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Global Nutrigenomics Market 2022-2026 The analyst has been monitoring the nutrigenomics market and it is poised to grow by $ 690. 14 mn during 2022-2026, accelerating at a CAGR of 12.

New York, Aug. 17, 2022 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Nutrigenomics Market 2022-2026" - https://www.reportlinker.com/p06314557/?utm_source=GNW 4% during the forecast period. Our report on the nutrigenomics market provides a holistic analysis, market size and forecast, trends, growth drivers, and challenges, as well as vendor analysis covering around 25 vendors.The report offers an up-to-date analysis of the current global market scenario, the latest trends and drivers, and the overall market environment. The market is driven by the increasing cost of medical treatment, growing investments by government and private stakeholders, and the rising number of health-conscious people.The nutrigenomics market analysis includes the application segment and geographic landscape.

The nutrigenomics market is segmented as below:By Application Obesity Cardiovascular diseases Cancer research

By Geographical Landscape North America Europe Asia Rest of World (ROW)

This study identifies the rising demand for training in and awareness of nutrigenomics technologies as one of the prime reasons driving the nutrigenomics market growth during the next few years. Also, increasing approval of grants and increasing prevalence of obesity will lead to sizable demand in the market.

The analyst presents a detailed picture of the market by the way of study, synthesis, and summation of data from multiple sources by an analysis of key parameters. Our report on nutrigenomics market covers the following areas: Nutrigenomics market sizing Nutrigenomics market forecast Nutrigenomics market industry analysis

This robust vendor analysis is designed to help clients improve their market position, and in line with this, this report provides a detailed analysis of several leading nutrigenomics market vendors that include BASF SE, Cell Logic Pty Ltd, Cura Integrative Medicine, DNA Life, Fagron NV, geneOmbio Technologies Pvt Ltd., Genetic Healing, Genova Diagnostics Inc., Greenarray, Holistic Health International LLC, Koninklijke DSM NV, Metagenics Inc., My DNA Health Ltd., NutriFit Canada, Nutrigenomix Inc., ORIG3N Inc., Preventine Life Care, The Gene Box, and Xcode Life Sciences Pvt. Ltd. Also, the nutrigenomics market analysis report includes information on upcoming trends and challenges that will influence market growth. This is to help companies strategize and leverage all forthcoming growth opportunities.The study was conducted using an objective combination of primary and secondary information including inputs from key participants in the industry. The report contains a comprehensive market and vendor landscape in addition to an analysis of the key vendors.

The analyst presents a detailed picture of the market by the way of study, synthesis, and summation of data from multiple sources by an analysis of key parameters such as profit, pricing, competition, and promotions. It presents various market facets by identifying the key industry influencers. The data presented is comprehensive, reliable, and a result of extensive primary and secondary research. Technavios market research reports provide a complete competitive landscape and an in-depth vendor selection methodology and analysis using qualitative and quantitative research to forecast accurate market growth.Read the full report: https://www.reportlinker.com/p06314557/?utm_source=GNW

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The Global Nutrigenomics Market is expected to grow by $ 690.14 mn during 2022-2026, accelerating at a CAGR of 12.4% during the forecast period -...

The Indian Institute of Chemical Technology (IICT)s 10th director D. Srinivasa Reddys career reads like a fairy tale.

The Shanti Swarup Bhatnagar award winner hails from Shobhanadripuram village in Nalgonda district, studied in a Telugu medium school till his graduation, did his post-graduation from Osmania University and Ph.D. from University of Hyderabad (UoH) under the tutelage of eminent academic-scientist Prof. Goverdhan Mehta.

He is currently holding the additional charge of CSIR-Institute of Integrative Medicine (Jammu) and CSIR-Drug Research Institute (Lucknow). In this interview, Dr. Reddy talks about his life and plans for the premier chemical research institute.

a) You have been a project assistant here and have returned as the director!

A: My father was a farmer and I never thought of becoming a scientist. I came to Hyderabad for my Intermediate in Mahabub College and B.Sc (BZC) in S.P. College when I used to distribute newspapers, give home tuitions and worked in a timber depot loading logs to earn money. With a lot of difficulty I joined as a project associate in IICT. Later, I cleared my CSIR-NET exam and joined Prof. Mehta. From then on, it has been growing upwards though hard work and perseverance.

b) How did your switch from private sector to research in public labs happen?

A: After my post-doctoral studies in United States and seriously considering settling there, I was offered a job with Dr. Reddys Labs. Later, I moved to Advinus Therapeutics (Pune) after which I joined CSIR-National Chemical Laboratory (Pune) as I wanted to pursue my passion for organic chemistry research, taking a huge pay cut. My wife, Vidya Ramdas, has been my co-researcher from UoH days and she continues to work in the pharma field. We have done some great work at NCL and I continue to have my lab with six research students. Soon, I will have a lab here and take in student researchers.

c) What are the areas of research you have been working on?

A: We developed the Silicon-switch approach for developing drug strategies for diseases affecting the central nervous system as most patents do not claim silicon derivatives. This has huge potential in discovering drugs in a short time. Our group has identified a few novel compounds that can protect from vector spreading diseases like dengue or zika virus and also kill the mosquitoes. We have filed a patent and talks are on with a private firm to develop this further for daily use. We have collaborated with different labs including CSIR-CCMB to authenticate the anti-cancer drug for use in Sickle Cell Anaemia.

d) What will be the areas of focus here in IICT?

A: We will be actively involved in the Anti-Virus Mission in association with other CSIR labs studying available molecules and re-purposing of existing anti-viral drugs to deal with SARS-COVID, Monkey Pox and several other viruses. We will soon have a BSL-3 facility here. We are actively assisting pharma and vaccine companies in their research. Our aim is to make the country self-reliant in APIs active pharmaceutical ingredients, KSMs- key starting materials and others with public, private partnerships. I am still trying to understand the various projects here.

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IICT to be involved in anti-virus mission & public, private partnerships for developing APIs - The Hindu

Zinc is an essential mineral for your health. It plays a role in:

Of all the trace minerals, only iron is found in higher concentrations in the body.

Yet even though zinc is important for your health, you can still get too much of it.

"The tolerable upper intake level (UL) for zinc, meaning the highest recommended daily amount, is 40 mg per day," says Dr. Jeffrey Gladd, an integrative medicine physician and chief medical officer at Fullscript.

Read on to learn the signs of a zinc overdose, how to get treatment, and what you can do to get the recommended daily amount of zinc.

A zinc overdose can involve different symptoms, depending on whether it's acute or chronic.

An acute overdose means you ingest a large amount of zinc in a short period of time.

Symptoms of an acute overdose usually won't appear until you ingest one to two grams of zinc, and Gladd says you don't need to worry about getting too much zinc from your diet.

A zinc overdose typically happens as a result of:

Symptoms of acute zinc overdose might include:

A zinc overdose can be life threatening. If you suspect you may have consumed too much zinc and have symptoms of an overdose, you'll want to contact 911 or a poison control center for emergency medical support, Gladd says.

The treatment for oral zinc overdose may include:

A chronic overdose means you've regularly consumed too much zinc over a longer period of time.

Chronic zinc overdose can occur when you ingest anywhere from 150-450 milligrams (mg) of zinc per day.

This generally happens as a result of taking too many zinc supplements, but using large amounts of zinc-containing denture creams can also expose you to excess zinc.

The symptoms of chronic excess zinc can affect your whole body and may include:

If you've taken more than the daily recommended amount of zinc for more than a few days and notice any of the above signs and symptoms, you should stop taking any supplemental zinc and check in with your doctor. Depending on how much zinc you've taken, and for how long, they may recommend treatment.

If you eat a balanced diet that includes a variety of zinc-containing foods, you likely don't need to supplement with extra zinc, Gladd says. This means, of course, you won't run the risk of getting too much zinc.

Foods that contain plenty of zinc include:

However, certain groups of people are more likely to have a zinc deficiency, including:

"If you're concerned about zinc levels, the best option is to get a zinc blood test. They are relatively inexpensive and allow you to get quick, accurate results," says Daniel Powers, herbal medicine expert and founder of the Botanical Institute.

Keep in mind it's always important to ask a healthcare professional before taking any supplement especially zinc, which you can easily overconsume.

The FDA doesn't regulate supplements, so it's important to check with your doctor if you're unsure about how much of any supplement to take. Opting for supplements that have undergone third-party testing can also help you ensure you get the supplement you want, in the advertised amount.

If you choose to supplement, keep in mind that experts recommend consuming no more than the recommended daily allowance (RDA) of zinc:

Zinc requirements for children and teens range from 2 mg to 11 mg per day, depending on age. If you think your child may not get enough zinc from their diet, it's best to ask your pediatrician about the correct dose.

Although you need zinc to maintain good health, you can take too much and excess zinc can have serious health consequences. If you've taken more than the daily recommended dose of zinc, you should get medical attention right away.

In most cases, a varied diet will provide enough zinc, and many people don't need to supplement. However, if you eat a limited diet, are pregnant or lactating, or have a health condition that affects zinc absorption, you may have a higher risk of zinc deficiency.

Your doctor or another healthcare professional can offer more guidance on how much zinc you should take for optimal health.

