Mesenchymal Cells: The Stem Cells of the Human Skeleton

Mesenchymal cells are the primary stem cells of the human skeleton. These multipotent cells originate in the bone marrow and have the ability to differentiate into various cell types. Osteoblasts, responsible for bone formation, chondrocytes, which give rise to cartilage, and adipocytes, specialized in storing energy as fat, are some of the cells that mesenchymal cells can produce. Muscle cells, or myocytes, arise from muscle satellite cells, while skin cells come from epithelial stem cells. Neurons mostly arise from neural stem cells, although some may come from astrocytes. White blood cells, on the other hand, come from hematopoietic stem cells. Mesenchymal cells play a crucial role in the maintenance and repair of the human skeleton, making them an essential area of study in regenerative medicine.

The Oxygen Dissociation Curve and its Effects on Oxygen Saturation

The oxygen dissociation curve is a graph that compares the oxygen saturation of hemoglobin (Hb) at different partial pressures of oxygen. When more oxygen is needed by the tissues, the curve shifts to the right. This means that at the same partial pressure of oxygen, less oxygen is bound to Hb, allowing it to be released to the tissues. This effect is caused by increased levels of CO2 and temperature, which assist in the transfer of oxygen to more metabolically active tissues. Additionally, increased levels of 2,3-DPG also aid in this process.

On the other hand, a left shift in the curve reflects conditions where there is less need for oxygen in the tissues, such as in the lungs. This allows for increased binding of oxygen to Hb, allowing it to be taken up before transport to the tissues that require it. Overall, the oxygen dissociation curve plays a crucial role in regulating oxygen saturation in the body and ensuring that oxygen is delivered to the tissues that need it most.

How MRI Scanners Use Hydrogen Ions to Create Images

MRI scanners use the magnetic properties of hydrogen ions, also known as protons, to create images of the human body. These protons have nuclear spin, which means they have magnetic vectors that can be aligned in an electromagnet. The scanner bombards the protons with radiofrequency radiation, causing them to release energy when they return to their resting state. This energy release is recorded and used to construct the MRI image.

While other nuclei, such as carbon 13, also have net nuclear spin and could be used in MRI imaging, hydrogen ions are much more abundant in human tissues. This makes them the preferred choice for creating images of the body. By using the magnetic properties of hydrogen ions, MRI scanners can create detailed images of internal structures without the use of harmful radiation.

Huntington’s Disease

Huntington’s disease is a genetic disorder that typically appears later in life and is characterized by symptoms such as chorea, cognitive decline, and personality changes. It is an autosomal dominant disease, meaning that there is a 50% chance of passing it on to offspring. If the gene is inherited from an unaffected parent, the child will not be affected. This is different from autosomal recessive inheritance, where both parents must pass on the gene for it to affect their children.

The disease is caused by an increase in the length of a repeating trinucleotide sequence (CAG) in the Huntington protein. This sequence can change in length through generations, and longer sequences are associated with earlier onset of symptoms (genetic anticipation). Since Huntington’s disease usually presents itself after people have already started their families, there are many issues associated with genetic testing.

Techniques in Biochemistry

Over-the-counter urine pregnancy tests use ELISA to detect beta-HCG in a woman’s urine. The test stick contains antibodies that react with beta-HCG, producing a color change that confirms pregnancy. The urinary pregnancy test is a solid-phase ELISA, where the antibody is immobilized on a specialized filter paper. The fluid travels laterally across the paper to bind with the antibody, and if beta-HCG is present, the line turns blue. Electrophoresis characterizes the electrical charge and size of substances, while PCR identifies specific sequences of DNA or RNA. Radioimmunoassay uses radioactivity to identify specific proteins. Enzymatic degradation breaks down large proteins into smaller subunits for which target antibodies may already exist. This method is used to characterize large proteins for which the structure has not yet been described.

The Relationship between Alveolar Size and Surface Tension in Respiratory Physiology

In respiratory physiology, the alveolus is often represented as a perfect sphere to apply Laplace’s law. According to this law, there is an inverse relationship between the size of the alveolus and the surface tension. This means that smaller alveoli experience greater force than larger alveoli for a given surface tension, and they will collapse first. This phenomenon explains why, when two balloons are attached together by their ends, the smaller balloon will empty into the bigger balloon.

