In this video, we're going to begin our lesson on the steps of the inflammatory response. It's really a series of just four events or four steps that occur in the inflammatory response during tissue damage and infection of a microbe. In this video, we're only going to focus on the very first event, or the very first step of the inflammatory response, which is tissue damage and infection. But later, in other videos, we'll talk about the other steps of the inflammatory response. In the first step of the inflammatory response, we have tissue damage and infection. Damage to the tissues allows microbes to bypass the first line of defense of innate immunity. It can bypass our skin, mucus membranes, antimicrobials, and things of that nature. When they bypass the first line of defense, they can enter into the surrounding tissue cells. Immediately after injury, blood vessels will briefly constrict via vasoconstriction. Vasoconstriction is the constriction or narrowing of the blood vessels. It does this in order to prevent blood loss. If we take a look at our image down below, what we're showing you is the very first event of the inflammatory response, which is tissue damage and infection by the microbe. Notice in this image, it is an image showing our skin. You can see the epidermis layer is at the top here and the dermis layer is right here. Down below, notice that the blood vessel is at the bottom. What you'll notice is that, when there is damage, like for example when a sharp object penetrates your tissues, some of our immune system cells are already going to be present in the tissues. For example, mast cells can be present in the tissues. However, when there is a penetration by a sharp object like this, it creates the opportunity for microbes to infect the tissues. This tissue damage can lead to infection by a microbe. Once again, the blood vessels are going to briefly constrict to prevent a large amount of blood loss. This here concludes our lesson on the first event of the inflammatory response, and we'll get to talk about the other events of the inflammatory response as we move forward. So, I'll see you all in our next video.
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Steps of the Inflammatory Response: Study with Video Lessons, Practice Problems & Examples
The inflammatory response consists of four key steps: tissue damage and infection, release of inflammatory mediators, vasodilation, and removal of invading microbes. Initially, tissue damage allows pathogens to enter, triggering mast cells to release cytokines like histamine, promoting inflammation. Vasodilation increases blood vessel permeability, facilitating immune cell migration (diapedesis) to the infection site. Finally, neutrophils and macrophages eliminate microbes through phagocytosis. While inflammation is protective, it can also cause accidental damage, highlighting the importance of understanding its dual role in health and disease.
Step 1: Tissue Damage & Infection
Video transcript
Step 2: Release of Inflammatory Mediators & Other Cytokines
Video transcript
In this video, we're going to talk briefly about the second step in the inflammatory response, which is the release of the inflammatory mediators and other cytokines. In response to a microbe invasion or tissue damage, local mast cells, which are very similar to basophils but reside in the tissues, are going to release cytokines and inflammatory mediators. These mast cells are already residing within the tissues, as you can see here in this image. They will begin to release cytokines and inflammatory mediators upon an infection. Inflammatory mediators really refer to messenger molecules that are specifically involved in the inflammatory response. For example, histamine is an example of an inflammatory mediator. The release of histamine will promote inflammation.
The release of inflammatory mediators will help to regulate changes in local blood vessels, potentially causing the local blood vessels to dilate, as we'll talk about in the next step. It will also signal immune system cells from the blood to the infected site, attracting immune system cells to the area of infection. If we take a look at this image down below, we're focusing on the second step of the inflammatory response, with inflammatory mediators and cytokines being released. Once again, these mast cells that are present in the tissues and reside in the tissues will begin to release cytokines and inflammatory mediators. These cytokines and inflammatory mediators will cause changes to the local blood vessels and also signal immune system cells to travel from the blood vessels to the area of infection to help eliminate the microbes.
This here concludes our brief lesson on the second step of the inflammatory response, and we'll be able to talk about the 3rd and the 4th steps of the inflammatory response as we continue to move forward. So I'll see you in our next lesson video.
In the inflammatory response, which immune cells are the first to begin the immune response to an injury?
The neutrophil cells are the first to respond to the injury and begin removing invading microbes.
The mast cells release inflammatory mediators to recruit other immune cells to the injury site.
The macrophages release histamine to dilate the blood vessels allowing immune cells to enter the injury site.
Step 3: Vasodilation
Video transcript
In this video, we're going to talk briefly about the 3rd step of the inflammatory response, which is vasodilation. Vasodilation is the dilation or the enlargement of the blood vessels that increases the permeability of those blood vessels. The increased permeability allows for cells of the immune system to leave the bloodstream and enter the site of infection. This increased permeability is in response to inflammatory mediators. Inflammatory mediators that are released by mast cells lead to vasodilation, the enlargement of the blood vessels, and the increased permeability of those blood vessels.
