How effective Are Drugs?

Waterpills

You will find many studies that show how waterpills reduce blood pressure, of course they do because they work on the arterial pressue but again below you will see that no heart attacks or strokes are prevented. 

Metformin and other diabetes drugs

Metformin is a widely prescribed oral medication for the treatment of type 2 diabetes (DM2). It belongs to the biguanide class of drugs that control blood sugar levels by inhibiting gluconeogenesis in the liver and thereby reducing glucose production in the liver, but there is also evidence it improves insulin resistance by promoting glucose uptake in the muscles.

Here’s a step-by-step explanation of how metformin works:

1. Improved insulin sensitivity: Insulin resistance is a common characteristic of type 2 diabetes, where the body’s cells don’t respond effectively to insulin, leading to high blood sugar levels. Metformin increases insulin sensitivity in the muscles and other peripheral tissues, allowing them to take up glucose more efficiently and use it for energy. This, in turn, helps lower blood sugar levels.
2. Reduced glucose production: The liver plays a crucial role in maintaining blood sugar levels by producing glucose through a process called gluconeogenesis. In people with type 2 diabetes, the liver may produce excessive glucose, contributing to high blood sugar levels. Metformin suppresses hepatic gluconeogenesis, reducing the amount of glucose released into the bloodstream and thereby lowering blood sugar levels.
3. Increased glucose uptake: Metformin promotes glucose uptake and utilization in the skeletal muscles by increasing the expression and activity of glucose transporters (such as GLUT4) on the cell surface. This helps muscles absorb more glucose from the blood, further reducing blood sugar levels.

Metformin is generally well-tolerated, but it may cause gastrointestinal side effects such as nausea, diarrhea, and abdominal discomfort in some individuals. These side effects can often be minimized by starting with a low dose and gradually increasing it as directed by a healthcare professional. In rare cases, metformin may cause a serious condition called lactic acidosis, particularly in patients with impaired kidney function, liver disease, or other risk factors.

Cancer:

There is evidence that metformin has positive effects on cancer, for the same reason as it lowers insulin resistance and thereby systemic inflammation. As discussed both cancer and DM2 are by nature inflammatory so metformin will assist in lowering systemic inflammation but in turn it never treats the undying root of the problem as discussed. The initial effects of metformin lowering glucose and inflammation are eventually over ridden and the patient ends up on insulin injections.

Li 2023: Of note, women with metabolic syndromes (MetS), including obesity, hyperglycemia, dyslipidemia, and hypertension, have an increased risk of developing endometrial carcinoma (EC), suggesting a close link between metabolism and EC. Interestingly, the metabolic preferences vary among EC cell types, particularly cancer stem cells and chemotherapy-resistant cells.

Metformin does indeed have some anti-inflammatory effects that could potentially be beneficial in cancer, as well as in type 2 diabetes.

Inflammation is a common feature of many chronic diseases, including both cancer and diabetes. It is thought to contribute to disease progression in multiple ways, for example by promoting insulin resistance in diabetes and by fostering an environment that supports tumor growth in cancer.

Metformin can reduce inflammation in several ways. As you mentioned, one way is by improving insulin sensitivity, which can lower blood insulin levels. High insulin levels can stimulate inflammation, so by reducing insulin, metformin may help to reduce inflammation. Additionally, metformin has been shown to directly inhibit inflammatory pathways inside cells, which could further contribute to its anti-inflammatory effects.

Metformin does not treat the underlying cause of either diabetes or cancer. In diabetes, the underlying problem is typically a combination of insulin resistance and dysfunction of the insulin-producing cells in the pancreas. In cancer, the underlying problem is uncontrolled cell growth. While reducing inflammation may help to slow disease progression, it does not fix these fundamental issues.

In the case of diabetes, metformin is often an effective first-line treatment, but many patients will eventually require additional treatments, including possibly insulin, to maintain good blood sugar control.

In the case of cancer, metformin is not a standard treatment, but it is being studied for its potential to enhance the effects of standard cancer treatments and improve outcomes for patients.

Semaglutide (Ozempic®) for weight loss?

Semaglutide is a serious medication used to manage blood glucose levels in people with type 2 diabetes. Long-term side effects of semaglutide are still being studied, and new information may have emerged, so please consult the latest medical literature and present it to your healthcare provider for the most accurate and current information.

->The difference of semaglutide and placebo was only 10%….

->Once you have DM2 semaglutide does not reduce weight much at all.

