signal transducer and activator of transcription) signalling from the lumen of the ER together with Calr [79,80] that might be affected by PD [81].

Gnb2l1: This guanine nucleotide binding protein (G protein), also known as Rack1 (receptor for activated protein kinase C 1), regulates intracellular Ca2+ levels, potentially contributing to processes such as learning, memory and synaptic plasticity by binding specifically to an ionotropic glutamate receptor and thereby dictating neuronal excitation and sensitivity [82].

Atp5a1: Mt-ATP synthase catalyzes ATP synthesis, utilizing an electrochemical gradient of protons across the inner membrane during oxidative phosphorylation. It seems obvious that even intermittent and minor impairment of this highly important enzyme could deprive the brain tissue of energy at crucial times, which may predispose or contribute to neurological diseases [83].

Concluding, our data has shed new insights on the possible involvement of the herb tianma on neuronal functions and its potential effect on signalling molecules critically involved in common neurorestorative processes related to neurodegenerative diseases such as AD, PD or Huntington’s disease (Figure 10). However, further systemic functional in/ex vivo biology studies are required to decipher the functional significance of the individual bioactive components of tianma, by phytochemistry, to unravel their direct effect on neuronal activities related to neuroprotective activities in order to open new potential avenues based on tianma for the possible treatment of neurodegenerative diseases such as AD [4,84,85].

There has been  success in our office with PD patients to combine Glutathione or GlutaMax with tianma. Please contact us for more information.

BOOK YOUR CONSULTATION HERE

Screen Shot 2011-12-26 at 5.03.28 PM

Treatment with Apocynin or Picrorhiza kurroa decreases clinical and pathological features of parkinsonism

Abstract

This study evaluates the therapeutic efficacy of the NADPH oxidase inhibitor apocynin, isolated as principal bioactive component from the medicinal plant Picrorhiza kurroa, in a marmoset MPTP model of Parkinson’s disease (PD). The methoxy-substituted catechol apocynin has a similar structure as homovanillic acid (HVA), a metabolite of dopamine (DA). Apocynin acquires its selective inhibitory capacity of the reactive oxygen species generating NADPH oxidase via metabolic activation by myeloperoxidase (MPO). As MPO is upregulated in activated brain microglia cells of PD patients and in MPTP animal models, the conditions for metabolic activation of apocynin and inhibition of microglia NADPH oxidase are in place. Marmoset monkeys received oral apocynin (100 mg/kg; p.o.) (n = 5) or Gum Arabica (controls; n = 5) three times daily until the end of the study, starting 1 week before PD induction with MPTP (1 mg/kg s.c. for 8 days). Parkinsonian symptoms, motor function, home-cage activity and body weight were monitored to assess the disease development and severity. Post-mortem numbers of the tyrosine hydroxylase expressing DA neurons in the substantia nigra were counted. During the MPTP injections, apocynin limited the body weight loss and relieved parkinsonian symptoms compared to controls (Linear regression, P < 0.05) indicating a reduction of disease progression. During the last test week, apocynin also improved the hand-eye coordination performance compared with vehicle treatment (resp. 39.3 ± 4.5 % and 17.7 ± 6.7 %; P = 0.048) and improved the home cage activity with 32 % (P = 0.029), indicating anti-Parkinson efficacy. Apocynin also increased the number of surviving DA neurons in MPTP-treated marmosets with 8.5 % (P = 0.059), indicating a tendency towards a neuroprotective efficacy. In conclusion, compensation for the loss of DA and its metabolite HVA by apocynin mitigates the PD progression and limits the parkinsonian signs and motor-function deterioration.

Glutathione is a powerful antioxidant and works to selective inhibitory capacity of the reactive oxygen species generating NADPH oxidase via metabolic activation by myeloperoxidase (MPO) as well. As MPO is upregulated in activated brain microglia cells of PD patients where the conditions for metabolic activation of oxidation leading to microglia NADPH oxidase, Glutathione also acts to inhibit this microglia activation as well. There has been some fare success in our office with PD patients to combine Glutathione or GlutaMax with Picrorhiza. Breathe from MitoZen offers Apocynin! Please contact us for more information.

BOOK YOUR CONSULTATION HERE

Screen Shot 2011-12-26 at 5.03.28 PM

Using saccadometry to measure the eye saccade can be of great help to measure issues parkinson’s patients commonly have with omnipause intrusions.

