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Neuron

Gist

A neuron, or nerve cell, is the fundamental unit of the nervous system, specialized to transmit information via electrical and chemical signals, enabling functions from thinking and feeling to movement, and forms the basis of the brain and nerves throughout the body. Structurally, a neuron typically consists of a cell body (soma), dendrites that receive signals, and an axon that transmits signals to other cells.

The basic functions of neurons can be summarized into four main tasks: receiving signals, integrating these signals/generating signals and transmitting the signals to target cells and organs. These functions reflect in the microanatomy of the neuron.

Summary

A neuron (American English), neurone (British English), or nerve cell, is an excitable cell that fires electric signals called action potentials across a neural network in the nervous system, mainly in the central nervous system and help to receive and conduct impulses. Neurons communicate with other cells via synapses, which are specialized connections that commonly use minute amounts of chemical neurotransmitters to pass the electric signal from the presynaptic neuron to the target cell through the synaptic gap.

Neurons are the main components of nervous tissue in all animals except sponges and placozoans. Plants and fungi do not have nerve cells. Molecular evidence suggests that the ability to generate electric signals first appeared in evolution some 700 to 800 million years ago, during the Tonian period. Predecessors of neurons were the peptidergic secretory cells. They eventually gained new gene modules which enabled cells to create post-synaptic scaffolds and ion channels that generate fast electrical signals. The ability to generate electric signals was a key innovation in the evolution of the nervous system.

Neurons are typically classified into three types based on their function. Sensory neurons respond to stimuli such as touch, sound, or light that affect the cells of the sensory organs, and they send signals to the spinal cord and then to the sensorial area in the brain. Motor neurons receive signals from the brain and spinal cord to control everything from muscle contractions to glandular output. Interneurons connect neurons to other neurons within the same region of the brain or spinal cord. When multiple neurons are functionally connected together, they form what is called a neural circuit.

A neuron contains all the structures of other cells such as a nucleus, mitochondria, and Golgi bodies but has additional unique structures such as an axon, and dendrites. The soma or cell body, is a compact structure, and the axon and dendrites are filaments extruding from the soma. Dendrites typically branch profusely and extend a few hundred micrometers from the soma. The axon leaves the soma at a swelling called the axon hillock and travels for as far as 1 meter in humans or more in other species. It branches but usually maintains a constant diameter. At the farthest tip of the axon's branches are axon terminals, where the neuron can transmit a signal across the synapse to another cell. Neurons may lack dendrites or have no axons. The term neurite is used to describe either a dendrite or an axon, particularly when the cell is undifferentiated.

Most neurons receive signals via the dendrites and soma and send out signals down the axon. At the majority of synapses, signals cross from the axon of one neuron to the dendrite of another. However, synapses can connect an axon to another axon or a dendrite to another dendrite. The signaling process is partly electrical and partly chemical. Neurons are electrically excitable, due to the maintenance of voltage gradients across their membranes. If the voltage changes by a large enough amount over a short interval, the neuron generates an all-or-nothing electrochemical pulse called an action potential. This potential travels rapidly along the axon and activates synaptic connections as it reaches them. Synaptic signals may be excitatory or inhibitory, increasing or reducing the net voltage that reaches the soma.

In most cases, neurons are generated by neural stem cells during brain development and childhood. Neurogenesis largely ceases during adulthood in most areas of the brain.

Details

The nervous system consists of two main cell types, neurons and supporting glial cells. The neuron (or nerve cell) is the functional unit of both the central nervous system (CNS) and the peripheral nervous system (PNS). The basic functions of neurons can be summarized into four main tasks: receiving signals, integrating these signals/generating signals and transmitting the signals to target cells and organs. These functions reflect in the microanatomy of the neuron. As such, neurons typically consist of four main functional parts which include the:

* Receptive part (dendrites), which receive and conduct electrical signals toward the cell body
* Integrative part (usually equated with the cell body/soma), containing the nucleus and most of the cell's organelles, acting as the trophic center of the entire neuron. More importantly, it is here where inputs are processed and integrated to determine whether an electrical impulse (action potential) will be generated.
* Conductive part (axon), which conducts electrical impulses away from the cell body.
* Transmissive part (axon terminals), where axons communicate with other neurons or effectors (target structures which respond to nerve impulses)

Neurons are categorized into different types based on their unique morphologies and functions. This article will focus on the structure and physiology of a typical multipolar neuron, the primary neuronal type found in the CNS, and explore its parts and functions in greater detail.

