MSM Handbook – All about the sulfur power for your health E-Book

Valentin Ducane Valentin Ducane

MSM Handbook – All about the sulfur power for your health

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Inhaltsverzeichnis

Titel

Basics of Medicine

MSM and its properties

Detoxification of the organs

Inflammations

Vascular diseases

Allergies

Causes and mechanisms of allergies

Immunomodulatory effect of MSM

Skin problems

Effect of MSM on acne, eczema and psoriasis

Topical application of MSM

Testimonials and clinical studies

hepatitis

Overview of hepatitis and its types

How MSM works in liver inflammation

intestinal problems

diabetes

Hashimoto

Scleroderma

Diet and lifestyle

Use and dosage of MSM

Which Schüssler salts can help?

Which teas contain MSM?

Can I get MSM from different foods?

Future research and developments

Impressum neobooks

Basics of Medicine

Valentin Ducane

MSM Handbook –

All about the sulfur power for your health

Detoxification of organs, inflammation, vascular diseases, allergies, skin problems, hepatitis, intestinal problems, arteriosclerosis, diabetes, Hashimoto scleroderma, chronic pain

Methylsulfonylmethane

Introduction to MSM (Methylsulfonylmethane)

MSM, or methylsulfonylmethane, is an organic sulfur compound that occurs naturally and is found in small amounts in many foods, such as fruits, vegetables, grains, and dairy products. As a natural source of sulfur, MSM has significant importance for human health because sulfur is an essential element found in every cell type in the body. It plays a key role in the synthesis of amino acids, proteins, enzymes, and hormones. MSM is also commonly used as a dietary supplement to promote various health benefits.

The discovery of MSM dates back to the work of Dr. Robert Herschler and Dr. Stanley Jacob in the 1970s. They researched the properties of dimethyl sulfoxide (DMSO), a substance derived from wood pulp, and discovered that MSM is a natural byproduct of DMSO oxidation. Their research laid the foundation for today's understanding of MSM's health benefits.

MSM is known for its anti-inflammatory, antioxidant, and pain-relieving properties. It is widely used in the treatment of joint pain, arthritis, allergies, inflammation, and other health problems. Its ability to increase the permeability of cell membranes facilitates the transport of nutrients and the removal of waste from cells, contributing to improved cellular health and overall well-being.

Historical background

The history of MSM begins in the 1950s, when scientists began investigating the biological effects of DMSO. DMSO was originally used as an industrial solvent, but it was soon discovered that it also possessed therapeutic properties. Dr. Stanley Jacob of Oregon Health & Science University and Dr. Robert Herschler, a chemist, led the research into DMSO and MSM. Their studies showed that MSM, a natural oxidation product of DMSO, offers similar therapeutic benefits but without some of DMSO's unpleasant side effects, such as skin irritation and unpleasant odor.

MSM was discovered as a dietary supplement and introduced to the healthcare market in the 1980s. Since then, it has established itself as a versatile remedy for supporting health and alleviating various ailments. Numerous studies and reports have confirmed its positive effects in treating pain, inflammation, allergies, and other health problems.

Importance and relevance of MSM in modern medicine

MSM has assumed a significant role in modern medicine due to its diverse therapeutic properties. Its anti-inflammatory and pain-relieving properties make it a popular supplement in the treatment of arthritis and other inflammatory conditions. It is also frequently used in the treatment of allergies, skin conditions, gastrointestinal problems, and liver disease.

An important aspect of MSM's effects is its ability to increase the permeability of cell membranes. This facilitates the transport of nutrients into cells and the removal of waste products from them, leading to improved cellular health and function. MSM also supports the formation of collagen and keratin, which are essential for the health of skin, hair, and nails.

MSM also has antioxidant properties that help neutralize free radicals and reduce oxidative damage. This is especially important for preventing chronic diseases and supporting overall well-being. Furthermore, MSM has immunomodulatory effects that support the immune system and improve the body's immune response.

Research on MSM continues to be active, with many studies investigating its potential benefits and applications. There is evidence that MSM may be helpful in the treatment of certain cancers, autoimmune disorders, and neurodegenerative diseases. While further research is needed to fully understand these potential benefits, the results so far are promising.