FCR is a natural approach to treatment of Parkinson’s Disease. Using saccadometry to measure the eye saccade can be of great help to measure issues parkinson’s patients commonly have with omnipause intrusions. This devices also can be helpful to measure effectiveness of treatments. Dr. John uses Endo-Nasal adjusting, Glutathione, PEMF of the brain, and Brain exercises that are targeted to the Dopamine producing neurons in the brain to activate them in order to keep them healthy and get them to produce dopamine naturally. Dr. John Lieurance has been pioneering the use of these modalities to treat parkinson’s for several years. He is a Chiropractic Neurologist and is located in Sarasota Florida.

Screen Shot 2011-12-26 at 5.03.28 PM

Natural Approach to Parkinson’s Disease: Chiropractic Neurology

FCR is a natural approach to treatment of Parkinson’s Disease. Using Endo-Nasal adjusting, Glutathione, PEMF of the brain, and Brain exercises that are targeted to the Dopamine producing neurons in the brain to activate them in order to keep them healthy and get them to produce dopamine naturally. Dr. John Lieurance has been pioneering the use of these modalities to treat parkinson’s for several years. He is a Chiropractic Neurologist and is located in Sarasota Florida.

Dr. John, I am sitting in my home in Texas considering the events of this past week. As I become more and more aware of how much better I feel physically and mentally, I am overwhelmed with emotion! Thank you from the bottom of my heart for what you do! I have so much hope for the future! Praise God, that you are using your gift He has bestowed upon you! You are doing a monumental work! Your friend, CG – Texas

Screen Shot 2011-12-26 at 5.03.28 PM

New Research shows Pesticide / Pakinsons connection! Learn how you an protect yourself with Glutathione.

Chronic systemic pesticide exposure reproduces features of Parkinson’s disease.

Ranjita Betarbet1, 2, Todd B. Sherer1, 2, Gillian MacKenzie1, Monica Garcia-Osuna1, Alexander V. Panov1 & J. Timothy Greenamyre1

1  Department of Neurology, Emory University, 1639 Pierce Drive, WMB 6000, Atlanta, Georgia 30322, USA

The cause of Parkinson’s disease (PD) is unknown, but epidemiological studies suggest an association with pesticides and other environmental toxins, and biochemical studies implicate a systemic defect in mitochondrial complex I. We report that chronic, systemic inhibition of complex I by the lipophilic pesticide, rotenone, causes highly selective nigrostriatal dopaminergic degeneration that is associated behaviorally with hypokinesia and rigidity. Nigral neurons in rotenone-treated rats accumulate fibrillar cytoplasmic inclusions that contain ubiquitin and alpha-synuclein. These results indicate that chronic exposure to a common pesticide can reproduce the anatomical, neurochemical, behavioral and neuropathological features of PD.

Comment:

How can you protect yourself? Glutathione acts like fly paper and wraps around then carries the toxins such as heavy metals and pesticides out of the body. Reseaech has proven that PArkinson’s in due to oxidative stress in the S. Nigra in the brain and low Glutathione levels contribute to the damage. Protecting your brain by supplementing with Glutathione is a smart choice. Remember you cann’t take Glutathione orally so suppositories and nebulization are a great option.

Testing for Brain Degeneration with the Oxidata test. A Way to Measure Parkinson’s Progression.

Test Your Free Radical Level in 5 Minutes – at Home!

ORDER A 4 MONTH OXIDATA TEST KIT HERE

The Oxidata™ Test enables you to determine the level of stress on your body caused by free radical activity.  People of all ages can benefit from knowing if they are getting enough antioxidants in their diets and nutritional supplements to effectively counteract free radical cell damage.

The Oxidata Test™ provides a useful nutritional guide in the form of a color chart that helps determine the amount of oxidative activity in the body and can be helpful in making appropriate lifestyle and dietary changes as well as monitoring Glutathione levels.

This one-time use, at-home urine test kitmeasures the level of free radicals in your system. Too many free radicals over a period of time leads to chronic diseases, cell damage and faster aging. Keeping track of your oxidation is really a measure of your Glutathione as Glutathione is your master antioxidant.

Causes of free radical damage

  • Heavy metals and petrochemicals in the environment and in our foods
  • Over-the-counter and prescription drugs
  • Cooked oils and fats
  • Radiation
  • Viruses, yeast and bacteria in the system
  • Low dietary anti-oxidants
  • Mental/emotional stress
  • Low Glutathione Levels

Everyone has heard of free radicals and the importance of antioxidants in the diet.  The Oxidata™ Test enables the user to measure the amount of oxidative stress the body is enduring and the results of antioxidant intervention.