In the lungs, this same principle applies to lung units, causing atelectasis and collapse when surfactant is not present. Surfactant is a substance that reduces surface tension, making it easier to expand the alveoli and preventing smaller alveoli from collapsing. Therefore, surfactant plays a crucial role in maintaining the proper functioning of the lungs and preventing respiratory distress. the relationship between alveolar size and surface tension is essential in respiratory physiology and can help in the development of treatments for lung diseases.

The Versatility of Amino Acids and its Applications in Electrophoresis

Amino acids are the building blocks of proteins and are composed of a basic structure of H2N – CHR – COOH, where R represents the variable group that distinguishes one amino acid from another. The simplest amino acid is glycine, where the R group is just H. Amino acids are capable of forming complex and useful molecules due to their dipolar or amphoteric nature, which makes them simultaneously acidic and basic. In solution, they form zwitterions, which can act as either an acid or a base depending on the pH of the solution. This versatility of amino acids is what allows for the process of electrophoresis, which separates proteins based on their charge in a solution. By using solutions of different pH, different proteins can be assessed, making it a useful tool in the diagnosis of bone marrow malignancies like myeloma.

Thiamine: Its Roles, Sources, Deficiency States, and Manifestations

Thiamine is a vital nutrient that plays several roles in the body. It acts as a cofactor to enzymes involved in energy production, metabolism of branched chain amino acids, and regulation of nerve and muscle action potentials. It is found in many foods, including wheat, oats, and yeast-containing products. However, deficiency states can occur in chronic alcohol dependence, renal dialysis, and cultures that mainly consume white rice. The deficiency can manifest as ‘dry’ beriberi, which causes peripheral neuropathy, muscle weakness, fatigue, and reduced concentration, or ‘wet’ beriberi, which also involves heart failure and edema. In severe cases, Wernicke-Korsakoff syndrome can develop, which is an emergency requiring urgent IV replacement of thiamine. If left untreated, it can lead to irreversible amnesia, confabulation, and dementia. Therefore, all patients with alcohol-related admissions should be considered for Pabrinex, a B vitamin infusion.

The Nucleolus: Structure and Function

The nucleolus is a non-membrane-bound structure that takes up about a quarter of the nuclear volume. It is composed mainly of proteins and nucleic acids and is responsible for transcribing ribosomal RNA (rRNA) and assembling ribosomes in the cell. Nucleoli are formed in nucleolar organizing regions (NORs), which are also the regions of the genes for three of the four eukaryotic rRNAs.

During ribosome assembly, ribosomal proteins enter the nucleolus from the cytoplasm and begin to assemble on an rRNA precursor. As the pre-rRNA is cleaved to produce 5.8S, 18S, and 28S rRNAs, additional ribosomal proteins and the 5S rRNA (which is synthesized elsewhere in the nucleus) assemble to form preribosomal subunits. These subunits then exit the nucleolus into the cytoplasm and combine to produce the final 40S and 60S ribosomal subunits.

Overall, the nucleolus plays a crucial role in protein synthesis by producing the components necessary for ribosome assembly. Its unique structure and function make it an essential component of the cell’s machinery.

Lipid Metabolism and Transport in the Body

The breakdown of triglycerides in the small intestine is facilitated by pancreatic lipase. These triglycerides are then transported to the liver and other parts of the body through chylomicrons.

Very low-density lipoprotein (VLDL) is responsible for carrying triglycerides from the liver to peripheral tissues. When there is an overproduction of VLDL in the liver, it can lead to high levels of triglycerides in the body.

Pure hypercholesterolaemia is a condition that arises due to a defect in the process of cholesterol uptake into cells. This process relies on apolipoprotein B-100 binding to LDL receptors and facilitating endocytosis. When this process is disrupted, it can lead to high levels of cholesterol in the body.

The Process of Meiosis

Meiosis is a complex process that involves two major cycles. The first cycle, meiosis I, condenses the reproductive cell’s DNA into chromosomes that are then replicated, creating two pairs of each original chromosome. These pairs are then separated, and the cell divides with one chromosome in each daughter cell. The second cycle, meiosis II, splits the chromosomes into individual chromatids, which are then separated as in meiosis I. This separation is facilitated by a spindle, a set of parallel fibers that attach to the center of each chromosome and split into two, making the chromatids travel on the polar opposite sides of the cell. The cell then divides again, giving rise to four haploid daughter cells.

During meiosis II, the chromosomes align on the spindle in metaphase II. Tetrads separate during anaphase I and line up during metaphase I. Sister chromatids separate on the meiotic spindle during anaphase II. Finally, chromosomes uncoil and lengthen at the end of meiosis, in telophase II. This process is essential for the production of gametes and the continuation of sexual reproduction in many organisms.