Overall, MSM is a valuable agent in modern medicine, widely used due to its versatile therapeutic properties and safe profile. Its importance is underscored by the numerous positive patient reports and ongoing research.

Summary of the introduction

In this introduction, we provided an overview of MSM, its properties, and its historical development. We explained the importance of MSM as an organic sulfur compound and its diverse applications in modern medicine. MSM offers numerous health benefits, particularly in the treatment of inflammation, pain, allergies, and other health problems.

Research on MSM has confirmed its importance and relevance in medicine, and it remains an important topic for future studies and developments. Through its positive effects on cellular health, immune system support, and antioxidant properties, MSM has the potential to significantly improve people's overall well-being and quality of life.

The following chapters of the book will detail the various health benefits of MSM, including its use in organ detoxification, the treatment of vascular diseases, skin problems, hepatitis, intestinal problems, atherosclerosis, diabetes, Hashimoto's disease, and scleroderma. Each chapter will thoroughly discuss the scientific basis, clinical studies, and practical applications of MSM in these specific areas.

Anatomy and physiology are two fundamental branches of biology that enable the understanding of the human body and its functions. Anatomy deals with the structure of the body, while physiology examines how these structures function. Together, they provide a comprehensive picture of how the human body is constructed and how it functions.

Anatomy of the human body

The anatomy of the human body can be divided into several systems that work together to maintain life processes. These systems include:

The skeletal system

Bones: The human skeleton consists of 206 bones that provide structure and stability to the body. Bones also serve as protection for internal organs and as attachment points for muscles that enable movement.

Joints: Joints are the connections between bones that allow movement and flexibility. There are different types of joints, including fixed, semi-fixed, and flexible joints.

Cartilage: Cartilage is a flexible connective tissue found in joints that protects bones from friction.

The muscular system

Muscles: The human body contains over 600 muscles responsible for movement, posture, and heat production. Muscles are divided into three main types: skeletal muscle, smooth muscle, and cardiac muscle.

Tendons and ligaments: Tendons connect muscles to bones, while ligaments connect bones to each other and ensure the stability of joints.

The nervous system

Central nervous system (CNS): The CNS consists of the brain and spinal cord. It controls most bodily functions and processes information received from the peripheral nervous system.

Peripheral nervous system (PNS): The PNS includes all nerves outside the central nervous system and is divided into the somatic and autonomic nervous systems. It transmits sensory information to the central nervous system and transmits motor commands to the muscles.

The cardiovascular system

Heart: The heart is a muscular organ that pumps blood throughout the body. It consists of four chambers: two atria and two ventricles.

Blood vessels: Arteries, veins, and capillaries are the main types of blood vessels that transport blood. Arteries carry blood away from the heart, veins return it, and capillaries facilitate the exchange of nutrients and waste products.

The respiratory system

Lungs: The lungs are the main organs of the respiratory system and are responsible for gas exchange. Oxygen is absorbed and carbon dioxide is removed from the blood.

Respiratory tract: The respiratory tract includes the nose, pharynx, larynx, trachea, and bronchi. They carry air to the lungs.

The digestive system

Gastrointestinal tract: The digestive tract begins in the mouth and ends in the anus. It includes the mouth, esophagus, stomach, small intestine, large intestine, and anus.

Digestive organs: The digestive organs include the liver, gallbladder, and pancreas, which produce digestive enzymes and juices that help break down food.

The endocrine system

Glands: The endocrine system consists of glands that produce hormones and release them into the bloodstream. The most important glands include the pituitary gland, thyroid, adrenal glands, and pancreas.

Hormones: Hormones are chemical messengers that regulate various body functions such as metabolism, growth and reproduction.

The immune system

White blood cells: The immune system consists of different types of white blood cells that recognize and fight pathogens.

Lymphatic system: The lymphatic system, including the lymph nodes, spleen and thymus gland, plays an important role in immune defense.

The urinary system

Kidneys: The kidneys filter blood to remove waste and produce urine.

Urinary tract: The urinary tract consists of ureters, bladder and urethra, which transport urine out of the body.

The reproductive system

Male reproductive system: The main components include the testes, vas deferens, and penis.

Female reproductive system: The main components include the ovaries, fallopian tubes, uterus, and vagina.