Semaglutide is now used ‘off-label’ as a weight loss drug. Below is some information on potential long-term side effects based on the knowledge available up to January 2022:

“Side Effects”
1. Gastrointestinal Symptoms: Nausea, vomiting, diarrhea, and abdominal pain are common side effects, and they can persist.
2. Decreased Appetite and Weight Loss: Semaglutide can lead to a reduction in appetite and significant weight loss.
3. Pancreatitis: There is a concern with medications in the same class as semaglutide that they could potentially increase the risk of pancreatitis.
4. Hypoglycemia: When used in combination with other diabetes medications, like insulin or sulfonylureas, semaglutide might increase the risk of low blood sugar levels.
5. Kidney Problems: There is some evidence suggesting that semaglutide might impact kidney function over time.
6. Thyroid Tumors: Medications in the same class as semaglutide have been linked to a rare type of thyroid tumor in animal studies, but the relevance of this finding to humans is not clear.

Long-term Concerns

1. Cardiovascular Safety: While some studies suggested that semaglutide may have cardiovascular benefits, long-term studies are essential to understand fully its impact on cardiovascular health.
2. Cancer Risk: The potential long-term risk of cancer, particularly thyroid cancer, with semaglutide is not completely understood and is a subject of ongoing research.

->2 times increased risk in Thyroid cancer

3. Muscle loss: While semaglutide is “effective” in managing blood sugar levels and promoting weight loss, its impact on muscle mass is an important consideration:

1. Weight Loss: The weight loss effect of semaglutide can include loss of both fat and lean body mass (muscle). Significant weight loss without adequate nutritional support or resistance training can lead to muscle loss.
2. Nutrient Intake: Reduced appetite can lead to decreased overall caloric and protein intake, which are crucial for maintaining muscle mass.
3. Physical Activity: People losing weight may not always engage in enough resistance or strength training to preserve muscle mass, which can contribute to muscle loss.
4. Metabolic Changes: Weight loss often leads to metabolic adaptations that can include a reduction in muscle mass, especially if the weight loss is rapid or not accompanied by strategies to preserve muscle.

– Patients on semaglutide should be closely monitored for any adverse effects
– Regular follow-up visits are necessary to monitor blood glucose levels, kidney function, and other relevant parameters.

Semaglutide was originally only intended for use to manage blood glucose levels in people with type 2 diabetes but has shown significant efficacy in promoting weight loss in individuals with and “without diabetes”.

Mechanism of Action for Weight Loss:

The difference of semaglutide and placebo is only 10%!

Of 611 randomized participants (495 women [81.0%], mean age 46 years [SD, 13], body weight 105.8 kg [SD, 22.9], and body mass index 38.0 [SD, 6.7]), 567 (92.8%) completed the trial, and 505 (82.7%) were receiving treatment at trial end. At week 68, the estimated mean body weight change from baseline was –16.0% for semaglutide vs –5.7% for placebo (difference, −10.3 percentage points [95% CI, −12.0 to −8.6]; P < .001). 

Semaglutide mimics a hormone in the body called glucagon-like peptide-1 (GLP-1) that affects appetite regulation. By binding to the GLP-1 receptor, semaglutide helps:
1. Decrease Hunger: By delaying gastric emptying and promoting a feeling of fullness or satiety.
2. Reduce Calorie Intake: The feeling of fullness or satiety helps individuals to eat fewer calories.

FDA Approval: A higher dose of semaglutide, marketed under the brand name Wegovy, has received approval from the U.S. Food and Drug Administration (FDA) as a treatment for chronic weight management in adults who are either obese or overweight and have at least one weight-related condition such as high blood pressure, type 2 diabetes, or high cholesterol.

Efficacy?: Clinical trials have demonstrated significant weight loss with semaglutide compared to placebo, with some participants losing around 15% of their body weight, on average, over a period of 68 weeks.

Administration and Dosage: The medication is administered via subcutaneous injection, usually once a week. The dose for weight management is different from the dose used for managing blood glucose levels in diabetes, so it’s crucial for individuals to use the medication as prescribed and under the guidance of a healthcare provider.

Minor Side Effects Summary:

Common side effects include nausea, diarrhea, vomiting, constipation, and abdominal pain. Most of the side effects are gastrointestinal and are more common when starting the medication but tend to decrease over time.

Major Side Effects:

• Cancer risk
• Pancreatic Exhaustion
• Muscle loss (up to 38% of the lost weight)
• Bone density loss
• increased insulin sensitivity
• GI symptoms

Weight loss Considerations:

– Semaglutide is generally considered as part of a comprehensive weight management program that includes dietary modifications, physical activity, and behavioral changes.
– It is important for individuals to discuss their medical history, current medications, and health goals with their healthcare provider to determine whether semaglutide is an appropriate option for them.
– The long-term safety and efficacy of semaglutide for weight loss are still being studied, and patients should be monitored regularly for any potential adverse effects while on the medication.