Neurons: Structure and types:

Neuron structure

Description: Spherical or polygonal central component of a neuron
Function: Integration and signal processing, protein synthesis, metabolic activities
Components: Nucleus (DNA), cytoplasmic organelles (endoplasmic reticulum (smooth and rough), Golgi apparatus, microtubules, mitochondria, lysosomes), axon hillock

Axon hillock

Description: Specialized, cone-shaped region of the cell body which forms the initial segment of the axon
Function: Site for initiation of action potentials (with initial segment of axon)
Components:
- Devoid of large cytoplasmic organelles (Nissl bodies and Golgi apparatus),
- Contains high density of voltage-gated sodium channels

Dendrites

Description: Tree-like, short, tapering processes of varying shape
Function: Reception of synaptic signals and translation into electrical events
Components: Similar to the cell body, neurotransmitter receptors, dendritic shaft, dendritic spines

Axon (nerve fiber)

Description: Single long process arising from the axon hillock
Function: Conduction of electrical impulses away from the cell body
Components:
- Axolemma (cell membrane), axoplasm (cytoplasm), myelin sheath, myelin sheath gaps (nodes of Ranvier), terminal arborizations, terminal boutons, microtubules, intermediate filaments
- Devoid of endoplasmic reticulum and ribosomes

Cell body

The cell body of a neuron, also known as the soma, is typically located at the center of the dendritic tree in multipolar neurons. It is spherical or polygonal in shape and relatively small, making up one-tenth of the total cell volume.

The functionality of the neuron is highly dependent on its cell body as it houses the nucleus, which contains the genetic material (DNA) of the cell as well as various cytoplasmic organelles. These organelles include the endoplasmic reticulum (both smooth and rough), which clusters with free ribosomes to form what is known as chromatophilic substances ( Nissl bodies) and are involved in the protein synthesis of enzymes, receptors, ion channels and other structural components. Additionally, the cell body contains the Golgi apparatus and microtubules, involved in the packaging and transport of proteins; mitochondria, involved in energy production; and lysosomes involved in the waste management of the cell.

The axon hillock refers to an anatomically and functionally distinct area of the cell body which serves as the origin of the axon. It is cone-shaped and devoid of large cytoplasmic organelles such as chromatophilic substance (Nissl bodies) and Golgi apparatus. The axon hillock contains a high density of voltage-gated sodium channels, allowing it to serve as a critical site for determining whether or not the sum of all incoming signals warrants the propagation of an action potential. It also supports neuron polarity by separating the receptive/integrative parts from the conductive/transmissive parts, providing directionality in the flow of information from the dendrites to the cell body, axon and axon terminals.

The region of the axon laying between the axon hillock and the beginning of the myelin sheath is termed the initial segment. This is the actual site of action potential generation, although more recent research states that both the initial segment and axon hillock are capable of action potential generation.

Dendrites

Dendrites are tree-like processes extending from the cell body of the neuron and contain organelles similar to those in the cell body. The highly branched structure of dendrites provides an increased surface area for receiving information from other neurons at specialized areas of contact called synapses. Dendrites primarily consist of dendritic shafts, which serve as the main structural branches.

These are lined with numerous tiny protrusions called dendritic spines, which serve as sites for the initial processing of synaptic signals via membrane embedded neurotransmitter receptors; they translate the chemical messages received into electrical events, which travel down the dendrites. There are approximately ten trillion of these structures present across all dendrites of neurons in the human cerebral cortex (for 16-20 billion neurons), therefore they greatly increase the area available for synaptic events.

Axon

The axon of a neuron is also known as a nerve fiber. The membrane of an axon is known as the axolemma, while the cytoplasm is also referred to as axoplasm. Bundles of axons in the CNS form a tract, while in the PNS, they are referred to as fascicles (which, when bound together with connective tissue, form nerves). Axons originate from the axon hillock and conduct electrical impulses, in the form of action potentials, away from the cell body through a process of sequential depolarization and repolarization. Unlike dendrites that form a complex network with many tapering branches, the axon of a neuron is usually a single, long process that can extend for a considerable distance before it branches and terminates. The length of axons varies and can sometimes exceed a meter, such as in some peripheral nerves like the sciatic nerve, which extends from the spinal cord to the feet.