The rest is here:
Zinc side effects: Signs of overdose and how to treat it - Insider

Introduction

Type 2 diabetes mellitus (T2DM) and obesity are major public health problems affecting millions of people worldwide. T2DM is a metabolic disorder characterized by long-term hyperglycemia and is one of the leading causes of morbidity and mortality.1 Obesity is an important exo-promoting factor of T2DM. Accumulating evidence demonstrates that obesity is not only strongly related to the etiology and pathogenesis of T2DM but also to the development of diabetic complications.2 Hyperglycemia and glucose toxicity can induce oxidative stress, worsening the outcome of AMI (acute myocardial infarction) in patients with diabetes.3 In addition, both hypertension and diabetes are critical risk factors for stroke in patients with atherosclerotic cardiovascular impairment.4 Capability of entering the CNS is an effective way for drug development to improve metabolism, alleviate diabetes, and obesity. CNS is an important target for improving obesity and many obesity-improving drugs exert effect through the CNS.5 Therefore, whether it can cross the BBB determines the effect of the drug. GLP-1 is secreted during mealtime and reduces blood glucose levels by enhancing insulin secretion and inhibiting glucagon release. A growing number of GLP-1RAs have been produced, which can be classified into short-acting or long-acting compounds. The net effects of the former reduce postprandial blood glucose, while the latter affects both fasting and postprandial blood glucose.6 In rodents, the anorexigenic effect of GLP-1RA administration peripherally requires central GLP-1R, for it is not inhibited in mice with central specific GLP-1R deletion.7

Sodium-glucose cotransporter-2 inhibitors (SGLT-2is) are a novel class of oral drugs for the treatment of T2DM. These drugs block SGLT-2 in proximal tubules, through which 90% of glucose is reabsorbed, thus decreasing the reabsorption of glucose and lowering the blood glucose levels.8 In addition to the anti-diabetic effects, weight loss has also been observed in patients receiving SGLT-2i monotherapy.911 This drug class affects multiple systems, including the nervous, cardiovascular and endocrine systems, resulting in exceedingly complex metabolic effects beyond glycemic control.

Clinical studies have shown that both SGLT-2is and GLP-1RAs reduce body weight and lower the risk of hospitalization and mortality of cardiovascular disease such as AMI in patients with type 2 diabetes.1214 These two agents possibly share similar CNS routes, but their modes of action might be very distinct.15,16 The blood-brain barrier (BBB) is a dynamic barrier that maintains the regular physiological state and metabolism of the central nervous system (CNS), but it also inhibits peripheral drugs from entering the CNS.17 Both the lipid-soluble GLP-1RAs and small-molecule SGLT-2is were considered to be able to cross the BBB in numerous preclinical trials.

Furthermore, increased levels of circulating free fatty acids, inflammatory cytokines (TNF-, IL-1, IL-6) and chemokines increase BBB permeability. These effects are compounded by the apoptosis of BBB microvascular endothelial cells caused by hyperglycemia and obesity.1821 BBB impairment has also been reported in a variety of neurological disorders, including Parkinsons disease and Alzheimers disease.22 Interestingly, oxidative stress is a common feature of all these cases. Elevated levels of reactive oxygen species (ROS) are observed during pathological processes, and ROS is considered to contribute to the increased permeability of the BBB. Mitochondria are the main source of ROS production in cells. The destruction of the mitochondrial electron transport chain (ETC) leads to an increase in ROS production, which triggers matrix metalloproteinases (MMP) induction, ultimately disrupting tight junctions and increasing BBB permeability.23 The integrity of the BBB is compromised in certain pathological states, and its temporary disruption allows drugs in the peripheral circulation to enter the CNS. Consequently, GLP-1RAs and SGLT-2is are able to cross the BBB. Terami et al revealed that diabetes-induced disruption of the BBB allowed SGLT-2is to pass through in a dose-dependent manner.24

This review introduces the basic structure and permeation mechanism of the BBB, discussing the relationship between the structural and/or chemical properties of SGLT-2is/GLP-1RAs and their permeability through the BBB.

The bloodbrain barrier (BBB) is composed of capillary endothelial cells linked by tight junctions, basal lamina, pericytes, and astrocytes. It acts as a regulatory interface between capillaries and nerve tissues in the brain and spinal cord that restricts the transfer of most drug substances from the bloodstream into the brain and serves as an important barrier to maintaining the brains homeostasis (Figure 1).17,25 However, some structures, such as circumventricular organs (CVOs), lack a complete BBB. CVOs are composed of malformed ependymal cells and many leaky capillaries that lack a full blood-brain barrier, allowing chemicals to enter the brain. CVOs include the pineal gland, the organum vasculosum of the lamina terminalis (OVLTs), the subfornical organ (SFO), the choroid plexus, the region postrema (AP), the pituitary glands posterior lobe, the subcommissural organ, and the median eminence (ME) of the mediobasal hypothalamus.26,27

Figure 1 Structure of the BBB: capillary endothelial cell, tight junction, basal lamina, astrocyte, pericyte, interneuron.

The semipermeable nature of BBB restricts the movement of large molecules, such as drugs or proteins >500 kDa. Compounds having logPoct2.0 have optimal brain penetration. The parameters used for predicting drug penetrability by modified Lipinskis rules for CNS penetration include hydrogen bond donors (HBD) 3; hydrogen bond acceptors (HBA) 7; logPoct 5.0; 7.5 < pKa < 10.5; molecular weight 400Da.28

Substances can cross the blood-brain barrier via paracellular transport and intercellular transport. Although most macromolecules in the blood are physically prevented from entering the brain due to the presence of the blood-brain barrier and tight junctions, specific and non-specific transcellular mechanisms transport various macromolecules and complexes across the blood-brain barrier. Figure 2 illustrates several primary routes across the BBB: positively charged macromolecules cross the BBB via adsorptive-mediated transcytosis (AMT); non-polar solutes and lipid-soluble drugs pass via passive diffusion; c) carrier-mediated transport (CMT) is responsible for the transport of a variety of essential polar molecules into the CNS; and receptor-mediated transcytosis (RMT), which requires specific ligands29 (Figure 2).

Figure 2 Mechanism of BBB transportation: a) Carrier-mediated influx, in which polar molecules are transported; b) Adsorptive-mediated transcytosis, in which positively charged macromolecules bind to receptors and are transported across the endothelial cell; c) Passive diffusion, in which most lipid-soluble molecules are transported; d) Receptor-mediated transcytosis, in which macromolecules bind to receptors and are transported to the CNS; e) Tight junction model (partially or completely open). Arrows indicate the direction of transportation.

Jensen et al conducted a study in the CNS by isolating and purifying a novel specific monoclonal GLP-1R antibody and detecting the location of GLP-1R using an in situ hybridization technique.30,31 The results confirmed that GLP-1 receptors (GLP-1R) are widely distributed throughout the cerebral cortex, hypothalamus, hippocampus, thalamus, caudate nucleus, and globus pallidus. Numerous studies focusing on diverse brain illnesses such as Alzheimers disease (AD) and ischemic brain injury have corroborated the localization of GLP-1R in the CNS.3234 In addition, a study reported GLP-1R expression on pericytes, which are multi-functional mural cells located at the center of the neurovascular unit (NVU).35 Other studies have mapped the action of GLP-1RAs, demonstrating that GABA neurons in the NTS express GLP-1 receptors and mediate the anorectic effects of liraglutide in rats.36 However, a study of single-cell RNA sequencing in the brain shows that the presence of GLP-1R on BBB endothelial cells is negligible.37

Exenatide,38 lixisenatide,39,40 beinaglutide,41 liraglutide,42 dulagutide43 and semaglutide44 are now commercially accessible as GLP-1 receptor agonists (Table 1). The GLP-1 receptor agonists can be classified into two groups based on their chemical structure. Exenatide is based on the exendin-4 structure and has a low amino acid sequence homology with human GLP-1, whereas natural GLP-1RAs, such as liraglutide, have a higher amino acid sequence homology of 95% with human GLP-1.45 According to the different molecular conformations (natural GLP-1 or long-acting GLP-1 analogs) and drug administration pathways, GLP-1 and its analogs transmit food reduction signals directly or indirectly to the central nervous system (CNS) through different signal pathways.

Table 1 The Physicochemical Properties of GLP-1 Receptor Agonists

Numerous studies have discovered the expression of native GLP-1 in CNS, implying that natural GLP-1 could cross the BBB from the peripheral circulation via passive transport due to their physiological, molecular biology, pharmacokinetic, and pharmacodynamic properties. Kastin et al observed and analyzed the influx rate following intravenous injection of 125I-[Ser8] GLP-1. The blood-brain flow of GLP-1 via passive diffusion may be determined by its physicochemical properties rather than lipophilicity, demonstrating the BBBs permeability to GLP-1.46 Several preclinical and clinical studies on ischemia-induced brain injury, Alzheimers disease (AD), Parkinsons disease (PD), and other neurodegenerative disorders have established that GLP-1RAs can cross the BBB and exert a significant neuroprotective effect.3234 Furthermore, various studies have examined the anorexia-promoting properties of GLP-1RAs. The studies have demonstrated that GLP-1R is also expressed in nuclei controlling food intake, such as the arcuate nucleus (ARC) and paraventricular thalamic nucleus (PVN). Previous studies also demonstrated that GLP-1RAs might cross the BBB and promote bodyweight loss by acting on these nuclei.4750 The effect of intravenous infusion of GLP-1 on food intake disappeared after vagotomy in humans, which suggested that the vagus afferent pathway is involved in the effect of GLP-1 on appetite.51 However, subdiaphragmatic vagotomy had no effect on GLP-1-induced acute activation of PKA in the brain, indicating that the vagus nerve is not involved in GLP-1RAs entering the brain.52 Interestingly, subphrenic vagus afferents can also attenuate the short-term appetite inhibitory effects of liraglutide and exendin-4, but their long-term effects on food intake do not depend entirely on vagus afferents.53 The above findings indicate that GLP-1RAs inhibit food intake and cause weight loss mainly by acting on different brain regions, which also supports the evidence of long-acting GLP-1RAs penetrating incomplete BBB in certain areas. GLP-1Rmediated transport occurs through circumventricular organs (CVOs) and maybe other parts of the hypothalamus via fenestrated capillaries and is partially dependent on tanycytemediated transport through certain localized compartments of the cerebrospinal fluid (CSF).54,55 Central administration of GLP-1RAs suppressed appetite, accompanied by increased expression of c-Fos in neurons within the PVN, amygdala, NTS, AP, LPB and ARC, which was consistent with the results of GLP-1R expression studies in the CNS.56 Decreased food intake and weight loss were observed with peripheral administration of GLP-1RAs, but inactivation of intestinal GLP-1 production did not interfere with food intake or weight control, suggesting that the GLP-1R-dependent signaling regulating appetite and body weight occurs in the CNS.50,57