So serious are the GI symptoms that initial dosage has to me minimal:

The dosage increase of Ozempic (semaglutide) from 0.5 mg to 2.4 mg is typically done progressively as part of the treatment plan to manage type 2 diabetes and, more recently, for weight management under the brand name Wegovy (which also uses semaglutide). This gradual increase in dosage serves several important purposes:

1. Tolerability:
Minimizing Side Effects: Ozempic can cause gastrointestinal side effects, such as nausea, vomiting, and diarrhea. By starting at a lower dose (0.5 mg) and gradually increasing to the maintenance dose, patients can better tolerate the medication, allowing their bodies to adjust to its effects. This slow titration helps in minimizing these side effects, which can be more pronounced at higher doses.
Patient Adaptation: The body needs time to adapt to the drug’s effects on appetite regulation and gastric emptying. A slower titration helps ensure that patients are less likely to discontinue the drug due to intolerable side effects.

Safety

Safety of Semaglutide – PubMed (nih.gov)  “In the current review we discuss the occurrence of adverse events associated with semaglutide focusing on hypoglycemia, gastrointestinal side effects, pancreatic safety (pancreatitis and pancreatic cancer), thyroid cancer, gallbladder events, cardiovascular aspects, acute kidney injury, diabetic retinopathy (DRP) complications and injection-site and allergic reactions and where available, we highlight potential underlying mechanisms.”

Gastric Emptying and Ozempic

One of its mechanisms is to mimic the action of an incretin hormone, which leads to increased insulin release in response to meals, decreased glucagon production, and delayed gastric emptying.

Delayed Gastric Emptying:

• Mechanism: Ozempic slows gastric emptying as part of its action to control blood sugar levels. This means that food stays in the stomach longer than usual, which can help increase satiety and reduce appetite.
• Effect: By delaying gastric emptying, Ozempic can help lower post-meal blood glucose spikes. However, this effect can also contribute to some of the gastrointestinal side effects associated with the medication.

Gastrointestinal Side Effects

Common Side Effects:

• Nausea: This is one of the most common side effects of Ozempic and can be attributed in part to the delayed gastric emptying.
• Vomiting and Diarrhea: These symptoms can also occur, particularly when beginning treatment or increasing the dosage.
• Constipation: Slowed digestion can lead to less frequent bowel movements.

Gastric Residue:

• Explanation: The term “gastric residue” typically refers to the amount of undigested material left in the stomach after a period of digestion. In the context of Ozempic, increased gastric residue could result from the medication’s effect on slowing gastric emptying.
• Potential Concerns: Increased gastric residue could potentially exacerbate feelings of fullness or bloating and contribute to the nausea experienced by some patients.

The concept of gastric residue refers to the amount of undigested material left in the stomach after a period of digestion. Increased gastric residue is generally not directly linked to an increased risk of cancer. However, conditions that lead to prolonged gastric residue and delayed gastric emptying might have indirect relationships with increased gastric discomfort or potentially other gastric conditions.

Delayed Gastric Emptying and Health Risks:

1. Gastrointestinal Discomfort:

• Chronic delayed gastric emptying, as seen in conditions like gastroparesis, can lead to symptoms such as nausea, vomiting, bloating, and abdominal pain. While these symptoms do not directly increase cancer risk, they can significantly impact quality of life and nutritional status.

2. Bacterial Overgrowth:

• Prolonged gastric residue can lead to bacterial overgrowth in the stomach. While this condition is typically more annoying than dangerous, chronic bacterial overgrowth can cause inflammation and has been associated with complications like small intestinal bacterial overgrowth (SIBO). Chronic inflammation is a known risk factor for various types of cancer, but the link between SIBO and specific cancers is not well-established.

3. Acid Reflux and Esophageal Conditions:

• Delayed gastric emptying can exacerbate gastroesophageal reflux disease (GERD), where stomach acid frequently backs up into the esophagus. Chronic GERD is associated with Barrett’s esophagus, a condition that increases the risk of esophageal adenocarcinoma. Therefore, indirectly, conditions that promote GERD might contribute to an elevated risk of this type of cancer.

4. Effect on Diet and Nutrition:

• Conditions that lead to increased gastric residue may also affect dietary habits. Poor digestion can result in nutritional deficiencies and weight loss, factors that can weaken the immune system and potentially affect cancer risk, although more research is needed to understand these relationships fully.