Physiology of the human body

Physiology studies how the body's various systems function and interact with each other. Here are some key concepts of human physiology:

Homeostasis

Homeostasis is the process by which the body maintains a stable internal environment despite changes in the external environment. This includes the regulation of temperature, pH, fluid, and electrolyte balance.

circulatory system

The heart pumps blood through the arteries to the organs and tissues. Oxygen-rich blood is transported to the systemic circulation, and oxygen-poor blood is transported to the pulmonary circulation, where it is enriched with oxygen.

Respiratory system

Breathing consists of inhaling and exhaling air. Oxygen is absorbed into the blood in the alveoli of the lungs, while carbon dioxide is released from the blood into the alveoli and exhaled.

digestive system

Digestion begins in the mouth and continues in the stomach, where food is broken down mechanically and chemically. Nutrients are absorbed in the small intestine, and water is reabsorbed in the large intestine to form solid stool.

nervous system

The nervous system controls and coordinates all bodily functions through electrical and chemical signals. The central nervous system processes information, while the peripheral nervous system transmits stimuli and executes motor commands.

Endocrine system

Hormones regulate many physiological processes, including metabolism, growth, and reproduction. Hormones are produced by endocrine glands and transported to target cells via the bloodstream.

immune system

The immune system protects the body from infections by recognizing and destroying pathogens. It includes innate and adaptive immune responses that work together to ensure effective defense.

urinary system

The urinary system removes waste and excess substances from the blood and regulates fluid and electrolyte balance. The kidneys filter the blood and produce urine, which is excreted through the urinary tract.

reproductive system

The reproductive system enables reproduction through the production of gametes (sperm and eggs) and supports the development of a new organism. Hormones regulate reproductive functions and the menstrual cycle.

The anatomy and physiology of the human body are complex and fascinating fields of science that require a deep understanding of the structure and function of the various body systems. Each system plays a specific role in maintaining health and well-being. A comprehensive knowledge of anatomy and physiology is fundamental to

Cell biology and biochemical processes

Introduction to Cell Biology

Cell biology is a key branch of biology that deals with the structure, function, and behavior of cells. Cells are the basic building blocks of all living organisms and play a central role in all biological processes. There are two main types of cells: prokaryotic cells, found in bacteria and archaea, and eukaryotic cells, found in plants, animals, fungi, and protists. Eukaryotic cells are more complex and contain various organelles that perform specific functions.

Structure of the cell

cell membrane

The cell membrane is a phospholipid bilayer that surrounds the cell and protects its internal components. It regulates the exchange of substances between the cell's interior and the environment and plays a crucial role in cell communication and signal transduction.

cytoplasm

The cytoplasm is a gel-like substance that contains organelles and provides the environment for many biochemical reactions. It consists primarily of water, proteins, lipids, and other molecules.

cell nucleus

The nucleus is the control center of the cell and contains the genetic material in the form of DNA. The nucleus is surrounded by a nuclear membrane and contains nucleoplasm, chromatin, and the nucleolus. The DNA in the nucleus controls cell activity through gene expression.

Mitochondria

Mitochondria are the energy centers of the cell and are responsible for the production of ATP (adenosine triphosphate) through the process of cellular respiration. They have a double membrane structure and contain their own DNA.

Endoplasmic Reticulum (ER)

The ER is a network of membranes that supports the synthesis and transport of proteins and lipids. There are two types of ER: the rough ER, which is covered with ribosomes and involved in protein synthesis, and the smooth ER, which is involved in lipid synthesis and metabolism.

Ribosomes

Ribosomes are small particles composed of RNA and proteins that are responsible for protein synthesis. They can exist freely in the cytoplasm or be bound to the rough ER.

Golgi apparatus

The Golgi apparatus consists of a series of membrane stacks (cisterns) and is involved in the modification, packaging, and distribution of proteins and lipids derived from the ER.

Lysosomes

Lysosomes are membrane-enclosed organelles containing hydrolytic enzymes that degrade macromolecules. They play a key role in cellular clearance and the digestion of foreign substances and damaged organelles.

cytoskeleton

The cytoskeleton consists of a network of protein filaments and tubules that provide structure and shape to the cell. It is also involved in cell motility, intracellular transport, and cell division.