Exendin-4, a bioactive peptide produced from Heloderma suspectum venom, is a 39-amino-acid peptide.58 Exendin-4 improved cognitive behavioral tests in Alzheimers disease patients by protecting the brain against abnormal insulin signaling.59 Kastin and Akerstrom established in a landmark study that peripherally injected Exendin-4 passed readily through the BBB, facilitated by its lipophilicity, rather than becoming trapped in the endothelial cell.60 According to multiple time regression analyses, exendin-4 passes directly through the BBB. Exendin-4 has been shown to easily cross the BBB, which is critical for Parkinsons disease treatment.61 In addition, Exendin-4 quickly enters the brain and brain microvascular endothelial cells via active ligands that bind to and activate GLP-1 receptors.52 Exenatide is based on exendin-4 structure.62 Numerous clinical trials established exenatides efficacy in individuals with Parkinsons disease, demonstrating that it entered the CNS via the BBB and exerted neuroprotective and neurorestorative effects.6365 Additionally, it was demonstrated that exendin-4 is also mediated by the adsorptive transcytosis across brain endothelial cells.66

On the other hand, Salamehs research indicates that lixisenatide can penetrate the BBB via adsorptive transcytosis.66 Lixisenatide has been demonstrated to pass the blood-brain barrier and exert neuroprotective effects in Alzheimers disease.67 Hunter and Holscher reported increased cAMP levels in the CNS at all dosages after 30 minutes and 3 hours of lixisenatide injection, which indicated the activation of the GLP-1 receptor, and presented persuasive evidence that lixisenatide crossed the BBB.68

Liraglutide is a GLP-1 agonist with neuroprotective properties in Alzheimers disease.69 It has demonstrated the ability to cross the BBB. The pharmacological concentration of GLP-1RA in the brain was proportional to the intraperitoneal injections, with 2.5, 25, or 250 nmol per kg of body weight protecting against impairment of recognition memory synaptic loss and degradation in the hippocampus of patients.68,70 Despite its varied ability to cross the BBB, liraglutide was more effective than exendin-4 in repairing the damage induced by 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine (MTPT).71 While these findings suggest that GLP-1RAs can reach brain tissue by passive diffusion across the BBB, other research has shown that liraglutide could only enter the brain by binding to the central GLP-1 receptor.

Dulaglutide is a GLP-1RA with a larger molecular weight, which may potentially cross a compromised BBB.72 However, there is no direct evidence proving that dulaglutide crosses the BBB.

In 2017, the US Food and Drug Administration (FDA) authorized semaglutide as the seventh clinically available GLP-1RA.44 The longer aliphatic chain in semaglutide, a long-acting formulation based on the structure of liraglutide, enhances hydrophobicity by altering the DPP-4 enzyme hydrolysis site with polyethylene glycol (PEG), allowing it to strongly bind to albumin. Semaglutide was detected within vascular endothelial cells and could not cross the BBB. According to the research by Gabery et al, semaglutide could bind to albumin and directly reach the brainstem, septal nucleus, and hypothalamus via CVOs, but showed no interaction with endothelial cells and could not cross the BBB. Interestingly, semaglutide seems to be able to pass through the tanycytes that line the ventricular wall or areas lacking a BBB.73

SGLT-2 is mainly expressed in the apical membranes of kidney segments 1 and 2 of the proximal convoluted tubules.74 A previous study has demonstrated that SGLT-2 is present in the central nervous system, including the brain parenchymal and the BBB.7577 SGLT-2 was shown to be expressed in ependymal cells and choroid plexus epithelial cells (CPE) in the brainstem, hypothalamus, periaqueductal grey (PAG), amygdala, and solitary nucleus of mice and humans.78

SGLT-2is are a novel class of diabetes medications and are well-known for their efficacy in the treatment of chronic heart failure in both diabetic and non-diabetic patients. RAAS is one of the most important arterial blood pressure regulators and plays a key role in cardiovascular and renal diseases. A study by Shin et al reported that dapagliflozin attenuated inflammatory and fibrotic markers.79 In addition to their anti-diabetic effects, SGLT-2is play a role in cardio-nephroprotection due to RAAS activation from their diuretic and sympathoinhibition effects.80 Phlorizin, the first SGLT-2i, is a naturally occurring chalcone compound discovered in apple bark in the 1850s by French researchers. It is a non-specific SGLT-1 and SGLT-2i that was not used as an anti-hyperglycemic medication due to gastrointestinal side effects until the chemical structure was modified in this decade. SGLT-2is are lipid soluble drugs with low molecular weight, as indicated by their chemical structures (Figure 3).

Figure 3 Chemical structure and molecule weight of SGLT-2 inhibitors. Dapagliflozin(2013) MF:C21H25ClO6 MW:408.88; Empagliflozin(2014) MF:C23H27ClO7, MW:450.91; Sotagliflozin(2019) MF:C21H25ClO5S MW:424.94; Ertugliflozin(2017) MF:C22H25ClO7 MW:436.88; Luseogliflozin(2014) MF:C23H30O6S MW:434.55; Tofogliflozin(2014) MF:C22H26O6 MW:386.44; Ipragliflozin(2014) MF:C21H21FO5S MW:404.45; Canagliflozin(2013) MF:C24H25FO5S MW:444.52.

Abbreviations: MF, molecular formula; MW, molecular weight.

Physicochemical properties, including molecular weight, pKa, LogPoct, HBA and HBD, are critical parameters related to the ability of drugs to cross the BBB. These properties can be obtained from the ChEMBL database, which is an open database that contains information on a large number of drug-like bioactive compounds: https://www.ebi.ac.uk/chembldb(Table 2).

Table 2 Physicochemical propertiesrelated to penetration capacity of the BBB of SGLT-2is.

Notably, given that SGLT-2 is expressed in the brain, which is consistent located with enhanced cFos expression induced by SGLT-2is, we hypothesize that SGLT-2is may cross the BBB via receptor-mediated transcytosis.76,81 In a recent study, we discovered that the SGLT-2i dapagliflozin might cross the BBB and interact with SGLT-2 in the brain.81 In addition to its hypoglycemic effect, the neuroprotective effect of SGLT-2is may be another evidence that it can cross the BBB. Dapagliflozin may enter the brain through impaired BBB, irrespective of its lipid-soluble properties, as evidenced by dramatically increased BBB permeability and disruption of tight junction between endothelial cells in Parkinsons disease.82 Empagliflozin improved cognitive performance in diabetic rats by lowering brain oxidative stress. In this context, the increase in cognitive function associated with empagliflozin and canagliflozin may also support the notion that these medicines are capable of penetrating the damaged BBB.83 Inflammation in the CNS of patients with diabetes or other chronic diseases may increase the permeability of the BBB, allowing SGLT-2is to pass through. El-Sahar et al examined dapagliflozins neuroprotective effect in rats with Huntingtons disease and discovered that it was capable of modulating aberrant neurotransmission. Other abnormal conditions in the rat striatum, such as apoptosis, glycolysis, and autophagy, may allow SGLT-2is to cross the BBB.84 On the other hand, some research shows that the neuroprotective effect of SGLT-2is is most likely caused by the increased native GLP-1 concentration and decreased corticosterone concentration following SGLT-2is administration.85

Dapagliflozin was the first SGLT-2i to be licensed as a commercially accessible drug by the US Food and Drug Administration in 2000. Our previous study found that dapagliflozin may act on the rostral ventrolateral medulla (RVLM) and affect the sympathetic outflow of sympathetic preganglionic neurons to the intermediolateral nucleus of the spinal cord (IML), thereby promoting parasympathetic activity. Dapagliflozin also inhibits SGLT-2 in mice and regulates central autonomic activity by stimulating neurons in the central nervous system and controls cardiovascular functions. SGLT-2 was localized to specific regions involved in autonomic control. Expression of c-Fos was significantly higher in major critical nuclei in the aforementioned regions in the mice group treated with dapagliflozin.81 Shaikh et al reported that dapagliflozin is a potent dual inhibitor of SGLT-2 and acetylcholinesterase, which could be used as the basis for future dual therapy for patients with diabetes and diabetes-related neurological disorders.86

In 2014, the drug empagliflozin (EMPA) was approved for the treatment of T2DM. Extensive investigation revealed that EMPA had been shown to have a neuroprotective impact on illnesses like Alzheimers disease and Parkinsons disease. In a recent study, EMPA was shown to traverse the damaged BBB and to improve ultrastructural remodeling of the neurovascular unit (NVU) and neuroglia in female diabetic mice.87 Entesar et al also confirmed that EMPA exerted neuroprotective effects in hyperglycemic rats.88 Increased expression of cerebral caspase-3 was observed in ischemia/reperfusion(I/R)-injured rats administered with oral EMPA, whereas apoptotic cells decreased, indicating that EMPA may help protect neurons. The researchers speculated that EMPA could cross through a compromised BBB and exert neuroprotective benefits. The above findings suggest that EMPA can enter areas with compromised BBB integrity (Figure 3).

Sotagliflozin, often known as a dual SGLT-1/SGLT-2 inhibitor, has the highest affinity for SGLT1 receptors but is not yet commonly used in diabetic patients as it is the newest SGLT-2is.89 In theory, sotagliflozin may have a greater neuroprotective effect than other SGLT-2is due to increased SGLT1 expression in the brain.90 Sotagliflozin should be able to penetrate the BBB via passive diffusion based on its lipid-soluble molecular structure. However, no current investigations have examined this concept.

Ertugliflozin was licensed for clinical usage in 2017 after it was demonstrated to decrease the risk of heart failure hospitalization (HHF).91 However, minimal research has been conducted on its BBB permeability. Based on physicochemical and polypharmacological data, ertugliflozin is likely unable to cross the BBB.92

Luseogliflozin is a selective SGLT-2 inhibitor that received marketing approval on March 24, 2014, for the treatment of T2DM.93 Many studies have shown that luseogliflozon could reverse cerebrovascular dysfunction and cognitive impairments in diabetic animals and elderly diabetics.94,95

The FDA authorized tofogliflozin for diabetic therapy in 2014. Takeda et al discovered that tofogliflozin could enhance food intake. They hypothesized that delivering tofogliflozin intracerebroventricularly (ICV) could stimulate food intake by acting directly on the CNS, whereas intraperitoneal administration showed no such effects.96 Tofogliflozin administered via ICV enhanced food intake, indicating the presence of SGLT-2 in the brain. However, the BBB permeability of tofogliflozin remains unknown (Figure 4). Additionally, c-fos (a neuronal activation indicator) was significantly enhanced in the arcuate nucleus (ARC) within 23 hours after tofogliflozin treatment, suggesting that tofogliflozin could permeate these regions and bind to receptors on the ARC.