Axons typically terminate as fine branches called terminal arborizations; each of which is capped with a terminal bouton. These specialized structures contain synaptic vesicles that store neurotransmitters to be released into the synaptic cleft (a small gap at a synapse between neurons where nerve impulses are transmitted by a neurotransmitter) when an action potential reaches the axon terminal.

Axons can be enveloped in an insulating layer of lipids and proteins called the myelin sheath. This sheath protects the axon and prevents the loss of electrical charge (ions) during the transmission of action potentials along the neuron, increasing the speed of impulse transmission. The myelin sheath is formed by specific types of glial cells, namely oligodendrocytes in the CNS and Schwann cells (neurolemmocytes) in the PNS. The myelination of PNS axons involves many Schwann cells, each of which participates in the formation of the myelin sheath of a single axon, by wrapping around it multiple times. Not all axons are covered by myelin. In the PNS, multiple nonmyelinated axons can go through a single Schwann cell, without myelin sheath production. In contrast, an oligodendrocyte can myelinate multiple axons in the CNS, due to its arm-like processes twisting around them.

The outermost nucleated cytoplasmic layer of Schwann cells overlying the myelin sheath is called the neurolemma. This structural characteristic aids in the regeneration of damaged peripheral axons when the corresponding cell body remains intact. In contrast, CNS neurons, which lack a neurolemma, exhibit limited regenerative capacity.

Nerve fibers are classified into groups, based on their myelination; group A neurons are heavily myelinated, group B are moderately myelinated, and group C are nonmyelinated. Along myelinated axons, evenly distributed gaps known as myelin sheath gaps (commonly referred to as nodes of Ranvier) allow electrical impulses to jump from node to node. This propagation pattern is referred to as saltatory conduction. Myelin sheath gapsare more numerous in axons of the PNS compared to those of the CNS.

Since axons lack endoplasmic reticulum and ribosomes, proteins and organelles needed for its growth are synthesized in the cell body and then transported to the axon via axonal transport. This is facilitated by microtubules and intermediate filaments that provide cytoskeletal "tracks" for transportation. The microtubule arrangements overlap, providing routes for simultaneous transport of different materials to and from the cell body.

Additional Information

Neurons (also called neurones or nerve cells) are the fundamental units of the brain and nervous system, the cells responsible for receiving sensory input from the external world, for sending motor commands to our muscles, and for transforming and relaying the electrical signals at every step in between. More than that, their interactions define who we are as people. Having said that, our roughly 100 billion neurons do interact closely with other cell types, broadly classified as glia (these may actually outnumber neurons, although it’s not really known).

The creation of new neurons in the brain is called neurogenesis, and this can happen even in adults.

What does a neuron look like?

A useful analogy is to think of a neuron as a tree. A neuron has three main parts: dendrites, an axon, and a cell body or soma (see image below), which can be represented as the branches, roots and trunk of a tree, respectively. A dendrite (tree branch) is where a neuron receives input from other cells. Dendrites branch as they move towards their tips, just like tree branches do, and they even have leaf-like structures on them called spines.

The axon (tree roots) is the output structure of the neuron; when a neuron wants to talk to another neuron, it sends an electrical message called an action potential throughout the entire axon. The soma (tree trunk) is where the nucleus lies, where the neuron’s DNA is housed, and where proteins are made to be transported throughout the axon and dendrites.

There are different types of neurons, both in the brain and the spinal cord. They are generally divided according to where they orginate, where they project to and which neurotransmitters they use.

Concepts and definitions

Axon – The long, thin structure in which action potentials are generated; the transmitting part of the neuron. After initiation, action potentials travel down axons to cause release of neurotransmitter.

Dendrite – The receiving part of the neuron. Dendrites receive synaptic inputs from axons, with the sum total of dendritic inputs determining whether the neuron will fire an action potential.

Spine – The small protrusions found on dendrites that are, for many synapses, the postsynaptic contact site.

Action potential – Brief electrical event typically generated in the axon that signals the neuron as 'active'. An action potential travels the length of the axon and causes release of neurotransmitter into the synapse. The action potential and consequent transmitter release allow the neuron to communicate with other neurons.

Bowman's Capsule

Gist

The glomerular capsule, also known as Bowman's capsule, is the blind expanded end of a renal tubule. It is a double layered epithelial capsule surrounding the glomerulus. The glomerular capsule together with the glomerulus are termed the renal corpuscle, the site of blood filtration within the kidneys.