Biochemical processes in the cell

Cellular respiration

Cellular respiration is the process by which cells produce energy in the form of ATP. It consists of three main phases: glycolysis, the citric acid cycle (Krebs cycle), and the respiratory chain (oxidative phosphorylation).

Glycolysis: This process takes place in the cytoplasm and converts glucose into pyruvate, producing ATP and NADH.

Citric acid cycle: Pyruvate is transported into the mitochondria and converted into acetyl-CoA, which then enters the citric acid cycle. Here, CO₂ , ATP, NADH, and FADH₂ are produced.

Respiratory chain: In the inner mitochondrial membrane, NADH and FADH transfer electrons through a series of protein complexes. This leads to the production of ATP through oxidative phosphorylation and the release of water.

photosynthesis

Photosynthesis is the process by which plants, algae, and some bacteria convert sunlight into chemical energy. This process takes place in the chloroplasts and involves two main phases: the light reactions and the Calvin cycle.

Light reactions: In the thylakoid membrane, chlorophyll and other pigments absorb light energy, which leads to the splitting of water and the production of ATP and NADPH.

Calvin cycle: In the stroma of the chloroplast, CO₂ is converted into glucose through a series of enzyme-catalyzed reactions, consuming ATP and NADPH.

Protein biosynthesis

Protein biosynthesis is the process by which cells make proteins. It consists of two main steps: transcription and translation.

Transcription: In the cell nucleus, DNA is transcribed into an mRNA sequence. This mRNA is then transported into the cytoplasm.

Translation: In the ribosomes, the mRNA is translated into an amino acid sequence that forms a protein. tRNA molecules carry the appropriate amino acids to the ribosomes, where they are joined together according to the mRNA sequence.

DNA replication and cell division

DNA replication is the process by which DNA is duplicated before the cell divides. This occurs during the S phase of the cell cycle. Cell division occurs by either mitosis or meiosis:

Mitosis: This process leads to the formation of two genetically identical daughter cells from one mother cell and consists of several phases: prophase, metaphase, anaphase and telophase.

Meiosis: This type of cell division is responsible for the formation of gametes (eggs and sperm) and results in four genetically distinct daughter cells. It consists of two consecutive divisions: meiosis I and meiosis II.

Signal transduction

Signal transduction is the process by which cells respond to external signals. This involves the binding of a signaling molecule (ligand) to a receptor on the cell surface, leading to a cascade of intracellular events. These signals can regulate cellular functions such as growth, differentiation, apoptosis, and metabolism.

Receptor tyrosine kinases (RTKs): These receptors bind growth factors and activate intracellular signaling cascades that promote cell proliferation and survival.

G protein-coupled receptors (GPCRs): These receptors bind a variety of ligands and activate intracellular signals through G proteins that control numerous cellular processes.

Ionotropic and metabotropic receptors: These receptors regulate ion concentrations in cells and modulate neuronal activities and other physiological processes.

Summary

Cell biology and biochemical processes are fundamental to understanding life processes. Cells, as the smallest living units, possess specialized structures and carry out complex biochemical reactions that make life possible. From energy production to protein synthesis to signal transduction, these processes contribute to the homeostasis and function of the entire organism. A deep understanding of these processes is essential for the development of medical therapies and the promotion of human health.

The immune system and how it works

introduction

The immune system is a complex network of cells, tissues, and organs that protects the body from pathogens such as bacteria, viruses, fungi, and parasites. It plays a central role in maintaining health and fighting off infections. The immune system can be divided into two main components: the innate immune system and the adaptive immune system. Both work together to protect the body and maintain homeostasis.

Components of the immune system

Innate immune system

The innate immune system is the body's first line of defense and responds rapidly to infections. It includes physical barriers, cellular defense mechanisms, and chemical defenses.

Physical barriers

Skin: The skin forms an impermeable barrier against many pathogens.

Mucous membranes: Mucous membranes in the respiratory tract, gastrointestinal tract and urogenital system produce mucus that traps pathogens and prevents their penetration.

Tears and saliva: These body fluids contain enzymes such as lysozyme that kill bacteria.

Cellular defense mechanisms

Phagocytes: These include macrophages and neutrophil granulocytes, which ingest and destroy pathogens through phagocytosis.

Natural killer cells (NK cells): These cells recognize and kill virus-infected cells and tumor cells without prior sensitization.