Figure 4 Factors influencing the blood-brain barrier permeability and possible treatment strategy. Increased oxidative stress, decreased VEGF levels and increased matrix metalloproteinase (MMP) activity result in basement membrane expansion, pericyte disintegration, increased paracellular diffusion, and decreased tight junction protein expression. In addition, fatty acids induce inflammatory responses, which reduce protein expression in BBB microvessels and increase BBB apoptosis, resulting in increased BBB permeability. Evidence shows that modification of the gut microbiota with prebiotics or probiotics and high-fiber diets improve systemic inflammation, restoring BBB integrity. In addition, treatment with GLP-1RAs and SGLT-2is inhibit the activation of inflammatory factors and attenuate oxidative stress via blood glucose and fatty acids reduction.

Ipraglifozin has a five-membered ring structure with low selectivity for SGLT-2 and was first approved in Japan in 2014. Destruction of mitochondrial ETC leads to increased ROS production, which triggers matrix metalloproteinases (MMP) induction, ultimately leading to compromised BBB integrity. Studies have shown that ipragliflozin can reduce body fat mass and alleviate mitochondrial dysfunction.97,98 Therefore, it has the effect of both anti-obesity, and anti-oxidant to improve BBB permeability. However, there are no adequate studies revealing the mechanism of ipragliflozin and its ability to cross the BBB.

In 2013, the FDA approved canagliflozin as an anti-diabetic medicine. Canagliflozin (CAN) has been demonstrated to bind to both AChE and SGLT-2, inhibiting both enzymes simultaneously.99 Its effects on neurotransmitters may also be linked to the activation of its receptors. Therefore, canagliflozin may potentially exert direct effects on CNS SGLT-2. Although a study found that canagliflozin had a cognitive protective effect in high-fat diet mice by decreasing obesity-related neuroinflammation,100 there is no conclusive evidence that it can cross the BBB. Due to its lipophilicity and low molecular weight, CAN could partially cross the blood-brain barrier via passive diffusion.101

DM and obesity influence BBB integrity through a number of mechanisms (Figure 4). In our previous studies, hyperglycemia and inflammation were shown to lead to pathological capillary changes in the retina.102 The current findings in the diabetic brain suggest a striking similarity, indicating a common pathophysiological mechanism between the retina and the brain microvessels. Magnetic resonance (MR) brain imaging with intravenous gadolinium (Gd) diethylenetriamine pentaacetic acid revealed increased BBB permeability in diabetic patients (Gd-DTPA). IgG has been demonstrated to leak into the brain interstitium of DMHC pigs via the permeable BBB.18,19 According to recent research, chronic hyperglycemic exposure resulted in compromised BBB integrity, characterized by altered tight junctions, thickened basement membrane, capillary density changes, and pericyte deterioration. In addition, pericyte loss caused by the Krebs cycle processing of excessive glucose resulted in increased oxidative stress. Furthermore, advanced glycation end products activate vascular endothelial growth factor (VEGF), which increases matrix metalloproteinase synthesis and alters tight junction proteins. In diabetic patients and rodents, elevated plasma matrix metalloproteinase (MMP) activity lowered BBB tight junction protein synthesis and increased BBB permeability.103105 Microvascular diseases may lead to BBB decomposition, allowing serum-derived components to flow into the brain parenchyma.106 Hyperglycemia also induces the production of reactive oxygen species107 and increases pro-inflammatory cytokines and chemokines in many cells.108,109

Obesity is considered a low-grade chronic inflammation and has already been associated with functional alterations in the BBB (Figure 4). Dietary components such as fatty acids stimulate lipopolysaccharide (LPS) receptors and toll-like receptor 4(TLR4), triggering an inflammatory cascade that releases inflammatory mediators(TNF-, IL-1, IL-6). Studies have shown a decrease in energy consumption in BBB microvessels and a suppression of expression of 47 types of BBB proteins in diet-induced obesity (DIO) mice. Additionally, the activities of enzymes, transporters, and cytoskeleton proteins on BBB microvessels are preferentially suppressed in these DIO animals.110,111 Moreover, a study indicated that a high-energy (HE) diet is related to increased BBB permeability as elevations in peripheral proinflammatory cytokines compromise BBB function in specific areas of the brain.112

Decreased BBB permeability and upregulated expression of tight junction proteins were observed in germ-free adult mice.113 Intestinal flora disorders may compromise the BBB integrity due to the decreased expression of tight junction proteins.114 Disorders of the gut-microbial flora may cause systemic inflammation by destroying the intestinal epithelial barrier and introducing toxic by-products in the blood circulation.115 In humans, changes in the composition of gut-microbial flora are associated with obesity and T2DM.116,117 Furthermore, increasing evidence indicates that modifying the microbiota with prebiotics or probiotics benefits the host, while high-fiber diets also induce faster resolution of inflammatory responses.118,119

Temporary disruption of BBB has been widely studied as a prevalent approach for delivering drugs into the CNS from the circulatory system.120 BBB malfunction is a hallmark of a variety of neurological disorders, including Alzheimers disease, Parkinsons disease, cerebral ischemia, stroke, hyperlipidemia, and diabetes.121 GLP-1RAs and SGLT-2is could cross the temporarily disrupted BBB in the brains of experimental animals and individuals with neurological disorders, diabetes, and obesity via a variety of transmembrane routes. GLP-1RAs and SGLT-2is both have the ability to penetrate damaged basement membranes and tight junctions (Figure 5).

Figure 5 (A) Normal BBB: GLP-1RAs can cross the normal BBB by receptor-mediated transport and passive diffusion, but whether SGLT-2is may cross the compromised BBB via passive diffusion is still being investigated. (B) Impaired BBB.

Although providing a first glimpse at the capacity of GLP-1RAs and SGLT-2is to traverse the BBB, the current review has not disclosed the specific signaling mechanisms, particularly for SGLT-2is. In addition, it is yet unknown how the physical and chemical features of SGLT-2is regulate their transportation in the CNS. The interaction of GLP-1RAs and SGLT-2is with the blood-brain barrier (BBB) requires additional research and direct evidence at the molecular or cellular level.

In conclusion, the preclinical and clinical studies demonstrated that GLP-1RAs and SGLT-2is act directly or indirectly on their receptors by crossing the BBB. Thus, they can not only lower glucose levels but also be applied in the treatment of CNS diseases. Central administration of GLP-1RAs or SGLT-2is could increase the expression of c-Fos in neurons within the PVN, amygdala, NTS, AP, and ARC,56,96 which was consistent with the expression of GLP-1R/SGLT-2 in the whole CNS.30,31,7577 This may be considered evidence that these drugs could pass through the BBB and activate the neurons in these nuclei. Some of the GLP-1RAs have been proven to cross through the BBB via passive diffusion.34,46,48,68 In addition, GLP-1RAs could cross the BBB via the GLP-1 receptor-mediated uptake mechanism.52 Liraglutide has access to specific areas of the brain associated with appetite regulation and was measured in selected CVOs and specific hypothalamic regions, of which the signal was GLP-1R-dependent.54 Adsorption transcytosis could be another mechanism involved in exendin-4 and lixisenatide crossing the BBB.66 Semaglutide may be unable to cross the regular BBB directly but could bind to serum albumin and pass through the tanycytes lining the ventricle wall.73 In summary, peripheral administration of GLP-1RAs either acts directly on the hypothalamus and hindbrain, which lack BBB, or directly crosses the BBB into CNS, which are then projected to other key feeding areas of the brain (Figure 6). Notably, SGLT-2is are medications of small molecular weight, with lower LogPoct than the permeation prediction index of BBB (listed in Table 2). SGLT-2is activated c-Fos expression in the CNS, and the relationship between the chemical structure/properties of SGLT-2is and BBB could be interpreted as evidence for penetrating the BBB.81 Due to the increased permeability of the BBB in hyperglycemia and obesity, SGLT-2is and GLP-1RAs are likely to pass through the compromised BBB.18 As such, the prospects of comprehensively elucidating the mechanism of SGLT-2is and GLP-1RAs interacting with BBB are promising, through which corresponding strategies for the prevention and treatment of DM, AD, PD and CVD can be developed.

Figure 6 The arcuate nucleus (ARC) in the hypothalamus, the area postrema (AP) and the Nucleus of Solitary (NTS) in the brainstem are 3 examples of CVOs that are not protected by an effective blood-brain barrier. Once GLP-1RAs enter the bloodstream by subcutaneous injection, they can activate ARC hypothalamic POMC/CART neurons, which subsequently stimulate sympathetic efferent output, controlling insulin secretion. It is unclear if GLP-1-RAs stimulate the pre-vertebral ganglia directly. GLP-1RAs also activate GLP-1 receptors on the surface of pancreatic cells, resulting in the conversion of adenosine to cyclic adenosine phosphate (cAMP) in islet cells through conjugation of active G protein with adenosine cyclase. As cAMP levels rise, the pancreatic beta cell membrane depolarizes, which promotes insulin secretion. Further work is required to determine whether SGLT-2is may cross the BBB and exert similar effects on the brain.

This work was supported by the Project of Key Medical Discipline of Pudong Hospital of Fudan University (Zdxk2020-11), Project of Key Medical Specialty and Treatment Center of Pudong Hospital of Fudan University (Zdzk2020-24), Integrative Medicine special fund of Shanghai Municipal Health Planning Committee (ZHYY- ZXYJHZX-2-201712), Special Department Fund of the Pudong New Area Health Planning Commission (PWZzk2017-03), Outstanding Leaders Training Program of Pudong Health Bureau of Shanghai (PWR12014-06), Pudong New Area Clinical Plateau Discipline Project (PWYgy-2021-03), the Natural Science Foundation of China (21675034), National Natural Science Foundation of China (81370932), Shanghai Natural Science Foundation (19ZR1447500) and Education Funding in Wenzhou Medical University (JG2021197).