The term diapedesis refers specifically to the migration of immune system cells through the intact walls of the blood vessels into the infected tissue. Additionally, the term exudate refers specifically to the fluid mix of blood plasma, proteins, and immune cells that exit the bloodstream to the infected site. Recall from some of our previous lesson videos that neutrophils are the first type of cells to be recruited to the site of infection. They are the first phagocytes that are recruited. Taking a look at our image down below, we have the 3rd step of the inflammatory response, which is vasodilation and diapedesis. You'll notice here that the cells of the infected area are infected with many microbes. Upon releasing those inflammatory mediators, mast cells lead to vasodilation. Here we have dilated blood vessels, labeled as dilated blood vessels. These dilated blood vessels increase the permeability of the blood vessels, allowing for diapedesis. Diapedesis, again, is the migration of immune cells from the blood into the site of infection. Macrophages and neutrophils can be recruited, and it's the neutrophils that are first recruited to the site of infection.
This concludes our brief lesson on the 3rd step of the inflammatory response, vasodilation. We'll be able to get some practice applying these concepts and talk about the 4th and final step of the inflammatory response as we move forward in our course. I'll see you all in our next video.
Which of the following is needed for vasodilation and diapedesis to occur at an infection site?
Mast cells releasing histamines and cytokines to dilate the blood vessels & recruit immune cells.
Adhesion proteins on the endothelial cells of the blood vessels allowing the immune cells to leave the blood stream.
Exudate full of blood, plasma, proteins and immune cells exiting the blood stream to the infection site.
All are needed for vasodilation and diapedesis to occur at the site of an infection.
Step 4: Removal of Invading Microbes
Video transcript
This video, we're going to talk about the 4th and final step of the inflammatory response, which is the removal of the invading microbes. The phagocytic cells that migrated from the blood into the infected area are going to destroy or eliminate those invading microbes. Now the neutrophils are going to remove microbes through degranulation or through phagocytosis, and macrophages are going to perform phagocytosis and engulf the cells, the dead cells in the area to help destroy and eliminate all of the microbes that have invaded. Taking a look at this image down below, the 4th and final step of the inflammatory response is phagocytosis of the invading microbes, and removal of those invading microbes. Notice in this image we have neutrophils and we also have macrophages. Together, they will work to eliminate these microbes and remove those microbes. This here concludes our lesson on this 4th and final step of the inflammatory response. Moving forward, we'll be able to get practice on these concepts and also continue to talk more about the innate immune responses. So, I'll see you all in our next video.
Which immune cells are responsible for removing dead or damaged host material at an injury site?
Macrophages.
Mast cells.
Neutrophils.
Platelets.
Match the scenario to the step of the inflammatory response it belongs in.
1. Tissue Damage & Infection.
2. Release of Inflammatory Mediators & Cytokines.
3. Vasodilation and Diapedesis.
4. Removal of Invading Microbes and Damaged Tissue.
_____ Local mast cells release histamines and cytokines when encountering an invading microbe.
_____ Neutrophils destroy the invading microbes found in the injury site.
_____ Peter accidentally cuts his finger with a kitchen knife.
_____ Fluid full of plasma, proteins and immune cells exits the blood stream at injury site.
_____ Macrophages remove the epidermis and dermis cells damaged by the injury.
_____ The blood vessels in the region of the injury dilate releasing immune cells and proteins.
_____ Pathogenic bacteria enter the host’s body.
Problem Transcript
The attraction of leukocytes to the area on inflammation is referred to as
Parasitism.
Infection.
Phototaxis.
Chemotaxis.