Acid-Base Imbalances in Different Medical Conditions

Poorly controlled diabetes can cause the breakdown of fatty acids, leading to the production of ketones as an alternative energy source. However, an excess of ketones can result in metabolic acidosis due to their acidic nature. On the other hand, chronic obstructive pulmonary disease (COPD) and suffocation can cause the retention of carbon dioxide, leading to respiratory acidosis. In COPD, there may be a compensatory metabolic alkalosis. Voluntary hyperventilation can cause respiratory alkalosis due to the reduction of carbon dioxide. Vomiting can also lead to metabolic alkalosis. Diabetic ketoacidosis is a complication of type 1 diabetes that results in high blood sugar levels, ketone production, and acidosis.

In summary, different medical conditions can cause acid-base imbalances in the body. It is important to identify the underlying cause of the imbalance to provide appropriate treatment.

The Stages of Prophase in Eukaryotic Mitosis

Prophase is the first stage of eukaryotic mitosis, except for plant cells which have a preprophase stage. During prophase, the cell’s chromatin, which is made up of DNA and associated proteins, condenses into double rod-shaped structures called chromosomes. This process is facilitated by the condensin protein I and/or II complexes. As the chromosomes form, the nuclear membrane and nucleoli disintegrate and disappear, making the chromatin visible.

Before prophase, the cell’s DNA is replicated during interphase, resulting in identical pairs of chromosomes called chromatids. These chromatids attach to each other at a DNA element called the centromere. DNA and centrosome duplication occur during interphase, while chromosome alignment takes place during metaphase. The nuclear membrane and nucleoli re-form during telophase, and the sister chromatids separate during anaphase.

In summary, prophase is the initial stage of eukaryotic mitosis where chromatin condenses into chromosomes, and the nuclear membrane and nucleoli disappear. Chromosome alignment, DNA and centrosome duplication, and re-formation of the nuclear membrane and nucleoli occur in subsequent stages.

The Functions of Endoplasmic Reticulum and Lysosomes

The endoplasmic reticulum (ER) is a complex network of membranes that is divided into two types: rough and smooth. The rough ER is characterized by the presence of ribosomes on its cytosolic side, which makes it an important site for protein production, modification, and transport. On the other hand, the smooth ER is involved in cholesterol and steroid handling, as well as calcium storage in some cells. This type of ER is particularly prominent in cells that produce large amounts of steroid hormones, such as those found in the adrenal cortex.

Lysosomes, on the other hand, are organelles that are responsible for breaking down and recycling cellular waste. They are formed by the Golgi apparatus, which is another complex network of membranes found in eukaryotic cells. Lysosomes contain a variety of enzymes that are capable of breaking down different types of molecules, including proteins, lipids, and carbohydrates.

In summary, the ER and lysosomes are two important organelles in eukaryotic cells that play different roles in cellular metabolism. While the ER is involved in protein production, modification, and transport, the lysosomes are responsible for breaking down and recycling cellular waste.

The Significance of Prometaphase in Cell Division

Prometaphase is a crucial phase in cell division that marks the transition from prophase to metaphase. Although it is often considered as a part of these two phases, it has distinct events that make it an individual phase. During prometaphase, the nuclear membrane disintegrates, and the nucleoli are no longer visible. Additionally, each chromosome forms two kinetochores near the centromere, which serve as attachment points for spindle fibers. These fibers connect to the opposite poles of the cell, forming travelling lines that will separate the sister chromatids during anaphase.

Prophase is characterized by chromatin condensation, while DNA and centrosome duplication occur during interphase. Chromosome alignment takes place during metaphase, and the sister chromatids separate during anaphase. Prometaphase, therefore, plays a crucial role in preparing the chromosomes for separation during anaphase. Its distinct events make it an essential phase in cell division, and its proper execution is necessary for successful cell division.

Cystic Fibrosis Inheritance

Cystic fibrosis (CF) is a genetic disorder that affects the chloride ion channels, leading to the thickening of respiratory and other secretions. It is an autosomal recessive condition, which means that a person must inherit two copies of the defective gene, one from each parent, to develop the disease. The most common defective allele is carried by approximately 1 in 20 people.