The authors report no conflicts of interest in this work.

1. Zheng Y, Ley SH, Hu FB. Global aetiology and epidemiology of type 2 diabetes mellitus and its complications. Nat Rev Endocrinol. 2018;14:8898. doi:10.1038/nrendo.2017.151

2. Bluher M. Obesity: global epidemiology and pathogenesis. Nat Rev Endocrinol. 2019;15:288298. doi:10.1038/s41574-019-0176-8

3. Filippo CD, Cuzzocrea S, Rossi F, Marfella R, DAmico M. Oxidative stress as the leading cause of acute myocardial infarction in diabetics. Cardiovasc Drug Rev. 2006;24:7787. doi:10.1111/j.1527-3466.2006.00077.x

4. Alloubani A, Saleh A, Abdelhafiz I. Hypertension and diabetes mellitus as a predictive risk factors for stroke. Diabetes Metab Syndr. 2018;12:577584. doi:10.1016/j.dsx.2018.03.009

5. Gong M, Wen S, Nguyen T, et al. Converging relationships of obesity and hyperuricemia with special reference to metabolic disorders and plausible therapeutic implications. Diabetes Metab Syndr Obes. 2020;13:943962. doi:10.2147/DMSO.S232377

6. Meier JJ. GLP-1 receptor agonists for individualized treatment of type 2 diabetes mellitus. Nat Rev Endocrinol. 2012;8:728742. doi:10.1038/nrendo.2012.140

7. Kanoski SE, Fortin SM, Arnold M, Grill HJ, Hayes MR. Peripheral and central GLP-1 receptor populations mediate the anorectic effects of peripherally administered GLP-1 receptor agonists, liraglutide and exendin-4. Endocrinology. 2011;152(8):31033112. doi:10.1210/en.2011-0174

8. Gallo LA, Wright EM, Vallon V. Probing SGLT2 as a therapeutic target for diabetes: basic physiology and consequences. Diab Vasc Dis Res. 2015;12:7889. doi:10.1177/1479164114561992

9. Brown RE, Gupta N, Aronson R. Effect of dapagliflozin on glycemic control, weight, and blood pressure in patients with type 2 diabetes attending a specialist endocrinology practice in canada: a retrospective cohort analysis. Diabetes Technol Ther. 2017;19:685691. doi:10.1089/dia.2017.0134

10. Cai X, Yang W, Gao X, et al. The association between the dosage of SGLT2 inhibitor and weight reduction in type 2 diabetes patients: a meta-analysis. Obesity. 2018;26:7080. doi:10.1002/oby.22066

11. Rosenstock J, Frias J, Pall D, et al. Effect of ertugliflozin on glucose control, body weight, blood pressure and bone density in type 2 diabetes mellitus inadequately controlled on metformin monotherapy (VERTIS MET). Diabetes Obes Metab. 2018;20:520529. doi:10.1111/dom.13103

12. Khat DZ, Husain M. Molecular mechanisms underlying the cardiovascular benefits of SGLT2i and GLP-1RA. Curr Diab Rep. 2018;18:45. doi:10.1007/s11892-018-1011-7

13. Marso SP, Bain SC, Consoli A, et al. Semaglutide and cardiovascular outcomes in patients with type 2 diabetes. N Engl J Med. 2016;375:18341844. doi:10.1056/NEJMoa1607141

14. Zelniker TA, Wiviott SD, Raz I, et al. SGLT2 inhibitors for primary and secondary prevention of cardiovascular and renal outcomes in type 2 diabetes: a systematic review and meta-analysis of cardiovascular outcome trials. Lancet. 2019;393:3139. doi:10.1016/S0140-6736(18)32590-X

15. Wen S, Nguyen T, Gong M, et al. An overview of similarities and differences in metabolic actions and effects of central nervous system between glucagon-like peptide-1 receptor agonists (GLP-1RAs) and sodium glucose co-transporter-2 inhibitors (SGLT-2is). Diabetes Metab Syndr Obes. 2021;14:29552972. doi:10.2147/DMSO.S312527

16. Zhou L, Sutton GM, Rochford JJ, et al. Serotonin 2C receptor agonists improve type 2 diabetes via melanocortin-4 receptor signaling pathways. Cell Metab. 2007;6:398405. doi:10.1016/j.cmet.2007.10.008

17. Abbott NJ, Patabendige AA, Dolman DE, Yusof SR, Begley DJ. Structure and function of the blood-brain barrier. Neurobiol Dis. 2010;37:1325. doi:10.1016/j.nbd.2009.07.030

18. Acharya NK, Levin EC, Clifford PM, et al. Diabetes and hypercholesterolemia increase blood-brain barrier permeability and brain amyloid deposition: beneficial effects of the LpPLA2 inhibitor darapladib. J Alzheimers Dis. 2013;35:179198. doi:10.3233/JAD-122254

19. Starr JM, Wardlaw J, Ferguson K, MacLullich A, Deary IJ, Marshall I. Increased bloodbrain barrier permeability in type II diabetes demonstrated by gadolinium magnetic resonance imaging. J Neurol Neurosurg Psychiatry. 2003;74:7076. doi:10.1136/jnnp.74.1.70

20. Mauro C, De Rosa V, Marelli-Berg F, Solito E. Metabolic syndrome and the immunological affair with the blood-brain barrier. Front Immunol. 2014;5:677. doi:10.3389/fimmu.2014.00677

21. Miller AA, Spencer SJ. Obesity and neuroinflammation: a pathway to cognitive impairment. Brain Behav Immun. 2014;42:1021. doi:10.1016/j.bbi.2014.04.001

22. Pan Y, Nicolazzo JA. Impact of aging, Alzheimers disease and Parkinsons disease on the blood-brain barrier transport of therapeutics. Adv Drug Deliv Rev. 2018;135:6274. doi:10.1016/j.addr.2018.04.009

23. Pun PB, Lu J, Moochhala S. Involvement of ROS in BBB dysfunction. Free Radic Res. 2009;43:348364. doi:10.1080/10715760902751902

24. Terami N, Ogawa D, Tachibana H, et al. Long-term treatment with the sodium glucose cotransporter 2 inhibitor, dapagliflozin, ameliorates glucose homeostasis and diabetic nephropathy in db/db mice. PLoS One. 2014;9:e100777. doi:10.1371/journal.pone.0100777

25. Abbott NJ. Dynamics of CNS barriers: evolution, differentiation, and modulation. Cell Mol Neurobiol. 2005;25:523. doi:10.1007/s10571-004-1374-y

26. Alexander JJ. Blood-brain barrier (BBB) and the complement landscape. Mol Immunol. 2018;102:2631. doi:10.1016/j.molimm.2018.06.267

27. Norsted E, Gomuc B, Meister B. Protein components of the blood-brain barrier (BBB) in the mediobasal hypothalamus. J Chem Neuroanat. 2008;36:107121. doi:10.1016/j.jchemneu.2008.06.002

28. Bagchi S, Chhibber T, Lahooti B, et al. In-vitro blood-brain barrier models for drug screening and permeation studies: an overview. Drug Des Devel Ther. 2019;13:35913605. doi:10.2147/DDDT.S218708

29. Gawdi R, Emmady PD, Jindal C. Physiology, blood brain barrier. J Thorac Dis. 2021;13(10):56175626. doi:10.21037/jtd-21-1018

30. Jensen CB, Pyke C, Rasch MG, et al. Characterization of the glucagon like peptide-1 receptor in male mouse brain using a novel antibody and in situ hybridization. Endocrinology. 2018;159(2):665675. doi:10.1210/en.2017-00812

31. Farr OM, Sofopoulos M, Tsoukas MA, et al. GLP-1 receptors exist in the parietal cortex, hypothalamus and medulla of human brains and the GLP-1 analogue liraglutide alters brain activity related to highly desirable food cues in individuals with diabetes: a crossover, randomised, placebo-controlled trial. Diabetologia. 2016;59:954965. doi:10.1007/s00125-016-3874-y

32. Holscher C. Novel dual GLP-1/GIP receptor agonists show neuroprotective effects in Alzheimers and Parkinsons disease models. Neuropharmacology. 2018;136:251259. doi:10.1016/j.neuropharm.2018.01.040

33. Lv M, Xue G, Cheng H, et al. The GLP-1/GIP dual-receptor agonist DA5-CH inhibits the NF-kappaB inflammatory pathway in the MPTP mouse model of Parkinsons disease more effectively than the GLP-1 single-receptor agonist NLY01. Brain Behav. 2021;11:e2231. doi:10.1002/brb3.2231

34. McGovern SF, Hunter K, Holscher C. Effects of the glucagon-like polypeptide-1 analogue (Val8)GLP-1 on learning, progenitor cell proliferation and neurogenesis in the C57B/16 mouse brain. Brain Res. 2012;1473:204213. doi:10.1016/j.brainres.2012.07.029

35. Bailey J, Barrett A, Coucha M, Abdelsaid MA. Abstract P729: glp-1 receptor nitration contributes to brain pericytes dysfunction in diabetes. Stroke. 2021;52:AP729AP729. doi:10.1161/str.52.suppl_1.P729

36. Fortin SM, Lipsky RK, Lhamo R, et al. GABA neurons in the nucleus tractus solitarius express GLP-1 receptors and mediate anorectic effects of liraglutide in rats. Sci Transl Med. 2020;12. doi:10.1126/scitranslmed.aay8071

37. Vanlandewijck M, He L, Mae MA, et al. A molecular atlas of cell types and zonation in the brain vasculature. Nature. 2018;554:475480. doi:10.1038/nature25739

38. Bhavsar S, Mudaliar S, Cherrington A. Evolution of Exenatide as a Diabetes Therapeutic. Curr Diabetes Rev. 2013;9:161193. doi:10.2174/1573399811309020007

39. Werner U, Haschke G, Herling AW, Kramer W. Pharmacological profile of lixisenatide: a new GLP-1 receptor agonist for the treatment of type 2 diabetes. Regul Pept. 2010;164:5864. doi:10.1016/j.regpep.2010.05.008