Damaging Effects of the Inflammatory Response
Video transcript
This video, we're going to talk a little bit about the damaging effects of the inflammatory response. Although inflammation is designed to eliminate microbes and protect us from microbes, sometimes inflammation can result in significant damage to the host. This is really accidental damage because, again, the inflammatory response is supposed to be eliminating microbes. The inflammatory response can be somewhat similar to a sprinkler system in a building, where the sprinkler system is designed to project water to eliminate and prevent fires. However, sometimes the sprinkler system can also cause accidental damage to electrical equipment. That's why the inflammatory response can be an analogy to a sprinkler system because it's designed to eliminate microbes, but sometimes it can cause accidental damage to the host. Depending on the location of where inflammation occurs within the host, inflammation can actually be life-threatening. For example, if inflammation occurs in the brain, it can be very life-threatening. The suffix -itis is found in many disease names and it specifically means inflammation. You can find that suffix is in the terms meningitis or encephalitis. Again, that suffix -itis means inflammation. Down below, we're showing you just an image of rheumatoid arthritis, which is basically inflammation that occurs in the joints. Meningitis and encephalitis are basically just inflammation of the meninges or the membranes of the brain or inflammation of the brain itself, which again can be life-threatening. That's important to keep in mind about the inflammatory response that occasionally it can have some damaging effects. This here concludes our brief lesson on the damaging effects of the inflammatory response. Once again, we'll be able to get some practice applying these concepts as we move forward. So I'll see you all in our next video.
Which of the following statements about the inflammatory response is false?
It includes vasodilation of the blood vessels and the release of immune cells from the blood stream.
Neutrophils are the first cells to exit the blood stream during the inflammatory response.
Apoptosis of infected cells triggers the inflammatory response.
Chronic triggering of the inflammatory response can damage the host.
Major signs of inflammation include: redness, swelling, heat, pain, and loss of function
Rheumatoid arthritis is an autoimmune disease, meaning that the body’s immune system attacks the body’s joint tissues. Why are many autoimmune diseases associated with chronic inflammation?
The tissues the immune system is “fighting” are always present, so the inflammatory response does not shut off.
The invading microbes are not easily killed and keep reforming causing chronic inflammation.
The invading virus goes dormant in the body and later reemerges causing prolonged periods of inflammation.
Which of the following is FALSE in regards to inflammation?
It is a component of the second line of defense.
It is caused by antibody-antigen complexes.
It is a component of the first line of defense.
It can be caused by endotoxins.
Do you want more practice?
More setsHere’s what students ask on this topic:
What are the four steps of the inflammatory response?
The four steps of the inflammatory response are: 1) Tissue damage and infection: This initial step involves the entry of pathogens due to tissue damage, bypassing the first line of defense. 2) Release of inflammatory mediators: Mast cells release cytokines and inflammatory mediators like histamine, which promote inflammation. 3) Vasodilation: Blood vessels dilate and become more permeable, allowing immune cells to migrate to the infection site. 4) Removal of invading microbes: Neutrophils and macrophages eliminate the pathogens through phagocytosis. These steps collectively help in containing and eliminating infections, although they can sometimes cause accidental damage to host tissues.
How do mast cells contribute to the inflammatory response?
Mast cells play a crucial role in the inflammatory response by releasing cytokines and inflammatory mediators such as histamine. These substances promote inflammation and cause changes in local blood vessels, including vasodilation and increased permeability. This allows immune cells to migrate from the bloodstream to the site of infection. The release of these mediators helps to attract other immune cells to the affected area, facilitating the elimination of invading pathogens. Thus, mast cells are essential for initiating and regulating the inflammatory response.
What is vasodilation and how does it aid in the inflammatory response?
Vasodilation is the process of blood vessels widening, which increases their permeability. This is a critical step in the inflammatory response, as it allows immune cells to exit the bloodstream and migrate to the site of infection. The increased permeability facilitates the movement of immune cells, such as neutrophils and macrophages, through the blood vessel walls (a process known as diapedesis) to the infected tissue. These immune cells then work to eliminate the invading pathogens, thereby aiding in the resolution of the infection.
What are the potential damaging effects of the inflammatory response?
While the inflammatory response is designed to protect the body by eliminating pathogens, it can sometimes cause accidental damage to host tissues. This is similar to how a sprinkler system can damage electrical equipment while extinguishing a fire. Inflammation can be particularly harmful if it occurs in critical areas like the brain, leading to conditions such as meningitis or encephalitis, which can be life-threatening. Chronic inflammation can also contribute to diseases like rheumatoid arthritis, where prolonged inflammation damages the joints. Understanding these potential damaging effects is crucial for managing inflammation-related conditions.
What role do neutrophils and macrophages play in the inflammatory response?
Neutrophils and macrophages are key players in the final step of the inflammatory response, which involves the removal of invading microbes. Neutrophils are the first immune cells to arrive at the infection site and eliminate pathogens through degranulation and phagocytosis. Macrophages follow and continue the process of phagocytosis, engulfing and digesting both pathogens and dead cells. Together, these phagocytic cells help to clear the infection and promote tissue repair, ensuring the resolution of the inflammatory response.