The fluid entering Bowman's capsule is called glomerular filtrate, which consists of plasma from blood minus large proteins and cells that cannot pass through the filtration barrier.

Bowman's capsule looks like a pouch, sac or cup. You can only see it under a microscope. Bowman's capsule contains fluid like blood plasma, but with no red or white blood cells or platelets.

Bowman's capsule surrounds the glomerular capillary loops and participates in the filtration of blood from the glomerular capillaries. Bowman's capsule also has a structural function and creates a urinary space through which filtrate can enter the nephron and pass to the proximal convoluted tubule.

Summary

Bowman's capsule (or the Bowman capsule, capsula glomeruli, or glomerular capsule) is a cup-like sac at the beginning of the tubular component of a nephron in the mammalian kidney that performs the first step in the filtration of blood to form urine. A glomerulus is enclosed in the sac. Fluids from blood in the glomerulus are collected in the Bowman's capsule.

Structure

Outside the capsule, there are two poles:

* The vascular pole is the side with the afferent arteriole and efferent arteriole.
* The tubular pole, is the side with the proximal convoluted tubule.

Inside the capsule, the layers are as follows, from outside to inside:

* Parietal layer—A single layer of simple squamous epithelium. Does not function in filtration.
* Bowman's space (or "urinary space", or "capsular space")—Between the visceral and parietal layers, into which the filtrate enters after passing through the filtration slits.
* Visceral layer—Lies just above the thickened glomerular basement membrane and is made of podocytes. Beneath the visceral layer lie the glomerular capillaries.
* Filtration barrier—The filtration barrier is composed of the fenestrated endothelium of the glomerular capillaries, the fused basal lamina of the endothelial cells and podocytes, and the filtration slits of the podocytes. The barrier permits the passage of water, ions, and small molecules from the bloodstream into the Bowman's space. The barrier prevents the passage of large and/or negatively charged proteins (such as albumin). The basal lamina of the filtration barrier is composed of three layers. The first layer is the lamina rara externa, adjacent to the podocyte processes. The second layer is the lamina rara interna, adjacent to the endothelial cells. The final layer is the lamina densa which is a darker central zone of the basal lamina. It consists of the meshwork of type IV collagen and laminin which act as a selective macromolecular filter.

Function

The process of filtration of the blood in the Bowman's capsule is ultrafiltration, and the normal rate of filtration is 125 ml/min, equivalent to 80 times the daily blood volume. It is a major site for blood filtration (including glomerulus).

Any proteins under roughly 30 kilodaltons can pass freely through the membrane, although there is some extra hindrance for negatively charged molecules due to the negative charge of the basement membrane and the podocytes.

Any small molecules such as water, glucose, salt (NaCl), amino acids, and urea pass freely into Bowman's space, but cells, platelets and large proteins do not.

As a result, the filtrate leaving the Bowman's capsule is very similar to blood plasma (filtrate or glomerular filtrate is composed of blood plasma minus plasma protein i.e. it contains all the components of blood plasma except the proteins) in composition as it passes into the proximal convoluted tubule.

Details

Bowman’s capsule is part of a nephron, a filter in your kidney. One million nephrons in each kidney clean your blood. A Bowman’s capsule in each nephron plays a part in the filtering process. After filtering, nutrients stay in your blood, and waste goes out through urine.

Overview

Bowman’s capsule surrounds blood vessels in each nephron that filters blood in your kidneys.

What is Bowman’s capsule?

Bowman’s capsule is a part of each filtering unit (nephron) in your kidney. You have about 1 million nephrons that filter blood in each of your two kidneys. Kidneys clean blood and return it to your body.

Every nephron has a glomerulus. A two-walled pouch, Bowman’s capsule covers the glomerulus. This group of tiny blood vessels is the starting point for filtering waste products out of your blood. Bowman’s capsule and the glomerulus make up the renal corpuscle.

You may hear other names for Bowman’s capsule, like:

* Glomerular capsule
* Malpighian capsule
* Renal corpuscular capsule

The space in between the walls (layers) of Bowman’s capsule is called Bowman’s space. You may hear healthcare providers refer to Bowman’s space as:

* Glomerular capsule space
* Filtration space
* Urinary space

Function:

What is the function of the Bowman’s capsule in the kidney?