If a man with CF has children with a woman who does not carry the recessive gene, then none of their children will be affected by the disease. However, they will all be carriers of the CF gene. On the other hand, if the woman is a carrier of the CF gene, there is a 50% chance that each child will inherit one copy of the defective gene from each parent and be affected by the disease. The remaining 50% of the children will inherit one copy of the defective gene and one normal gene, making them carriers of the CF gene but not affected by the disease.

In summary, the probability of any child being affected by CF is 2.5% if one parent has the defective gene and the other does not. It is important for individuals who are carriers of the CF gene to be aware of their status and seek genetic counseling before planning to have children.

The Golgi Apparatus, Cell Division, and Homeostasis

The Golgi apparatus is a structure found in eukaryotic cells that consists of flattened membrane stacks. Its primary function is to modify proteins that have been synthesized in the rough endoplasmic reticulum, preparing them for secretion or transport within the cell. However, the Golgi apparatus is not directly involved in cell division, which is controlled by the nucleus.

Cell homeostasis, on the other hand, is primarily maintained by membrane-embedded channels or proteins such as the sodium-potassium pump. This mechanism ensures that the cell’s internal environment remains stable. The sodium-potassium pump is an active transport mechanism that involves the binding of three intracellular sodium ions to the protein. Adenosine triphosphate (ATP) donates a phosphate group to the protein, which causes it to change shape and release the sodium ions out of the cell.

The protein then accepts two extracellular potassium ions, and the donated phosphate group detaches, causing the protein to revert to its original shape. This allows the potassium ions to enter the cell, increasing the intracellular potassium concentration and decreasing the intracellular sodium concentration. This process is in contrast to the extracellular conditions.

In summary, the Golgi apparatus modifies proteins for secretion or transport, while cell division is controlled by the nucleus. Cell homeostasis is maintained by membrane-embedded channels or proteins such as the sodium-potassium pump, which actively transports ions to stabilize the cell’s internal environment.

The Electron Transport Chain in Mitochondria

The electron transport chain (ETC) is a crucial process in cellular aerobic respiration that occurs in the mitochondrial cristae. These are folded membranes inside the organelle. During respiration, NADH and FADH produced from other parts of the process, such as glycolysis, transfer electrons from electron donors to electron acceptors through redox reactions. This electron transfer is coupled with proton transfer across the mitochondrial membrane, creating an electrochemical proton gradient. This gradient induces the production of ATP, which is used as an energy currency by the cell.

ATP is produced through a mechanism called chemiosmotic phosphorylation. The structure of the mitochondrion is essential for this process to occur. The cristae provide a large surface area for the ETC to take place, and the mitochondrial membrane is impermeable to protons, allowing for the creation of the proton gradient. The inner membrane also contains ATP synthase, the enzyme responsible for producing ATP through chemiosmotic phosphorylation.

In summary, the electron transport chain in mitochondria is a complex process that involves the transfer of electrons and protons across the mitochondrial membrane to create a proton gradient. This gradient is then used to produce ATP through chemiosmotic phosphorylation. The structure of the mitochondrion is crucial for this process to occur efficiently.

The Relationship between Alveolar Size and Surface Tension in Respiratory Physiology

In respiratory physiology, the alveolus is often represented as a perfect sphere to apply Laplace’s law. According to this law, there is an inverse relationship between the size of the alveolus and the surface tension. This means that smaller alveoli experience greater force than larger alveoli for a given surface tension, causing them to collapse first. This phenomenon is similar to what happens when two balloons of different sizes are attached together, with the smaller balloon emptying into the larger one.

In the lungs, this collapse of smaller alveoli can lead to atelectasis and collapse if surfactant is not present. Surfactant is a substance that reduces surface tension, making it easier to expand the alveoli and preventing smaller alveoli from collapsing. this relationship between alveolar size and surface tension is crucial in respiratory physiology, as it helps explain the importance of surfactant in maintaining proper lung function.

Diagnostic Methods for Deep Vein Thrombosis

When it comes to diagnosing deep vein thrombosis (DVT), there are several methods available. The most common ones are Doppler studies and venography. Doppler studies use B mode ultrasonography to examine the venous system, while venography involves injecting a contrast dye into the veins and taking X-rays. CT scans are not typically used for DVT diagnosis because they require contrast and expose the patient to radiation. D-Dimer concentrations can help rule out DVT if they are negative, but they cannot diagnose it. MRI scans are useful for examining soft tissues and bones, but they are not the best option for visualizing the vasculature. Finally, oxygen saturation of the limbs is not a reliable diagnostic method because tissue perfusion can be the same even if there is arterial disease. Overall, Doppler studies and venography are the most effective methods for diagnosing DVT.