40. Tang C, Li Q, Deng X, et al. Discovery of lixisenatide analogues as long-acting hypoglycemic agents using novel peptide half-life extension technology based on mycophenolic acid. RSC Adv. 2020;10:1208912104. doi:10.1039/D0RA01002B

41. Zhang YL, Zhou C, Li XF, et al. Beinaglutide showed significant weight-loss benefit and effective glycaemic control for the treatment of type 2 diabetes in a real-world setting: a 3-month, multicentre, observational, retrospective, open-label study. Obes Sci Pract. 2019;5:366375. doi:10.1002/osp4.342

42. Buse JB, Rosenstock J, Sesti G, et al. Liraglutide once a day versus exenatide twice a day for type 2 diabetes: a 26-week randomised, parallel-group, multinational, open-label trial (LEAD-6). Lancet. 2009;374:3947. doi:10.1016/S0140-6736(09)60659-0

43. Geiser JS, Heathman MA, Cui X, et al. Clinical pharmacokinetics of dulaglutide in patients with type 2 diabetes: analyses of data from clinical trials. Clin Pharmacokinet. 2016;55:625634. doi:10.1007/s40262-015-0338-3

44. Kalra S, Sahay R. A review on semaglutide: an oral glucagon-like peptide 1 receptor agonist in management of type 2 diabetes mellitus. Diabetes Ther. 2020;11:19651982. doi:10.1007/s13300-020-00894-y

45. Jacobsen LV, Flint A, Olsen AK, Ingwersen SH. Liraglutide in type 2 diabetes mellitus: clinical pharmacokinetics and pharmacodynamics. Clin Pharmacokinet. 2016;55:657672. doi:10.1007/s40262-015-0343-6

46. Kastin AJ, Akerstrom V, Pan W. Interactions of glucagon-like peptide-1 (GLP-1) with the blood-brain barrier. J Mol Neurosci. 2002;18:714. doi:10.1385/JMN:18:1-2:07

47. Zhou L, Williams T, Lachey JL, et al. Serotonergic pathways converge upon central melanocortin systems to regulate energy balance. Peptides. 2005;26(10):17281732. doi:10.1016/j.peptides.2004.12.028

48. Zhou L, Yueh CY, Lam DD, et al. Glucokinase inhibitor glucosamine stimulates feeding and activates hypothalamic neuropeptide Y and orexin neurons. Behav Brain Res. 2011;222:274278. doi:10.1016/j.bbr.2011.03.043

49. Heisler LK, Jobst EE, Sutton GM, et al. Serotonin reciprocally regulates melanocortin neurons to modulate food intake. Neuron. 2006;51:239249. doi:10.1016/j.neuron.2006.06.004

50. Brierley DI, Holt MK, Singh A, et al. Central and peripheral GLP-1 systems independently suppress eating. Nature Metabol. 2021;3:258273. doi:10.1038/s42255-021-00344-4

51. Plamboeck A, Veedfald S, Deacon CF, et al. The effect of exogenous GLP-1 on food intake is lost in male truncally vagotomized subjects with pyloroplasty. Am J Physiol Gastrointest Liver Physiol. 2013;304:G1117G1127. doi:10.1152/ajpgi.00035.2013

52. Fu Z, Gong L, Liu J, et al. Brain endothelial cells regulate glucagon-like peptide 1 entry into the brain via a receptor-mediated process. Front Physiol. 2020;11:555. doi:10.3389/fphys.2020.00555

53. Labouesse MA, Stadlbauer U, Weber E, et al. Vagal afferents mediate early satiation and prevent flavour avoidance learning in response to intraperitoneally infused exendin-4. J Neuroendocrinol. 2012;24(12):15051516. doi:10.1111/j.1365-2826.2012.02364.x

54. Secher A, Jelsing J, Baquero AF, et al. The arcuate nucleus mediates GLP-1 receptor agonist liraglutide-dependent weight loss. J Clin Invest. 2014;124:44734488. doi:10.1172/JCI75276

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The Relationship Between the Blood-Brain-Barrier and the Central Effec | DMSO - Dove Medical Press

A rare genetic mutation may help explain why some families are more susceptible to diabetes and kidney failure, according to a new study led by University of Utah health scientists. They say the discovery, made within several generations of the same family, could eventually lead to better treatments for these conditions among a range of patients, whether they have inherited the mutation or not.

In the past, we have seen sporadic cases here and there, but this is the first family to demonstrate that this mutation may be inherited. Marcus Pezolesi, PhD, MPH, corresponding author of the study and U of U Health associate professor of internal medicine in the department of nephrology, says. What is exciting is that treatments are being developed that can improve this condition not only within this family but in the vast spectrum of patients with diabetes at risk of kidney disease.

The study, conducted in collaboration with the Joslin Diabetes Center and Harvard Medical School in Boston, appears in NPJ Genomic Medicine,

Scientists have long known that people who are overweight or obese produce less adiponectin, a hormone that promotes insulin sensitivity, inhibits cell death, and reduces inflammation. As a result, these individuals have a higher risk of developing insulin resistance, type 2 diabetes, kidney disease, and other life-threatening conditions.

To determine whether there may be a genetic cause for diabetic kidney disease, Pezolsi and his colleagues analyzed DNA samples from 14 members of a family collected at the Joslin Diabetes Center. In all, six family members over three generations had diabetes and end-stage kidney disease.

Digging deeper, the researchers used whole-genome sequencing to isolate a defect in a gene called ADIPOQ, which encodes the adiponectin protein. The mutation shortens the gene, disrupting its ability to produce the hormone, which breaks down ceramides, a fatty substance similar to cholesterol. As a result, people with the mutation have higher levels of ceramides. Previous studies suggest that ceramides are a driving force behind the onset of type 2 diabetes and may contribute to diabetic kidney disease.

In laboratory studies of human embryonic kidney cells, researchers found that just one copy of this mutation was able to reduce adiponectin production. Researchers determined that this mutation occurs in about one out of every 57,000 people.

Overall, carriers of the genetic mutation had approximately 85% less adiponectin and 30% higher levels of ceramides circulating in their blood relative to non-carriers within the same family, who were used as a control group.

Whats most exciting to me is that this discovery allows us to confirm decades of research in animals, says William Holland, PhD, study co-corresponding author and U Health Associate Professor of Nutrition and Integrative Medicine. physiology. The biological effects of adiponectin in regulating insulin sensitivity, glucose tolerance and ceramide levels are well established in rats, and the present study demonstrates that loss of adiponectin impairs metabolic health in humans.

Although the study was conducted in the same family, Holland says, its findings could have broad implications for the diagnosis and treatment of these conditions in many people. We can use these findings as a starting point for the development of personalized drugs that mimic the beneficial effects of adiponectin and reduce the risk of diabetes and kidney disease, he says.

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Detection Of Rare Genetic Mutation In A Family Could Lead To Better Diabetes Treatment - Nation World News

image:Joseph D. Buxbaum, PhD, Director of the Seaver Autism Center for Research and Treatment at Mount Sinai view more

Credit: Mount Sinai Health System

A new study of genes underlying neurodevelopmental differences has uncovered more than 70 that are very strongly associated with autism and more than 250 with strong links to the condition. The analysis is the largest of its kind to date and includes more than 150,000 participants, 20,000 of whom have been diagnosed with autism.

The results offer the most comprehensive look yet at diverse forms of genetic variation in autism and in more broadly defined neurodevelopmental conditions. The insights shed light on the molecular roots of brain development and neurodiversity, and provide new avenues for future research on the biology of autism.

The findings result from a collaboration involving scientists and datasets from the Autism Sequencing Consortium, the Simons Foundation Powering Autism Research initiative, the Lundbeck Foundation Initiative for Integrative Psychiatric Research, the Population-Based Autism Genetics and Environmental Study, and the Center for Common Disease Genomics at the Broad Institute of the Massachusetts Institute of Technology and Harvard. The work is the culmination of an investment several years ago by these consortia to conduct large-scale genetic analysis for neurodevelopmental conditions and share these datasets on autism.

The new work appears in Nature Genetics, alongside three related studies that use some of the same data to advance the understanding of the genetic basis of autism.

We know that many genes, when mutated, contribute to autism and in this unprecedented study, we were able to bring together multiple types of mutations in a wide array of samples to get a much richer sense of the genes and genetic architecture involved in autism and other neurodevelopmental conditions. This is significant in that we now have more insights as to the biology of the brain changes that underlie autism and more potential targets for treatment, said co-senior author Joseph D. Buxbaum, PhD, Director of theSeaver Autism Center for Research and Treatmentat Mount Sinai, and Professor of Psychiatry, Neuroscience, and Genetics and Genomic Sciences, at the Icahn School of Medicine at Mount Sinai.

In an analysis led by co-first author Minshi Peng, then a graduate student in the lab of co-senior author Kathryn Roeder, PhD, a professor of statistics and life sciences at Carnegie Mellon University, the scientists examined the expression, or activity levels, of the genes they uncovered in developing human neurons. They learned that genes linked predominantly to developmental delay tend to be active in early neuronal development, whereas autism-related genes tend to play a role in more mature neurons. Furthermore, in an analysis of more than 20,000 samples from individuals with schizophrenia, the researchers found that genes that are strongly associated with autism were also more likely to be associated with genes that increase risk for schizophrenia.

These analyses indicatethat there are shared genetic risk factors between autism and other neurological and psychiatric disorders, Dr. Buxbaum said.

Our discoveries were enabled not only by very large-scale, rich data collections in autism research and population genetic studies, but also by newly developed analysis methods, allowing us to explore the genetic roots of neurodevelopmental variability in new ways. In addition to the massive gene discovery efforts in the field, we are beginning to make inroads into understanding where, when, and how these genes exert their effects during neurodevelopment, said co-senior author Michael Talkowski, PhD, institute member at the Broad and director of the Center for Genomic Medicine at Massachusetts General Hospital.

Based on the study findings, Dr. Buxbaum said a precision medicine approach to autism would benefit patients, as treatments that work for individuals carrying a mutation in one gene may not work in other individuals carrying a mutation in a different gene.