The function of Bowman’s capsule is to help the glomerulus filter blood. Small molecules from your blood pass freely into Bowman’s space. Cells and large proteins stay in your blood.

The glomerular capsule also protects cells called podocytes by keeping white blood cells from getting in. White blood cells can’t pass through Bowman’s capsule. Podocytes in a kidney capsule have pedicels that manage what stays and what goes. Finger-like pedicels link together like they’re holding hands. The way they join creates slits that only let certain things go through. When you’re healthy, protein and cell content can’t get through.

The small molecules then pass through tubes in your kidney. Your kidney regulates which molecules your blood absorbs and which leave your body in pee (urine).

Waste materials go out of your body as urine through tubules (tiny tubes). The blood pressure in the glomerulus helps move the blood along. As the fluids leave, water and nutrients go back into your blood.

Two arterioles go into the Bowman’s capsule. One brings blood into the glomerulus. The other lets blood out.

Anatomy:

Where is Bowman’s capsule located?

Bowman’s capsule is in the renal cortex, part of your kidney. Your kidneys are in your back, below your rib cage. Usually, you have one kidney on either side of your spine. Your kidneys are between your intestines and diaphragm. Each kidney connects to your bladder by a tube called a ureter.

What does it look like?

Bowman’s capsule looks like a pouch, sac or cup. You can only see it under a microscope. Bowman’s capsule contains fluid like blood plasma, but with no red or white blood cells or platelets.

What are the parts of Bowman’s capsule?

The glomerular capsule has two layers. A type of body tissue, simple squamous epithelium, makes up the outer (parietal) layer. These parietal cells give structure to Bowman’s capsule. Cells called podocytes form the inner (visceral) layer.

Additional Information:

Introduction

Bowman’s capsule is a part of the nephron that forms a cup-like sack surrounding the glomerulus. Bowman’s capsule encloses a space called “Bowman’s space,” which represents the beginning of the urinary space and is contiguous with the proximal convoluted tubule of the nephron. Bowman’s capsule, Bowman’s space, and the glomerular capillary network and its supporting architecture can collectively be thought of as composing the glomerulus. There are an estimated 900000 glomeruli within the cortex of a mature human kidney.

Structure and Function

In the kidney, the glomerulus represents the initial location of the renal filtration of blood. Blood enters the glomerulus through the afferent arteriole at the vascular pole, undergoes filtration in the glomerular capillaries, and exits the glomerulus through the efferent arteriole at the vascular pole.

Bowman’s capsule surrounds the glomerular capillary loops and participates in the filtration of blood from the glomerular capillaries. Bowman’s capsule also has a structural function and creates a urinary space through which filtrate can enter the nephron and pass to the proximal convoluted tubule. Liquid and solutes of the blood must pass through multiple layers to move from the glomerular capillaries into Bowman’s space to ultimately become filtrate within the nephron’s lumen.

The first step of filtration occurs through the endothelial layer of the capillaries, which is composed of fenestrated endothelial cells. These fenestrations, or slits between endothelial cells, are approximately 60 to 80 nm wide and restrict the movement of matter above this size. In addition to filtering based on size, the fenestrated endothelium carries negative charges that preferentially restrict the movement of negatively charged substances into Bowman’s space.

Filtrate next moves through the glomerular basement membrane (GBM). From the direction of the capillaries and moving towards Bowman’s capsule, three layers compose the GBM – the lamina rara interna, the lamina densa, and the lamina rara externa. Mesangial cells within the glomerulus play a role in creating and maintaining the GBM, as well as holding capillary loops together.

Following the GBM, filtrate must pass through the epithelial layer of Bowman’s capsule, which is composed of podocytes. The podocytes feature finger-like projections of cytoplasm referred to as “foot processes” or “pedicels.” These foot processes interdigitate with one another and create a further barrier through which filtrate must pass. Structures called “slit diaphragms” bridge nearby foot processes and provide structural support. The podocytes are the primary cells of the epithelium adjacent to the capillaries (the visceral epithelium) and play a role in filtration. The parietal epithelium of Bowman’s capsule is the outer layer and is composed of simple squamous epithelial cells called “parietal cells.” The parietal layer is not directly involved with filtration from the capillaries. Parietal cells play a structural role in maintaining Bowman’s capsule and are also speculated to have the ability to differentiate into podocytes to replace damaged or old podocytes. Bowman’s space is the area between the visceral and parietal epithelium of Bowman’s capsule.