Many, if not all disease, afflict the body through oxidative damage.  The free radical theory of aging says that it is the primary cause of aging itself.

Free radicals are like fire.  It is only when free radicals become unconfined and excessive and start attacking normal, healthy tissue that disease takes place.  This happens when antioxidant / Glutathione activity is inadequate.

ORDER A 4 MONTH OXIDATA TEST KIT HERE

Discover Your Need for Antioxidants

  • The Oxidata™ Test is the world’s first and only non-invasive urine test that measures the amount of free radicals or oxidants in the body within five minutes.
  • The Oxidata™ Test is an advanced patented technology available through GlutaGenic.com

Features

  • In-Office or At-Home Convenience
  • Quick 5-minute test
  • Scientifically Developed
  • This urine test provides higher accuracy than an MDA (malondialdehyde) blood test.  Accuracy is within the range of 90%.

The Oxidata Test Kit Includes:

  • Free Radical Activity Evaluation Color Chart
  • Evaluation Explanation
  • Urine cup, the testing vial, a pipette to add urine to the vial, and specific directions.
  • Each kit contains one test vial for one-time use.

Instructions

Supplemental Dietary Restrictions Prior To Using Your Oxidata Test:  The day before you use the test, do not take supplemental vitamins, such as vitamin C, vitamin B complex, or vitamin B-1 (thiamine), vitamin B-2 (riboflavin), vitamin B-3 (niacin, also known as pyridoxamine). Any oral intake of vitamins or medication that turns your urine to an excessively yellow color (Riboflavin) may interfere with your ability to interpret the reading of your value. If you are currently taking any medications consult with your physician about the results of this test. Also don’t take your Glutathione the day before.

Use the test at least once a week if the initial test shows high oxidative stress then reduce to once or twice a month after antioxidant supplementation has reduced it to a normal level. For optimal results, consult your healthcare practitioner before taking nutritional supplementation.

Place urine in cup and draw up one milliliter with the dropper. Break top off of ampoule and squeeze urine from dropper into ampoule. Wait five minutes; then hold ampoule up to evaluation chart to match colors. Record your reading on our Oxidata™ Test chart.

Frequency of Test

The frequency for the Oxidata™ Test varies with each individual. If an individual test color is in the high free radical range, the person should begin or increase antioxidant supplementation and retest at least twice a month until free radical activity has been reduced. The Oxidata™ Test should be taken once a month thereafter.

ORDER A 4 MONTH OXIDATA TEST KIT HERE

Your Test Results

If your score is high we recommend that you consider Signing up for the “7 Secrets to Raising Glutathione” as well as Glutathione Supplementation.

Thank You for Joining me Today! 

Essential Tremor is treated using the latest in Neurology by Sarasota Doctor. Watch video on how.

Essential tremor (ET) is a slowly progressive neurological disorder of which the most recognizable feature is a tremor of the arms or hands that is apparent during voluntary movements such as eating and writing.[1] This type of tremor is often referred to as “kinetic tremor.”  The general pattern being that the tremor begins in the arms and then spreads to these other regions in selected patients.  Some patients may have unsteadiness and problems with gait and balance that are above and beyond that due to normal aging. Aside from enhanced physiological tremor, it is the most common type of tremor and one of the most commonly observed movement disorders.[11] Essential tremor was also previously known as “benign essential tremor”, but the adjective “benign” has been removed in recognition of the sometimes disabling nature of the disorder. Although essential tremor is often mild, patients with severe tremor have difficulty performing many of their routine activities of daily living.

Restless Leg Syndrome

Restless legs syndrome (RLS) is a neurological disorder characterized by throbbing, pulling, creeping, or other unpleasant sensations in the legs and an uncontrollable, and sometimes overwhelming, urge to move them. Symptoms occur primarily at night when a person is relaxing or at rest and can increase in severity during the night. Moving the legs relieves the discomfort. Often called paresthesias (abnormal sensations) or dysesthesias (unpleasant abnormal sensations), the sensations range in severity from uncomfortable to irritating to painful.

The most distinctive or unusual aspect of the condition is that lying down and trying to relax activates the symptoms.

Considerable evidence suggests that RLS is related to a dysfunction in the brain’s basal ganglia circuits that use the neurotransmitter dopamine, which is needed to produce smooth, purposeful muscle activity and movement. Disruption of these pathways frequently results in involuntary movements. Individuals with Parkinson’s disease, another disorder of the basal ganglia’s dopamine pathways, often have RLS as well.

Some studies show that RLS can be an early symptom of Parkinson’s disease.