A critical takeaway is that autism has many genetic mutations driving it and thus genetic testing is warranted, not just for the benefit of families and individuals at risk for autism spectrum disorder, but also to drive development of therapeutics, said Dr. Buxbaum. The more we can advance therapeutics, based on the targets identified in these genetic findings, the more people we have the potential to help, which could have a significant impact in addressing autism and developmental delay worldwide.

Additional co-senior authors on the study include Mark Daly, PhD (Broad and Center for Genomic Medicine at Massachusetts General Hospital), Bernie Devlin, PhD (University of Pittsburgh School of Medicine), and Stephan Sanders,PhD (University of California, San Francisco).Additional co-first authors include Harrison Brand, PhD, an assistant professor in neurology at Massachusetts General Hospital and Harvard Medical School; Jack Fu, a postdoctoral fellow in the Talkowski lab; and Kyle Satterstrom, a computational biologist in the Daly lab.

About Mount Sinai Health SystemThe Mount Sinai Health System is one of the largest academic medical systems in the New York metro area, with more than 43,000 employees working across eight hospitals, over 400 outpatient practices, over 300 labs, a school of nursing, and a leading school of medicine and graduate education. Mount Sinai advances health for all people, everywhere, by taking on the most complex health care challenges of our time discovering and applying new scientific learning and knowledge; developing safer, more effective treatments; educating the next generation of medical leaders and innovators; and supporting local communities by delivering high-quality care to all who need it.

Through the integration of its hospitals, labs, and schools, Mount Sinai offers comprehensive health care solutions from birth through geriatrics, leveraging innovative approaches such as artificial intelligence and informatics while keeping patients medical and emotional needs at the center of all treatment.

About Seaver Autism Center for Research and Treatment at Mount SinaiThe Seaver Autism Center for Research and Treatment at Mount Sinai conducts progressive research studies to enhance the diagnosis of autism and related disorders, discover the biological causes of those disorders, and develop and disseminate breakthrough treatments. With a vision to be the international leaders for precision medicine in autism and related disorders, the Center bridges the gap between new discoveries in basic science and enhanced care, while ensuring the community is aware of new and improved approaches to caring for people with autism. The Seaver Autism Center was founded through the generous support of the Beatrice and Samuel A. Seaver Foundation.

For more information, visitwww.seaverautismcenter.org, or find us on Facebook, Twitter and Instagram.

The Autism Sequencing ConsortiumCo-founded by Dr. Buxbaum in 2010, the ASC was first funded by the Beatrice and Samuel A. Seaver Foundation and the Seaver Autism for Research and Treatment at Mount Sinai and subsequently continuously funded by the National Institute of Mental Health for almost a decade. The groups research has gained additional support over the past decade from the Simons Foundation for Autism Research Initiative, the National Human Genome Research Institute, sand the National Institute of Child Health and Human Development.

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Data/statistical analysis

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'Rare coding variation provides insight into the genetic architecture and phenotypic context of autism

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Study of more than 150,000 people identifies - EurekAlert

Inflammation. You've no doubt come across this nutrition buzzword. And like a lot of folks, you may not fully understand what it means or why it's such a hot topic. So, before getting into the worst eating habits that cause inflammation and may speed up aging, let's get solid on what inflammation really is.

Whether you're stung by a bee or burn your hand on the stove, your body has an immune response that fends off toxins, pathogens, and infections, causing short-term inflammation in the process.

The dark side of inflammation is when it becomes chronic and simmers in the background, the swelling and heat never abating because your body keeps sending out inflammatory cells to fight even when there's no invader.

This type of long-term, low-grade inflammation can damage tissues and joints. "You may even notice that your skin ages faster when you're constantly inflamed as inflammation can break down collagen and elastin, which are responsible for keeping your skin looking young and supple," says Dr. Rene Armenta, a surgeon with Renew Bariatrics.

Months and years of chronic inflammation may initiate such inflammatory diseases as cardiovascular disease, cancer, type 2 diabetes, kidney disease, autoimmune disorders, and non-alcoholic fatty liver disease, according to research published in Nature Medicine. These inflammatory diseases and disorders are associated with aging.

Eating foods with anti-inflammation properties is part of a two-prong approach to avoiding aging-associated diseases. The other is ditching the following worst types of eating habits that may trigger inflammation and accelerate aging.

This is an unhealthy habit you'll want to break to avoid chronic inflammation. "Fruits like berries and oranges and green leafy vegetables like spinach and kale provide the vitamins, minerals, and antioxidants we need to help keep our immune systems healthy and strong, which is essential especially as you age," says medical review board member Amy Goodson, MS, RD, a registered dietitian and the author of The Sports Nutrition Playbook. "Only 1 in 10 people eat the recommended amounts, which means 90% of us can do a better job."

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The high temperatures needed to fry foods can create harmful compounds called Advanced Glycation End Products (AGEs) that accumulate in the body as we age.

"Foods such as cooked red meat and refined carbohydrates like white bread contain AGEs," says Johna Burdeos, RD, owner of Dietitian Johna. "Consuming too much of these foods can result in cellular damage and inflammation, which can speed up the aging process and increase the risk of insulin resistance and type 2 diabetes. The inflammatory response in the skin is seen in visible signs of weakened skin elasticity, like wrinkles, puffiness, and acne."

RELATED:The 11 Worst Foods Damaging Your Skin, Say Dermatologists

Processed meats like cold cuts, bacon, hot dogs, and junk foods like candy bars, cookies, sugary drinks, potato chips, ice cream, and fast foods are not the healthiest things to eat. Research suggests these ultra-processed foods, the hallmark of what's known as the Western Diet, can disrupt the delicate balance of healthy and unhealthy microbes in the gut or microbiome.

"When processed foods alter the bacteria that live in our gut, this triggers an altered immune response leading to chronic inflammation," says Kathryn Piper, RDN, LD, of The Age-Defying Dietitian. "Diabetes, heart disease, and dementia have been linked to chronic inflammation."

The remedy for an unhealthy microbiome is avoiding ultra-processed foods and making a habit of getting more dietary fiber, ideally 25 to 38 grams per day from foods like whole grains, fruits, vegetables, nuts, seeds, beans, lentils, and legumes, says Goodson.

"Very few people eat enough fiber, but if you want to age gracefully with positive gut health and a healthy cholesterol, fiber is the key," says Goodson. "Make your goal to get 4 to 6 grams of fiber at every meal and snack throughout the day."

Drinking any alcohol may increase inflammation in your body, and excessive alcohol intake definitely increases your risk of chronic low-grade inflammation among other health hazards, says Piper.

"If you drink, limit your consumption to the recommended less than 1 alcoholic beverage per day for women and less than 2 drinks per day for men," she says.

RELATED:The Lifestyle Habits That Slow Down Aging, From a 100-Year-old Neurologist

Gluten is a protein found in wheat and other grains, which means it shows up in bread, pizza crust, pasta, baked goods, and cereals. Although many people digest gluten without issue, people who are sensitive to gluten (a condition called nonceliac gluten sensitivity) experience a different type of immune response that causes an inflammatory effect, according to a 2020 study in Gastroenterology.6254a4d1642c605c54bf1cab17d50f1e

"If someone experiences gut issues, has been diagnosed with an autoimmune disease, or has had unexplained chronic symptoms that put them on the path to an autoimmune disease or another serious diagnosis, then going gluten-free will likely help," says Jenny Levine Finke, a Certified Integrative Nutrition Coach, and author of Dear Gluten, It's Not Me, It's You.

In a 2022 study published in Nutrition Reviews, researchers found that a gluten-free diet can "ameliorate" autoimmune-related symptoms in 64.7% of those with a nonceliac autoimmune disease. For clues to where you stand with gluten, ask your doctor or dietitian to know what's good for you as an individual.

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6 Worst Eating Habits Causing Inflammation and Aging You Faster - Eat This, Not That

Prof. Dr. Mattias Desmet explains his theory of mass formation as it relates to the COVID pandemic and responds to criticism

In an Epoch Health podcast, Dr. Ann Corson spoke with Prof. Dr. Mattias Desmet, the worlds leading expert on the theory of mass formation and its application on the COVID-19 pandemic.

Dr. Desmet discussed the degeneration of modern science and explained the effects this has had on society, especially during the COVID-19 pandemic and how this had led to a global mass formation. He goes into great detail on what exactly causes mass formation and how people can resist the mass.

Prof. Dr. Desmet is a professor of clinical psychology in the Department of Psychology and Educational Sciences at Ghent University in Belgium and a practicing psychoanalytic psychotherapist. His work is widely discussed in Forbes, The Joe Rogan Experience, Fox News, The New York Post among hundreds of other media outlets and his interviews have millions of views. His previous works include The Pursuit of Objectivity in Psychology and Lacans Logic of Subjectivity: A Walk on the Graph of Desire and over a hundred peer-reviewed academic papers. In 2018 he received the Evidence-Based Psychoanalytic Case Study Prize of the Association for Psychoanalytic Psychotherapy, and in 2019 he received the Wim Trijsburg Prize of the Dutch Association of Psychotherapy. His latest book is the The Psychology of Totalitarianism, a psychological analysis that builds on the seminal The Origins of Totalitarianism by Hannah Arendt.

Dr. Corson has four decades of clinical practice. Her patient population includes people who are immunocompromised due to conditions such as Lyme disease and co-infections as well as mold-induced illness. She treats patients with an integrative approach and is known internationally for her success. Dr. Corson grew up in Southeastern Pennsylvania and obtained the Doctor of Medicine degree in 1982 from the University of Pennsylvania School of Medicine in Philadelphia, PA. She has been board certified in Family Medicine and in Integrative Holistic Medicine. Today, she has a solo integrative practice in Philadelphia and cares deeply about medical ethics and humanity. In 2008, she joined the non-profit organization Doctors Against Forced Organ Harvesting (DAFOH) and currently serves as Editor-in-Chief of DAFOHs e-newsletter.