In summary, filtrate entering Bowman’s space traverses through glomerular capillaries, the GBM, and the interdigitated foot processes of the podocytes and is filtered based on size and electric charge. The filtrate entering Bowman’s space has a very similar composition to that of the blood in the glomerular capillaries except for the protein, and cell content as these are the components largely prevented from entering Bowman’s space when glomerular filtration is functioning properly.

Combination Quotes - III

1. I want every version of a woman and a man to be possible. I want women and men to be able to be full-time parents or full-time working people or any combination of the two. - Natalie Portman

2. To us, the value of a work lies in its newness: the invention of new forms, or a novel combination of old forms, the discovery of unknown worlds or the exploration of unfamiliar areas in worlds already discovered - revelations, surprises. - Octavio Paz

3. Looking beautiful isn't just about what you apply on your face. It's the little things you do that matter. A combination of a good diet, exercise, healthy habits, discipline, dancing etc. is what my beauty routine consists of. Also, I have no bad habits; I don't drink or smoke. All these contribute to me being fit and looking good. - Madhuri Dixit

4. I have a flexible body, thanks to the combination exercise routine I follow. But I'm fairly lazy when it comes to working out my legs and back. - Shriya Saran

5. It's an interesting combination: Having a great fear of being alone, and having a desperate need for solitude and the solitary experience. That's always been a tug of war for me. - Jodie Foster

6. For me a good body is a combination of peaceful mind, positive energy and physical exercise. - Shriya Saran

7. Books are mute as far as sound is concerned. It follows that reading aloud is a combination of two distinct operations, of two 'languages.' It is something far more complex than speaking and reading taken separately by themselves. - Maria Montessori

8. Nature teaches us that tens of billions of light years may have passed, and life in all of its expressions has always been subjected to an incredible combination of matter and radiation. - Fidel Castro.

Fetoscope/Fetoscopy

Gist

A fetoscope, also known as a fetal stethoscope or Pinard horn, is a simple, non-electronic instrument used in prenatal care to listen to a baby's heartbeat by amplifying sounds through the mother's abdomen, typically after 18-20 weeks of gestation. It's a cone-shaped device, often made of metal or plastic, that allows midwives and doctors to monitor fetal well-being without ultrasound, providing a traditional, cost-effective method for assessing the fetus.

The fetoscope allows healthcare providers, especially midwives, to monitor the heartbeat of a fetus and assess the baby's health and development. A fetal heartbeat is a vital sign that helps to detect potential issues (especially genetic conditions) early on.

Summary

A fetoscopy is a procedure that allows your healthcare team to see the inside of your uterus during pregnancy. It helps treat certain genetic conditions in a developing fetus.

Fetoscopy is a procedure during pregnancy that lets your pregnancy care provider see the fetus developing inside your uterus. Providers use it to evaluate and treat congenital disorders (diseases you’re born with). It involves inserting a thin, fiber-optic tube (endoscope or fetoscope) into your uterus through a tiny incision in your abdomen. It has a small camera on the end so your provider can see inside your uterus and amniotic sac (the sac that holds the fetus in your uterus). The fetoscope is hollow, so your provider can insert surgical tools through it, allowing them to treat certain fetal conditions or obtain samples of tissue (biopsy). In some cases, the fetoscope is inserted through your cervix instead of through your abdomen.

When is a fetoscopy done?

Fetoscopy is performed in the second or third trimester of pregnancy to treat fetal conditions or collect biopsies.

Some of the most common conditions treated with fetoscopy are:

* Twin-to-twin transfusion syndrome

Twin-to-twin transfusion syndrome is a rare, potentially life-threatening condition that occurs when identical twins aren't getting an equal share of blood while in the uterus. Your surgeon uses a fetoscope to better visualize your placenta and the blood vessels causing the condition. Then, they place a laser through the fetoscope that they use to close off the blood vessels causing uneven blood flow. This procedure is called fetoscopic laser photocoagulation.

* Amniotic band syndrome

Amniotic band syndrome occurs when the fetus gets tangled up in bands of tissue from the amniotic sac. It can restrict blood flow or cause amputation of limbs or organs. A fetoscope allows your surgeon to insert a laser device that cuts and releases the bands of tissue around the fetus.