Xeroderma Pigmentosum and DNA Repair

Deoxyribonucleic acid (DNA) found in the skin cells can absorb ultraviolet (UV) light, which can cause the formation of pyrimidine dimers. These dimers are removed through a process called excision repair, where the damaged DNA is cut out and replaced with new DNA. However, if this process fails, it can lead to mutations in genes that suppress tumors or promote their growth, potentially leading to cancer.

Xeroderma pigmentosum is a genetic disorder that is inherited in an autosomal recessive pattern. This means that an individual must inherit two copies of the mutated gene, one from each parent, to develop the disorder. Generally, disorders that affect metabolism or DNA replication on a cellular or genetic level are inherited in an autosomal recessive pattern. On the other hand, genetic disorders that affect larger structural components are usually inherited in an autosomal dominant pattern. While there are exceptions to these rules, they can serve as a helpful guide for exam preparation.

Tests for Assessing Arterial and Venous Circulation, Hip Dysfunction, and Meniscal Tear

Buerger’s test is a method used to evaluate the arterial circulation of the lower limb. The test involves observing the angle at which blanching occurs, with a lower angle indicating a higher likelihood of arterial insufficiency. Additionally, the degree of reactive hyperaemia on dependency of the limb after one minute is another positive sign of arterial insufficiency during the test.

Another test used to assess circulation is the Ankle-Brachial Pressure Index (ABPI), which involves using blood pressure cuffs to determine the degree of claudication. McMurray’s test, on the other hand, is used to evaluate for a meniscal tear within the knee joint.

Perthe’s test is a method used to assess the patency of the deep femoral vein prior to varicose vein surgery. Lastly, Trendelenburg’s test is used to evaluate hip dysfunction. These tests are important in diagnosing and treating various conditions related to circulation and joint function.

The Versatility of Pyruvic Acid in Cellular Metabolism

Pyruvic acid is a simple alpha-keto acid that plays a crucial role in several metabolic pathways within the cell. It serves as a central intersection where different pathways converge and diverge. One of the primary ways pyruvic acid is produced is through glycolysis, where glucose is broken down into pyruvic acid. Depending on the cell’s needs, pyruvic acid can be converted back into glucose through gluconeogenesis or used to synthesize fatty acids through the acetyl-CoA pathway. Additionally, pyruvic acid can be used to produce the amino acid alanine.

Pyruvic acid is also involved in respiration, where it enters the Krebs cycle under aerobic conditions. This cycle produces energy in the form of ATP, which is used by the cell for various functions. Under anaerobic conditions, pyruvic acid can ferment into lactic acid, which is used by some organisms as a source of energy.

In summary, pyruvic acid is a versatile molecule that plays a critical role in cellular metabolism. Its ability to be converted into different molecules depending on the cell’s needs makes it an essential component of many metabolic pathways.

Absorption of Fat-Soluble Vitamins

Fat-soluble vitamins, namely A, D, E, and K, have a different absorption process compared to water-soluble vitamins. In the gut, these vitamins are combined with other fat-soluble substances such as monoacylglycerols and cholesterol to form micelles. These micelles are then transported to the lymphatic system and eventually enter the bloodstream through the subclavian vein.

However, any issues that affect the absorption of fats will also impact the absorption of fat-soluble vitamins. This means that individuals with conditions that affect fat absorption, such as cystic fibrosis or celiac disease, may have difficulty absorbing these vitamins. It is important to ensure adequate intake of fat-soluble vitamins through a balanced diet or supplements to prevent deficiencies and associated health problems.

Gas Laws

Gas laws are a set of scientific principles that describe the behavior of gases under different conditions. One of these laws is Avogadro’s law, which states that equal volumes of gases at a standardized temperature and pressure contain the same number of molecules. Another law is Boyle’s law, which explains that gases expand when the temperature is increased. Charles’ law, on the other hand, states that the pressure of a gas is inversely proportional to its volume at a standardized temperature. Lastly, Graham’s law explains that the rate of diffusion of a gas is in inverse proportion to its weight. The specific gas laws that you need to know may vary depending on your syllabus, but you should be able to recognize and apply them if given the formulae. It is unlikely that you will be expected to know the correct formula.