More on the mechanism of weight loss

Glucagon-like peptide-1 (GLP-1) and Semaglutide are different. Semaglutide is a peptide that is structurally similar to the hormone glucagon-like peptide-1 (GLP-1). GLP-1 is an incretin hormone produced in the gut in response to food intake, and it plays several important roles in glucose metabolism. Here’s a more detailed look at GLP-1 and how semaglutide mimics its actions:

GLP-1 and Its Functions

1. Stimulates Insulin Secretion: GLP-1 enhances the secretion of insulin from pancreatic beta cells in a glucose-dependent manner, meaning it increases insulin secretion when blood glucose levels are high.
2. Inhibits Glucagon Secretion: GLP-1 suppresses the release of glucagon from pancreatic alpha cells, which helps reduce hepatic glucose production.
3. Slows Gastric Emptying: GLP-1 slows down the rate at which the stomach empties its contents into the small intestine, which helps moderate postprandial (after meal) blood glucose spikes.
4. Reduces Appetite: GLP-1 acts on the brain to promote satiety (feeling of fullness) and reduce appetite, contributing to lower caloric intake and weight loss.

Semaglutide as a GLP-1 Receptor Agonist

1. Structural Similarity: Semaglutide is a synthetic analog of GLP-1, meaning it has a similar structure but with modifications that enhance its stability and prolong its action in the body.
2. Longer Half-Life: Unlike native GLP-1, which is rapidly degraded by the enzyme dipeptidyl peptidase-4 (DPP-4), semaglutide is resistant to DPP-4 degradation, giving it a longer half-life. This allows for less frequent dosing (once weekly for semaglutide).
3. Mechanism of Action: Semaglutide binds to and activates GLP-1 receptors, mimicking the effects of natural GLP-1. This includes stimulating insulin secretion, inhibiting glucagon release, slowing gastric emptying, and reducing appetite.

1. Stimulating Insulin Secretion: GLP-1 enhances the secretion of insulin from the pancreas in a glucose-dependent manner. This means that it promotes insulin release when blood glucose levels are high, but not when they are normal or low, reducing the risk of hypoglycemia.
2. Inhibiting Glucagon Release: It suppresses the secretion of glucagon, a hormone that raises blood glucose levels. By inhibiting glucagon, GLP-1 helps lower blood glucose.
3. Slowing Gastric Emptying: GLP-1 slows the rate at which the stomach empties its contents into the small intestine, prolonging the absorption of glucose and leading to a more gradual rise in blood glucose levels after eating.
4. Appetite Regulation: It acts on the brain to increase satiety, thereby reducing food intake.

Glucagon-like Peptide-1 (GLP-1) Mechanism

GLP-1 receptor agonist, meaning it mimics the action of GLP-1. GLP-1 is an incretin hormone that plays a key role in glucose homeostasis. Its mechanism of action includes:

1. GLP-1 Receptor Activation: Semaglutide binds to and activates GLP-1 receptors in the pancreas and other parts of the body.
2. Enhanced Insulin Secretion: Like GLP-1, it enhances the secretion of insulin in a glucose-dependent manner, helping to lower blood glucose levels when they are elevated.
3. Reduced Glucagon Secretion: It also suppresses the release of glucagon, contributing to lower blood glucose levels.
4. Slowing Gastric Emptying and Appetite Suppression: Semaglutide slows down gastric emptying and acts on the brain to reduce appetite and food intake, similar to the natural hormone.
5. Cardiovascular Effects: Recent studies have shown that GLP-1 receptor agonists like Semaglutide may have beneficial effects on cardiovascular outcomes in people with Type 2 diabetes.
6. Extended Half-Life: Semaglutide has modifications that extend its half-life, allowing for less frequent dosing (typically once weekly) compared to the natural GLP-1, which has a very short half-life and would require multiple daily doses.

In conclusion, while GLP-1 naturally regulates blood sugar, appetite, and insulin secretion, Semaglutide is a synthetic drug that mimics these actions, offering a practical and potent treatment for Type 2 diabetes, often with added cardiovascular benefits. It’s the prolonged action of drugs like Semaglutide, compared to the short-acting natural GLP-1, that makes them particularly useful in clinical practice but also dangerous as to the unknown long term effects.