* Congenital diaphragmatic hernia (CDH)

CDH occurs when the fetus has a hole in its diaphragm, which causes its abdominal organs to shift upward, putting pressure on the lungs. This prevents its lungs from growing properly. Surgeons use fetoscopy to insert a balloon in the fetus's airway to promote lung growth. The balloon is removed several weeks later. This procedure is called fetoscopic endoluminal tracheal occlusion (FETO).

There are other conditions fetoscopy may be used for, like treatment of placental tumors, spina bifida and other congenital diseases.

Details:

What is a Fetoscope, and Why do Midwives Use it?

A fetoscope is a medical instrument that allows healthcare providers to listen to the fetal heartbeat. Unlike a standard stethoscope, a fetoscope is designed to pick up the sounds of a baby’s heartbeat through the mother’s abdomen. It is essential to prenatal care, especially in environments prioritizing low-intervention, natural childbirth approaches, like Birthways Family Birth Center.

The Purpose of a Fetoscope

The fetoscope allows healthcare providers, especially midwives, to monitor the heartbeat of a fetus and assess the baby’s health and development. A fetal heartbeat is a vital sign that helps to detect potential issues (especially genetic conditions) early on. This monitoring is crucial throughout pregnancy, especially as the due date approaches.

Difference Between a Doppler and a Fetoscope

A fetoscope and a Doppler device detect a fetal heartbeat, but they differ in several ways:

* Technology: A Doppler uses ultrasound waves to detect the movement of the baby’s heart and translate it into sound. On the other hand, a fetoscope relies on the practitioner’s ability to manually detect and listen to the fetal heartbeat without electronic amplification.
* Sound Quality: The sound detected through a Doppler is electronically amplified to make it louder and clearer. The fetoscope provides a more natural sound but may require more skill to handle.
* Safety: The Doppler uses ultrasound waves and introduces a small amount of energy into the body. However, it is generally considered safe. A fetoscope, however, is entirely noninvasive and doesn’t involve any ultrasound or electronic waves, making it a safe option for both mother and baby.

When Can You Use it?

A fetoscope is typically used to detect a fetal heartbeat starting around 18 to 20 weeks of pregnancy. However, it requires skill and patience, as the heartbeat may not always be easy to locate, especially in early pregnancy.

Using a fetoscope is generally more effective in the later stages of pregnancy when the baby is larger and the heartbeat is stronger.

Is it Safe?

Yes, a fetoscope is entirely safe during all stages of pregnancy. It’s a non-invasive tool that does not emit radiation, ultrasound, or electronic waves. Sometimes, a fetoscope may not detect the fetal heartbeat. But this is not a concern as long as the baby is moving.

Why Do Midwives Use Them?

Midwives often prefer fetoscopes because of their safety, simplicity, and effectiveness. It aligns with the midwifery philosophy of providing natural, low-intervention care. A fetoscope creates a calm and natural environment for the mother and the baby.

To sum up, the fetoscope is a valuable tool in prenatal care. It offers a safe, effective, and natural way to monitor the baby’s health throughout pregnancy. You can learn more about fetoscopes on our YouTube channel.

Additional Information

Fetoscopy is an endoscopic procedure during pregnancy to allow surgical access to the fetus, the amniotic cavity, the umbilical cord, and the fetal side of the placenta. A small (3–4 mm) incision is made in the abdomen, and an endoscope is inserted through the abdominal wall and uterus into the amniotic cavity. Fetoscopy allows for medical interventions such as a biopsy (tissue sample) or a laser occlusion of abnormal blood vessels (such as chorioangioma) or the treatment of spina bifida.

Fetoscopy is usually performed in the second or third trimester of pregnancy. The procedure can place the fetus at increased risk of adverse outcomes, including fetal loss or preterm delivery, so the risks and benefits must be carefully weighed in order to protect the health of the mother and fetus(es). The procedure is typically performed in an operating room by an obstetrician-gynecologist.

Non-surgical fetoscopes

Fetoscopy is a surgical procedure which may involve the use of a fibreoptic device called a fetoscope. Some confusion may arise from the use of specialized forms of stethoscopes, including Pinard horns and Doppler wands, to audibly monitor fetal heart rate (FHR). These audio diagnostic tools are also called "fetoscopes" but are not related to visual fetoscopy.