Dr. Flavio Cadegiani, a Brazilian endocrinologist, suspects that the worst is yet to come for spike-protein-induced diseases in the endocrine system.

The endocrine system, colloquially known as the hormone system, is critical for our health. It regulates growth and development, mood, metabolism, reproduction, immunity, and functions of other organs through the secretion of hormones.

Hormones are one of the three biggest messengers in the body. Compared to the two other messengers—neurotransmitters and cytokines—hormones are slower in responding and have systemic functions across the body rather than localized actions.

While cells can usually respond to neurotransmitters in milliseconds and cytokines in minutes to hours, cells that respond to hormones can take hours or even weeks.

Since hormones can have slow and systemic actions, a dysfunctional or damaged endocrine system will generally be slow in its symptom onset and recovery.

“What we’re going to see in the future [for endocrine diseases] is a little bit different from the other fields, because glands have reserves and the decrease of the reserve will not be clinically seen right now, but it may be in the future,” Cadegiani said at a Front Line COVID-19 Critical Care Alliance (FLCCC) conference in Kissimmee, Florida.

Therefore, affected individuals may show no symptoms until their reserves have been depleted.

Cadegiani said most of his concerns for the future are speculative and based on his own clinical observations. But since the pandemic and the administration of COVID-19 vaccines began, there have been increasing reports that implicate endocrine pathologies.

Endocrine glands control the function of many organs across the body, and each endocrine organ is also connected through a feedback loop, also known as a hormonal axis.

At the top of this chain is the hypothalamus, which is a diamond structure in the brain and acts as a master switchboard. It sends messages to the pituitary gland, a small, oval structure tucked behind the nose.

The pituitary gland is colloquially known as the master gland; it regulates other endocrine organs together with the hypothalamus, forming hormonal axes.

The pituitary gland is part of the hypothalamic-pituitary-gonadal axis, which regulates the reproductive organs, including the ovaries and the testes. In females, it’s responsible for regulating the release of ovarian hormones as part of the menstrual cycle; in males the axis regulates spermatogenesis.

The hypothalamic-pituitary-adrenal axis is a neuroendocrine axis that mediates the adrenal glands, an organ that produces hormones that trigger the fight-or-flight response. The process is a stress response that occurs in response to harmful threats and can reduce metabolism, suppress the immune system, and activate the sympathetic nervous system.

The key driver behind spike-protein-induced disease is inflammation.

Upon entering cells, spike proteins can activate pro-inflammatory pathways by inducing DNA damage; inhibiting DNA repair; causing stress to the cell’s mitochondria, which is critical for cell energy production; and much more. All of this lead to cellular stress, injury, and possible cell death.

When many cells are affected, it can cause problems in tissues and organs, affecting individual endocrine glands and the system.

Spike proteins also inhibit autophagy, the cellular “recycling system,” thereby preventing the cells from clearing the toxic protein out, leading to prolonged damage.

Spike proteins may also contribute to autoimmunity. Since it shares many similarities with common human tissues and proteins—known as “molecular mimicry”—it has the potential to cause immune cells to mount an attack against the body’s own cells and organs, leading to endocrine damage.

Cadegiani said pathologies in the pituitary are difficult to diagnose; they’re often masked by other conditions, therefore there’s little literature on pituitary pathology presentation after COVID-19 vaccinations.

The adrenal glands, located above the kidneys, produce hormones responsible for the stress response. This includes adrenaline, cortisol, and aldosterone. The release of these three hormones is critical for maintaining energy and other needs during stressful situations.

The glands are also likely to be involved in post-vaccine myocarditis events that are often seen in young males. Cadegiani said this type of myocarditis may be a sign of adrenal dysfunction.

While dopamine mostly acts within the nervous system, both adrenaline and noradrenaline play important roles in stress responses.

Adrenaline activates the fight-or-flight stress response and the noradrenaline supports the response by increasing heart rate, breaking down fats, and increasing blood sugar levels.

He hypothesized that the vaccines triggered a hyper-catecholaminergic state by elevating levels of adrenaline, causing hyperactivation of adrenaline.

Dysfunctions in the adrenal glands are likely to lead to adrenal insufficiency.

Cadegiani hypothesized adrenal insufficiency—a condition in which the adrenal glands become unable to produce enough hormones—to be a possible consequence of spike protein injury.

It makes two hormones: thyroxine and triiodothyronine. Deficiencies in triiodothyronine results in hypothyroidism, characterized by a large thyroid; over-secretion of it can cause hyperthyroidism.

The thyroid also plays a role in regulating the immune system. COVID-19 infection is often a sign of underlying thyroid problems, and damage from infection can exacerbate thyroid problems, creating a negative cycle.

Although the research shows that thyroids can be implicated in infection, thyroiditis, which is inflammation of the thyroid, has currently only been reported in relation to the COVID-19 vaccine.

Four of the patients also developed Graves’ disease, which is an autoimmune disease and a complication of hyperthyroidism. Hashimoto’s disease, another thyroid autoimmune condition, has also been reported following vaccinations.

Spike proteins from both the vaccine and the virus have shown a potential to disturb glucose metabolism.

Erectile dysfunction has been established in research to be due to dysfunctions of the endothelial cells, and the spike proteins impair endothelial cells.

Studies linking COVID-19 and erectile dysfunction have largely blamed it on the virus’s interaction with ACE2 receptors displayed on the surface of endothelial cells. Endothelial cells are abundant in ACE2 receptors, making them one of the most targeted in COVID-19 infections.

Since the vaccine rolled out in 2021, the Centers for Disease Control and Prevention data reported 193 cases of erectile dysfunction following COVID-19 vaccination.

Although sperm count gradually made a recovery after 145 days, sperm concentration and motility didn’t return to pre-vaccination levels, with unknown long-term effects.

Concerns of reproductive problems have also been reported in women, most particularly after vaccinations rather than after infection.

VAERS data shows that more than 60 percent of adverse event reports came from women, indicating that women are more vulnerable to post-vaccine symptoms.

Dr. Paul Marik, a critical care expert, also observed that women were at a greater risk of presenting with post-vaccine symptoms in the clinic.

Cadegiani predicted greater adverse events in pregnancies for the coming future.

The authors of the paper reviewed 10 studies and found that unvaccinated women have a clinical and biochemical pregnancy rate of 47 and 60 percent, respectively, while the vaccinated had a rate of 45 and 51 percent.

Cadegiani predicted more cases of endocrine pathologies as a result of spike injuries in the future.

“Endocrine diseases progress slowly and then only clinically appear in the severe states,” Cadegiani said. “So it’s not possible to tell this [anytime] beforehand.”