Pancreatic exhaustion

The concept of “pancreatic exhaustion” or beta-cell dysfunction due to continuous stimulation to produce insulin is an area of ongoing research, particularly in the context of Type 2 Diabetes (T2D). Here’s a summary of the current understanding:

1. Beta-Cell Overactivity and Dysfunction: There is evidence suggesting that sustained overactivity of pancreatic beta-cells, due to continuous stimulation for insulin production, might contribute to beta-cell dysfunction over time. This is especially relevant in the early stages of Type 2 Diabetes, where beta-cells are often overstimulated to compensate for insulin resistance.
2. Glucokinase (GK) and Insulin Secretion: The enzyme glucokinase (GK) in beta-cells plays a crucial role in insulin secretion. Increased activity of GK, as seen in certain disease models, can lead to a heightened response to glucose and subsequent hyperinsulinemia. This could potentially drive beta-cell exhaustion in susceptible individuals.
3. Pharmacological Interventions: Past pharmacological interventions aimed at activating GK to stimulate insulin secretion have had limited long-term success. In some cases, persistent hyperinsulinemic hypoglycemia due to GK mutations has been linked to beta-cell dysfunction and diabetes later in life, suggesting that long-term beta-cell overactivity caused by augmented GK activity may contribute to beta-cell dysfunction.
4. Potential Mechanisms: Various posttranslational modifications are thought to increase the activity of GK, which may be brought on by excess nutrient load, the need to adapt to insulin resistance, hyperglycemia, or other unidentified mechanisms. These modifications might cause an increase in GK activity, consistent with changes found after treating islets in high glucose.

The concept of “pancreatic exhaustion” is complex and involves multiple factors, including genetic predisposition, environmental factors, and the chronic metabolic demands placed on the pancreas in conditions like T2D. While the exact mechanisms are still being studied, it’s clear that prolonged overstimulation of the pancreas can contribute to beta-cell dysfunction, a key factor in the progression of T2D.

Diabetes type 1 and stem cell therapy

The use of stem cell therapy to treat type 1 diabetes (T1D) is an active area of research with promising preliminary results, but it has not become a standard treatment. 

Type 1 diabetes is an autoimmune disease where the body’s immune system attacks and destroys the insulin-producing beta cells in the pancreas. Without these beta cells, the body can’t produce enough insulin, a hormone that helps regulate blood sugar levels.

Stem Cell Approaches:

1. Embryonic Stem Cells (ESCs): These cells have the potential to become any cell type in the body, including insulin-producing beta cells. Scientists have developed methods to differentiate ESCs into beta cells and have tested these in animal models with some success.

2. Induced Pluripotent Stem Cells (iPSCs): Similar to ESCs, iPSCs can be directed to become beta cells. iPSCs are generated from adult cells, like skin cells, that have been reprogrammed back into a stem cell-like state, allowing for potential patient-specific treatments and reducing concerns about immune rejection.

3. Mesenchymal Stem Cells (MSCs): MSCs have immunomodulatory properties that could help in modulating the autoimmune attack in type 1 diabetes, although they don’t differentiate into beta cells. Some studies have investigated their potential in altering the course of T1D or improving the function of existing beta cells.

Challenges:

1. Immune Rejection: One of the major challenges in T1D is the immune system’s destruction of insulin-producing cells. Even if new beta cells are introduced via foreign stem cell therapy, they might still be attacked by the immune system. This makes immune system modulation or protection of these cells critical for long-term success.

2. Safety Concerns: Using artificial or genetically manipulated cells. There are concerns about the potential for stem cells to form tumors, called teratomas, if they are not fully differentiated into beta cells. Ensuring the safety of these therapies is paramount.

3. Functional Integration: Newly formed beta cells need to integrate functionally with the body’s regulatory system to release insulin appropriately in response to blood glucose levels.

Clinical Trials:

Various clinical trials have been investigating stem cell therapies for type 1 diabetes, from the potential of hematopoietic stem cell transplantation to reset the immune system to more recent trials with beta cell replacement from differentiated stem cells.

The potential of stem cell therapies for type 1 diabetes is enormous, but several challenges need to be overcome before they can become routine treatments. Patients and families interested in stem cell therapies should be cautious about clinics offering “stem cell cures” without rigorous scientific evidence and should consult with diabetes specialists about the most recent and proven treatments.

Keep in mind that the field of stem cell research is rapidly evolving, so it’s a good idea to periodically check the latest research or consult with healthcare professionals to get the most up-to-date information.

Phase 1/2 study indicates stem cell-derived therapy that is designed to replace destroyed beta cells with healthy transplanted insulin-producing cells may have potential to transform type 1 diabetes

-> At 90 days post-procedure, all six patients in Parts A and B responded to a mixed-meal tolerance test by triggering production of the bodies own insulin!