Chemical defense substances

Complement system: A group of proteins that mark pathogens and promote their destruction.

Cytokines: Signaling proteins that promote communication between cells of the immune system and regulate their activity.

Adaptive immune system

The adaptive immune system is more specialized and develops a targeted response to specific pathogens. It is characterized by the ability to form immunological memory, meaning it can respond more quickly and effectively in the event of a re-infection.

Lymphocytes

B cells: These cells produce antibodies that recognize and neutralize specific antigens.

T cells: There are different types of T cells, including T helper cells, which coordinate the immune response, and cytotoxic T cells, which directly kill infected cells.

Antigen presentation

Dendritic cells and macrophages: These cells take up antigens, process them, and present them on their surface to activate T cells.

How the immune system works

Detection of pathogens

Pathogen recognition occurs through pattern recognition receptors (PRRs) on cells of the innate immune system. These receptors recognize conserved molecular patterns that are present in many pathogens but not in host cells.

Inflammatory reaction

An inflammatory response is initiated by the release of cytokines and chemokines produced by infected or damaged cells. These signaling molecules promote the migration of immune cells to the site of infection, increase blood vessel permeability, and induce fever, which inhibits the proliferation of pathogens.

Phagocytosis

Phagocytes such as macrophages and neutrophils ingest pathogens and destroy them in specialized vesicles called phagolysosomes. The pathogens are degraded by acidic enzymes and reactive oxygen species.

Antigen presentation and activation of the adaptive immune system

After phagocytosis, dendritic cells and macrophages present antigens on their surface. These antigens are bound to MHC (major histocompatibility complex) molecules and recognized by T cells. T helper cells are activated and promote the activation and differentiation of B cells and cytotoxic T cells.

Production of antibodies

Activated B cells differentiate into plasma cells, which produce large amounts of specific antibodies. These antibodies bind to antigens on the surface of pathogens, marking them for destruction by phagocytes or neutralizing them directly.

Cytotoxic reaction

Cytotoxic T cells recognize and bind to infected cells that present antigens on their MHC I molecules. By releasing perforin and granzymes, cytotoxic T cells induce programmed cell death (apoptosis) in the infected cells.

Immunological memory

An important aspect of the adaptive immune system is the formation of immunological memory. After the initial infection, memory cells (memory B and T cells) remain in the body, which can respond more quickly and effectively to a re-infection with the same pathogen.

Disorders of the immune system

Autoimmune diseases

In autoimmune diseases, the immune system mistakenly attacks the body's own tissues. Examples include rheumatoid arthritis, lupus erythematosus, and type 1 diabetes.

immunodeficiency

Immunodeficiency can be congenital (e.g., severe combined immunodeficiency, SCID) or acquired (e.g., due to HIV/AIDS). Those affected have an increased risk of infections and tumors.

Allergies

Allergies are hypersensitivity reactions of the immune system to harmless substances (allergens). Examples include hay fever, asthma, and food allergies.

Therapeutic applications and vaccinations

Immunotherapy

Immunotherapies aim to modulate the immune system to treat diseases. Examples include the treatment of cancer with checkpoint inhibitors and the therapy of autoimmune diseases with immunosuppressive drugs.

vaccinations

Vaccinations are an effective method for preventing infectious diseases. They stimulate the immune system to develop an immune response and memory cells against specific pathogens without the need for natural infection.

Summary

The immune system is a highly complex network that protects the body from a wide variety of pathogens. It consists of the innate and adaptive immune systems, which work together to ensure effective defense. The immune system's ability to recognize, neutralize, and destroy pathogens is critical for maintaining health. A thorough understanding of how the immune system works is essential for the development of new therapeutic approaches and vaccines that help combat infectious diseases and other immunological disorders.

MSM and its properties

Chemical structure and properties of MSM

Chemical structure of MSM

Methylsulfonylmethane (MSM) is an organic sulfur compound with the chemical formula ( CH3)2SO2(CH3)2SO2 ( CH3 ) 2SO2 . It is also known as dimethylsulfone and methylsulfone. The chemical structure of MSM consists of two methyl groups (-CH3 ) and one sulfonyl group (-SO2) bonded to a central carbon atom. The structure of MSM can be represented as follows:

mathematics

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H H

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H — C — S — C — H

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H H