Parkinsonism

Any person who has the signs and symptoms characteristic of Parkinson’s disease is said to have parkinsonism, but not every person with parkinsonism has Parkinson’s disease, it’s only one of the possibilities.

Patients and their families need to understand parkinsonism, because some 20 to 25 percent of people diagnosed with Parkinson’s disease will eventually be discovered to have some other form of parkinsonism. Parkinsonism may look like Parkinson’s disease, but over time it does not act like it.

For this reason, if you have been diagnosed with Parkinson’s disease it is important to see a neurologist who has experience diagnosing and treating this disorder.

Treatment for Parkinson’s Disease

Featured

What is NAD+?

NAD+ stands for Nicotinamide Adenine Dinucleotide, and is an essential molecule found in every cell of your body. It is a coenzyme of Vitamin B3 (niacin), which means it’s a small helper molecule that binds to a protein molecule in order to activate an enzyme. Enzymes are responsible for over 5,000 different biochemical reactions throughout the body and NAD+participates in more reactions than any other vitamin-derived molecule.

What does NAD+ do?

NAD+ stands for Nicotinamide Adenine Dinucleotide, and is an essential molecule found in every cell of your body. It is a coenzyme of Vitamin B3 (niacin), which means it’s a small helper molecule that binds to a protein molecule in order to activate an enzyme. Enzymes are responsible for over 5,000 different biochemical reactions throughout the body and NAD+participates in more reactions than any other vitamin-derived molecule.

  • ENERGY PRODUCTION– NAD+ helps your cells convert food into energy by acting as an electron transporter during cell metabolism.
  • Repair DNA – A constant supply of NAD+ is needed for the activation of PARPs, which detect and repair damaged DNA.
  • Enzyme Activty – A class of enzymes called sirtuins help regulate certain metabolic pathways and genetic expressions. Sirtuins are NAD-dependent and the more sirtuin activity, the better for health and longevity. Increased sirtuin activity can help increase metabolism, decrease inflammation, extend cell life, and prevent neurodegeneration.
  • Cell Signaling– NAD+ is also released from the intercellular space to the extracellular space for communication. Research is revealing that NAD and ATP may alert the immune response when the cell is under stress or when there is inflammation.
  • Neurotransmitter– Although more research still needs to be conducted, in some instances, NAD+ meets the pre- and postsynaptic criteria for a neurotransmitter. NAD+ is released from smooth muscle, neurosecretory cells, and brain synaptosomes for cell-to-cell communication. NAD helps the enzyme pathway from tyrosine to dopamine which is compromised in Parkinsons Disease.
  • Gene Expression– A class of enzymes called sirtuins help regulate certain metabolic pathways and genetic expressions. Sirtuins are NAD-dependent and the more sirtuin activity, the better for health and longevity. Increased sirtuin activity can help increase metabolism, decrease inflammation, extend cell life, and prevent neurodegeneration.

    NAD+ and NADH are used in processes such as metabolizing alcohol and converting lactate to pyruvate in the body.

    What is NAD+ Therapy?

    NAD+ Therapy involves a high dose intravenous infusion of NAD+ that goes straight into the bloodstream. IV therapy allows NAD+ to bypass the digestive system for better absorption. NAD+ works rapidly to repair cells throughout the body and neurons in the brain.

    ​Every client has an individualized protocol based on the condition, so treatment length can vary from 4 to 12 days. Clients receive a high dose IV therapy under the supervision of Dr. Milgram and qualified nurses. The therapy is administered in a calm, holistic outpatient setting that allows working professionals the flexibility they need and out-of-towners the opportunity to see the beautiful city of Sarasota, Florida.

    NAD+ therapy anecdotally has a synergistic effect when combined with other innovative therapies offered at advanced rejuvenation. These include:

  • Whole Body Cryotherapy

  • Hyperbaric Oxygen Therapy

  • Naturopathic Nutritional Support

  • Functional Chiropractic Neurology

  • Stem Cell Therapy

  • Acupuncture

  • Platelet Rich Plasma

  • Prolozone

  • IV Laser Therapy

Benefits of NAD+ Therapy

When your NAD+ levels are increased, your cells produce more energy, your good genes are “turned on”, DNA is repaired, and many other functions are optimized. Since NAD+ is such a powerful and prolific molecule in the body, high dose IV therapy can be helpful for many different conditions including:

  • Neurodegeneration such as Parkinson’s 

  • Hearing Loss and Tinnitus

  • Substance Abuse

  • Addiction

  • Anxiety

  • Stress

  • Depression

  • PTSD

  • Chronic Fatigue

  • Chronic Pain

  • Brain Injury & TBI

  • Mitochondrial Disease

  • Aging

At the end of treatment with NAD+ therapy, clients have generally reported the following benefits:

  • Increased Energy

  • Increased Mental clarity

  • Improved Focus and concentration

  • Enhanced sense of purpose

  • Improved mood

  • Improved memory

  • Improved eyesight

  • Improved hearing (Read more here)

  • Reduced Pain

 Our clinic is a certified provider of a proprietary NeuroREJUVENATION ™ Therapy developed by Advanced Rejuvenation, the first and longest operating NAD+ clinic in Florida. Call or email for a FREE consultation. 941 330-8553 or AskdoctorJL@Gmail.com

Glutathione and Parkinsions- Genetics show sufferers of PD have low Glutathione levels!

7 Secrets to Raising Glutathione

Explore Glutathione Suppository and Parkinsons.

Watch these video’s of patient’s receiving our treatments.

Various Glutathione treatment options for Parkinson’s Disease by Dr. John from John Lieurance, DC on Vimeo.

Click on the link below to schedule your consultation TODAY!

Schedule

Understanding the brain and nervous system is at the core of many health challenges is crucial in understanding why FCR works so well on Parkinson’s Disease. Your brain and nervous system control every aspect of your body’s response to stress, like mental stress, emotional stress, structural stress, toxic stress, and even infections.

By balancing your brain you balance your body’s response to stress and it’s environment.

“The Nervous System Controls and Coordinates all the Systems of the Body and Relates the Individual to Their Environment” Gray’s Anatomy, 24th edition, pg.46

Functional Cranial-Release is the art and science of restoring normal brain and nervous system function by using Functional Neurology along with specific endo-nasal balloon manipulation to accomplish the following:

1) Restore the brains ability to oxygenate itself through both improving air flow into higher area’s through the nasal passage and also improve the normal pumping action inherent in all of use (cranial rhythm) that moves nutrients such as oxygen and neurotransmitters that bath the central nervous system keeping it healthy. This can be helpful to better distribute Dopamine around the specific areas of the brain! Also better nutrient supply to areas such s the substantia nigra!

2) Utilize neurologic testing to determine the pathways and brain centers that are viable area’s to support better substantial nigra integrity and dopamine producing areas of the brain. Area that can support a Parkinson’s sufferer can be explored using the following; Examination of your eye’s movements and reflex’s which can be a major problem with Parkinson’s such as poor saccade function and poor smooth eye pursuit! In Parkinsons There are specific areas of the brain that shut down and cause many of the symptoms such as slowness of movement, tremor, stiffness, constipation and poor balance. With FCR we look through these systems with testing such as a saccadometer test and other neurological testing to see how this is showing up in your specific case. Also the muscles or motor system, the autonomic nervous system, your circulation, your sensory system, the vestibular system (or) your ability to balance. Through the specific use of various modalities such as one or more of the following; Very Specific cranial adjustments along with specific neurological exercises to include such ones as Eye Pattern & Eye Exercise’s, Canalith Repositioning (or) Eply’s, Vestibular Rehabilitative Modalities or VRT, and many others too numerous to list.  We also utilize Glutathione therapies. The modalities used depend on the specific needs of the patient. Please sign up for the 7 secrets to raising glutathione at the bottom of this page for a free video course by Dr John.

3) A series Cranial Release’s are performed where the connective tissues that surround your brain and spinal cord called the Dura Mater are specifically released using endonasal balloon inflations. This is done in combination with the above mentioned functional neurologic modalities to provide the therapeutic effect to balance and normalize brain function. This normalization results in healing and management of Parkinson’s associated with neurodegenerative dis-orders.

Glutathione

See Glutathione at GlutaGenic.com for exciting delivery systems for boosting brain function and allowing healing and improvement from neurological conditions. This is often used like the oxygen to allow a greater window for driving brain healing through FCR. Often your brains metabolic state can be a limiting factor in doing certain activities that can be of benefit to your brain. Oxygen and Glutathione can open some doors for you in this area.

Watch this demonstration of FCR being performed.

Here is a video demonstrating FCR with a Vertigo and Migraine Patient.

What others are saying about FCR.

Call (941) 330-8553 for an appointment.

You can also request a phone consultation if you are out of town.

E-Mail Dr. John at ASKDOCTORJL@Gmail.com

Yours in Health,

John Lieurance, D.C.