During the COVID-19 pandemic, there were many questionable methodologies used by the scientific community to justify their actions. However, in order for these actions to be taken in the first place, there needed to be a system in place to enable such things to happen. Dr. Desmet explained that science, once a form of truthful observation and thinking, devolved into a dogmatic ideology.

In the beginning, around the 17th century, science represented a discourse through which a minority went against an established discourse, namely established religion. In the beginning, science was a pragmatic form of truthful speaking, it was to listen to what nature had to say and observe the phenomena of nature, without being blinded or [deafened] because of the prejudices and the dogmas of the mainstream discourse, he said.

For us, slowly, this minority became the dominant, and the more it became the dominant discourse itself, the more dogmatic [it became]. It evolved from looking at the world in an open-minded way to an ideology or belief. Belief means prejudice, and people started to believe the universe was a machine, that nothing existed except material particles, that everything was logically deductible, he explained. Thats what science, the scientific ideology, represents.

When a certain theory, a certain view of the world, starts to become dominant, when the majority of the people start to believe in a certain discourse, that discourse becomes the privileged instrumentto manipulate society, to be successful, for instance, to win money, to have a grip on society and so on. And thats what happened with scientific discourse, he said. This resulted in this perverted state of science, especially in the medical sciences.

Dr. Desmet said that, for him, it all began in 2005, when it became clear that for instance, in the medical sciences, up to 85 percent of the papers cannot be reproduced, which is dramatic, of course. A separate research group, for example, would repeat the same analysis on the same data and find radically different results than the first research group.

It became clear that several factors played a role, such as massive errors in calculation and statistical analysis. Many scientists used [the] wrong methods to analyze data, [they used] sloppy, sloppy methods. And then also there was much more fraud than was ever before. So for all kinds of reasons, a lot of the academic research proved to be unreliable and without much value.

Dr. Desmet had done plenty of research in this regard and even wrote his PhD about this phenomenon. When addressing his colleagues and telling them about this phenomenon, most of [them] refused to see what I had when I tried to show them [they] even became angry with me.

I had the impression that the group dynamics and mass psychology were responsible for this blindness and for their radical incapability to see the absurdity of the research they were doing.

Science is however inherently flawed, Dr. Desmet claims. Scientists always had the ambition to validate the fact that only numerical or quantitative information is 100 percent accurate, so they began to separate things into one dimensional objects easy to quantify. So they want to measure everything and they forget that most objects in nature can never be measured adequately. Data measured in a scientific process can never tell the full story.

At the beginning of the pandemic, Desmet immediately saw that the way the dangerousness of the virus was measured was flawed.

I immediately had the impression that this research dramatically overrated the dangers, the dangers of the virus. Dr. Desmet said that people might be infected with COVID-19, but the deaths linked to COVID-19 were in fact mostly in those who already had serious comorbidities. There was plenty of data, showing that most people who were registered as corona victims actually suffered from three or four major other medical conditions.

They always make this measurement that confirms their own subjective preferences, meaning that in this case, all these global institutions such as the WEF, the WHO, the UN, all these institutions actually selected counting methods that confirmed the narrative that they wanted to distribute, namely, we are dealing with an extremely dangerous virus. Yet when Dr. Desmet published opinions and papers detailing the empirical evidence, it was clear that people didnt want to hear it.

So Dr. Desmet began focusing on the psychological processes in society and applied mass formation theory. But what is that exactly?

Mass formation has existed for as long as mankind exists, Desmet said. The Crusades, Nazi Germany, the Soviet Union, and many more phenomena were an example of mass formation. It will exist as long as mankind exists, and there are very specific conditions that need to be met for it to take place, he explained.

The first condition is a sort of isolation, where people feel disconnected from their environment.

Weve seen throughout the last few centuries that the number of people feeling isolated, feeling lonely, and disconnected from their environment is constantly increasing, he said. And thats a consequence of the industrialization of mechanization. Its clear that loneliness almost perfectly correlated to the industrialization and mechanization of development and the use of technology, which might sound [paradoxical], but it isnt.

Dr. Desmet said feeling disconnected will then lead to a lack of meaning that bridges over to anxiety, depression, and frustration, because as human beings experience meaning, we see that we have an effect on the otherand if the connection with the other deteriorates or disappears then these spontaneous experiences will maybe not manifest anymore.

Once people feel disconnected and struggle with lack of meaning [they] may typically be confronted with anxiety, free-floating anxiety, frustration, and aggression people feel anxious or aggressive but dont know what theyre anxious, frustrated, or aggressive for.

And thats an extremely precarious mental state, because if youre anxious, and you dont know what youre anxious for, you just feel completely out of control. You cannot protect yourself from something that makes you anxious if you dont know what makes you anxious. So in this state, people areif under these conditions, someone distributes a narrative, preferably through the mass media, indicating an object of anxiety and at the same time a strategy to deal with the object of anxiety, then all this free-floating anxiety latches onto the object of anxiety and there might be a huge willingness to execute this strategy to deal with the object of anxiety, even if the strategy is absurd.

This strategy turns into a ritual, which doesnt have to be rational. They [the rituals] have a social function, a personal function, and an effective function, which is all they need.

Dr. Desmet says that mass formation is extreme collectivism. It destroys individuals ethical self awareness and robs them of their ability to think critically.

A mass is a kind of group that emerges not because individuals connect to each other; the mass is a group that emerges because each individual separately connects to the collective. Meaning that this famous, typical solidarity that exists in a mass is never a solidarity between individuals. Its a solidarity between all individuals, separately, and the collective. The longer the mass formation exists, the more all the love and all psychological energy is sucked away from the connections between the individuals who bond with other individuals, and is invested in bond between the individuals and the collective, meaning that in the end, people feel much more solidarity for the collective than for someone else.

That explains, of course, why in the corona crisis, so many people were talking about solidarity, but at the same time, they accepted that if someones parents were dying in a hospital[that the children] were not allowed to visit their father or their mother. As this phenomenon unfolds, it becomes a kind of hypnosis that leads people to commit atrocities, Desmet explained.

During the course of the pandemic crisis, some have pointed at the elite as the true enemy and cause of the crisis. Desmet disagrees.

From the French Revolution onwards, you can say, a new elite, which immediately understood that the new leaders, the politicians, were not really leaders anymore. They were followers because they had to be elected by the masses, they knew that they couldnt really lead the masses. They had to follow the masses. And thats where the leaders of society started to realize that they needed something else. They needed propaganda and indoctrination to constantly manipulate the masses, and to constantly try to steer them when they wanted to get them. Indoctrination and propaganda it the subject of Desmets next book, which he is currently working on.

The elite is certainly powerful, and propaganda is real, Desmet said, but that is not what we are truly facing.

The real enemy is a certain way of thinking, its a certain view of man and the world, the mechanistic, rationalist view of man and the world. Its this delusional belief that we can understand everything on a rational basis, that we can control everything rationally, and that we should manipulate everything rationally. Its precisely this worldview that leads to an elite that would try to control society, he added.

Its this mechanistic thinking that is the real enemy, that leads to the development of this new elite and at the same time, that brings the population in this specific psychological state, where it is so sensitive for manipulation, where it is so sensitive for indoctrination propaganda.

Hannah Arendt says totalitarianism is always a diabolic pact between the masses and the elite, and thats true. But its wrong to say that its all the fault and only the fault of the elite. If we would destroy the elite, the problem would not be solved. The same elite would be recreated again if the population continues to be in the grip of this rationalist, mechanist view of man and the world. Thats why it is wrong to analyze everything in terms of one large conspiracy and nothing else. If thats the analysis you start from, then the logical, strategical conclusion, the tactical conclusion will be that we need a violent revolution against the eliteand if we do that, we will destroy ourselves, he said. The elite is also something that is created by the population.

As Solzhentisyn said, the dividing line between good and evil doesnt run between people, it runs through every heart, he said.

So how do we resist the mass? Dr. Desmet says the most important principle is that we always have to continue to speak out. Thats the most important principle. So mass formation is kind of [like] hypnosis, its identical.

Usually dissonant voices wont succeed [in] waking up the masses. But that doesnt mean that the dissonant voice doesnt have an effect, it has an effect. It has the effect that the mass formation doesnt become deeper.

As a human being, I believe we have the ethical duty to always articulate the words that seem sincere and honest to us and that in this pool of darkness, tries to represent a little bit of light, and gets more and more in touch with the ethical principles of humanity, and tries to live up to these principles.

Those who do usually go through a fast process of evolution, they become stronger and stronger and stronger as human beings Thats the most profound reason, the ethical reason, why we have to choose to continue to speak out also from a tactical point of view, this will be the best choice we can make.

If you, this group who doesnt go along with the narrative, makes the right choice, you will start to see that this crisis was meant to be there. We need this crisis. Its a process in which a large organism, a dominant society, puts a large pressure on a small organismand pushes it on a path where it would not go wrong, if there was this large path who puts this pressure on, he said.

But if we choose to remain silent, or if we refuse to try to reinvent and rearticulate the ethical principles of humanity in this period, in these times, then the opposite will happen. The masses will probably first destroy the people who do not go along with them, and then they will start to destroy themselves, and in the end, it will be one pure, destructive process.

But its absolutely critical that we do so peacefully and reasonably. While [the mass] probably will show the tendency to dehumanize us, we should not react in the same way, because if we react in the same way we will destroy ourselves and everything will become meaningless, he said.

If we are convinced that that the elite is pure evil and the rest of us are merely victims, then, as I said, the only conclusion is violence.

Its vital that we continue to speak in a sincere and honest way, not because we are convinced that we are the only ones who know the truth, and all the rest are liars and so on if we feel that, to our own best understanding something is right, sincere and honest, then we have to articulate it.

And you know, we dont have to be blind terrible things happened, wars were provoked, famine millions of people were sent into debt by the elite. Thats all true. Thats all true. And I know thats true. But its also true that the population is responsible, that the elite is also something that is created by the population that emerges from the population.

Views expressed in this article are the opinions of the author and do not necessarily reflect the views of The Epoch Times. Epoch Health welcomes professional discussion and friendly debate. To submit an opinion piece, please follow these guidelines and submit through our form here.

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How to End the Mass Formation (VIDEO) - The Epoch Times