This topic is another introductory topic in Microbiology. The aim is to understand the gram stain, and then by extension, what bacteria are gram positive, and what bacteria are gram negative. Emphasis will also be given to taxonomy based on morphology – namely, cocci, baccili, spirilla or pleomorphic. Continue reading Bacterial Taxonomy 1 – Classification Based on Morphology and the Gram Stain
This topic covers the Scapula, the large flat bone of the back. We discuss the structure of the scapula, the muscles attached to the scapula, and several of its features. Hope you enjoy this post! Continue reading Scapula
This is the second post in the series: Pathologic Cell Injury and Cell Death. This topic, Necrosis, involves cell death that is done unintentionally by the cell. I will talk about all the different mechanisms of necrosis, pyknosis and its variants, and the different morphological types of necrosis, including Coagulation, Liquefactive, Fat, Caseous, Fibrinoid, Gangrenous and Avascular. Continue reading Pathologic Cell Injury and Cell Death II – Necrosis
This topic is Part 1 of a 4 Part Series. The first topic, Reversible Cell Injury, covers the physiology and pathology of reversible cell injuries, and what happens to a cell when a cell is unable to adapt to the stresses of the environment. I will discuss histological changes in cells, Cellular Swelling and Steatosis. Continue reading Pathologic Cell Injury and Cell Death I – Mechanism of Reversible Cell Injuries
This is an Introduction to Pharmacology, talking specifically about the Characteristics of Drugs. I will briefly touch on Pharmacodynamics and Pharmacokinetics and speak about how the characteristics of some drugs are important in their effect on the body. Hope you guys enjoy it! Continue reading Introduction to Pharmacology I – Characteristics of Drugs
This topic covers the Clavicle. A short topic, I quickly skim the gross anatomy of the clavicle, muscles and nerves related to the clavicle, and the ossification of the clavicle. As usual, there are useful videos about the clavicular fracture you may use to supplement the notes below! Continue reading Clavicle
This topic covers the concept of Autophagy in detail, a concept I’ve covered briefly in “Waste Disposal In Cells” and “Cellular Adaptation To Stress.” I have explored the topic in full detail here, including the classes, types, and importance, and as usual , included several diagrams, videos and questions. I hope you find this useful! Continue reading Autophagy
Cellular Adaption To Stress
Cellular adaptation refer to (usually) reversible changes in size, number, phenotype or appearance, metabolic activity or functions of cells in response to adverse environmental conditions or internal bodily stresses.
Basically, just as we react to something in our environment, cells don’t just sit there and take their punishment – they change to try to conquer the problem.
There are 4 important ways in which they do this:
Hypertrophy and Hyperplasia
Hypertrophy is a cellular response that involves the increased size of cells, that results in an increase in size of the affected organ.
Note that there is no increase in the number of cells, rather JUST the size. This type of cellular adaptation to stress occurs in a number of different cells, and is usually coupled with another type of cellular adaptation, hyperplasia.
Hyperplasia is a cellular response that involves the increase in number of cells in response to a stimulus.
Both hyperplasia and hypertrophy occur as compensatory mechanisms to an increased workload on the organ or cell.
To remember which is which, think of the prefix and suffix that make up the word. The suffix “plasia” means “development” and thus hyperplasia means “increased development,” corresponding to an increase in the number of cells. Similarly, “-trophy” means “sustenance, nutrition” and thus, hypertrophy refers, in fact to the very mechanism of hypertrophy, an increase in factors that sustain and allow growth of the cells, which will be explained later.
If cells are divided into cells that are capable of dividing, and cells that are incapable of dividing, we can also divide the way they react to increased stress.
- Cells capable of dividing respond to an increased workload using both hyperplasia and hypertrophy.
- Cells incapable of dividing can only respond to an increased workload by hypertrophy. An example of this is in myocytes, or cardiac muscle cells in myocardial fibres. Thus, the heart mainly responds to an increased workload by hypertrophy. Other examples are adult skeletal muscles and neurons.
Physiologic vs Pathologic Hypertrophy and Hyperplasia:
Hypertrophy and hyperplasia, while it can be physiological to aid the body, may also be disease related, or pathological, and is a very important indicator of disease.
Physiologic Hypertrophy: is caused by an increased workload, increased functional demand or stimulation by hormones and growth factors. Of these, the most common stimulus for hypertrophy is increased workload. An example of workload induced hypertrophy would be the muscle enlargement in bodybuilders as muscles are forced to tolerate new loads. An example of hormone-induced hypertrophy is within the endometrium and myometrium of the uterus, as estrogen upregulation during the follicular stage of the menstrual cycle stimulates an increase in muscle proteins in the stroma of the endometrium and the large smooth muscle layer of the myometrium, and thus, muscle size.