Regulation of the Cell Cycle by Cyclins and Cyclin-Dependent Kinases

The cell cycle is controlled by the activity of proteins known as cyclins and phosphorylating enzymes called cyclin-dependent kinases (CDKs). Cyclins and CDKs combine to form an activated heterodimer, where cyclins act as the regulatory subunits and CDKs act as the catalytic subunits. Neither of these molecules is active on their own. When a cyclin binds to a CDK, the CDK phosphorylates other target proteins, either activating or deactivating them. This coordination leads to the entry into the next phase of the cell cycle. The specific proteins that are activated depend on the different combinations of cyclin-CDK. Additionally, CDKs are always present in cells, while cyclins are produced at specific points in the cell cycle in response to other signaling pathways.

In summary, the cell cycle is regulated by the interaction between cyclins and CDKs. This interaction leads to the phosphorylation of target proteins, which ultimately controls the progression of the cell cycle.

Poiseuille’s Equation and Fluid Flow in Cylinders

Poiseuille’s equation is used to describe the flow of non-pulsatile laminar fluids through a cylinder. The equation states that the flow rate is directly proportional to the pressure driving the fluid and the fourth power of the radius. Additionally, it is inversely proportional to the viscosity of the fluid and the length of the tube. This means that a short, wide cannula with pressure on the bag will deliver fluids more rapidly than a long, narrow one.

It is important to note that even small changes in the radius of a tube can greatly affect the flow rate. This is because the fourth power of the radius is used in the equation. Therefore, any changes in the radius will have a significant impact on the flow rate. Poiseuille’s equation is crucial in determining the optimal conditions for fluid delivery in medical settings.

Carbohydrates: Building Blocks of Energy and Storage

Carbohydrates are organic compounds made up of carbon, hydrogen, and oxygen, with a general formula of Cx(H2O)y. They can be classified as either aldehydes or ketones and contain multiple hydroxyl groups. Monosaccharides are the simplest form of carbohydrates, consisting of a single unit. They are categorized based on the number of carbon atoms they contain, with trioses having three, pentoses having five, and hexoses having six carbon atoms. These monosaccharides are essential for energy production and building larger carbohydrate structures.

Disaccharides are formed when two monosaccharides are joined together through a condensation reaction, releasing a water molecule. The most common disaccharides are lactose, maltose, and sucrose. Polysaccharides, on the other hand, are long, branched polymers made up of multiple single units. They serve as convenient storage molecules for energy reserves, such as glycogen in humans and starch in plants.

In summary, carbohydrates are vital building blocks for energy production and storage in living organisms. Monosaccharides, disaccharides, and polysaccharides all play important roles in maintaining the body’s energy balance and overall health.

ELISA: A Common Immunoassay in Medical Diagnostic Testing

An enzyme-linked immunosorbent assay (ELISA) is a type of immunoassay that is widely used in medical diagnostic testing. This method uses antibodies to identify and/or quantify the analyte being tested. The ELISA process involves several steps, including coating a plate with the antigen, adding the patient’s sample, washing the plate to remove any unbound material, adding an enzyme-linked antibody, washing the plate again, and adding a substrate to produce a measurable signal.

Over time, many modifications have been made to the ELISA, making it a versatile tool in the laboratory for measuring various analytes. Some of the substances that can be measured using immunoassays include thyroid hormone, testosterone, oestrogen, troponin, and vitamin D. The ELISA has been around for a long time and is still widely used today due to its accuracy, sensitivity, and specificity.

Electrophoresis: Separating Molecules Based on Charge and Mass

Electrophoresis is a technique that separates solutes, molecules, or nucleic acids based on their mass and charge. It involves the migration of charged particles in a liquid medium under the influence of an electric field. The apparatus consists of two electrodes placed at either end of a support medium, or gel, which is suspended in a buffer solution. The sample is inserted into a well and a current is applied. Over time, positively charged solutes move towards the negative electrode, while negatively charged substances move towards the positive electrode. Once the migration is complete, the gel is removed and stained to color the substance being tested for, such as protein.

This technique is widely used in medical testing, but it requires a higher degree of operational and interpretive skill than many other tests, which is why it often takes longer to get a result. Electrophoresis has various uses and adaptations, such as standard electrophoresis for protein detection in the diagnosis of myeloma, identification of unusual lipid fractions in patients with inherited diseases, and detection of viral DNA through Southern Blotting. There is also Northern blotting, primarily a research technique at present, which uses electrophoresis to separate RNA. Additionally, Western blotting is used to test for the presence of antibodies to DNA through protein separation.