Introduction to the muscular system

Last updated: January 14, 2026

Introduction to the muscular system

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Introduction to the skeletal system
Introduction to the cardiovascular system
Introduction to the muscular system
Anatomical terminology
Anatomy of the muscles and nerves of the posterior abdominal wall
Anatomy of the abdominal viscera: Innervation of the abdominal viscera
Enteric nervous system
Physiological changes during exercise
Pentose phosphate pathway
Glycolysis
Electron transport chain and oxidative phosphorylation
Development of the face and palate
Pharyngeal arches, pouches, and clefts
Development of the teeth
Development of the tongue
Citric acid cycle
Gluconeogenesis
Nitrogen and urea cycle
Amino acid metabolism
Fatty acid synthesis
Ketone body metabolism
Fatty acid oxidation
Cholesterol metabolism
Glucose-6-phosphate dehydrogenase (G6PD) deficiency
Glycogen storage disease type III
Glycogen storage disease type IV
Glycogen storage disease type V
Gaucher disease (NORD)
Cystinosis
Ornithine transcarbamylase deficiency
Familial hypercholesterolemia
Disorders of carbohydrate metabolism: Pathology review
Dyslipidemias: Pathology review
Glycogen storage disorders: Pathology review
Disorders of fatty acid metabolism: Pathology review
Lysosomal storage disorders: Pathology review
Disorders of amino acid metabolism: Pathology review
Carbohydrates and sugars
Proteins
Fats and lipids
Vitamin B12 deficiency
Fat-soluble vitamin deficiency and toxicity: Pathology review
Water-soluble vitamin deficiency and toxicity: B1-B7: Pathology review
Zinc deficiency and protein-energy malnutrition: Pathology review
Nernst equation
Nernst equation
Peroxisomal disorders: Pathology review
Peroxisomal disorders: Pathology review
Nuclear structure
Nuclear structure
Amino acids and protein folding
Amino acids and protein folding
Nucleotide metabolism
Nucleotide metabolism
Mitosis and meiosis
Mitosis and meiosis
Adenosine deaminase deficiency
Adenosine deaminase deficiency
Purine and pyrimidine synthesis and metabolism disorders: Pathology review
Purine and pyrimidine synthesis and metabolism disorders: Pathology review
Polymerase chain reaction (PCR) and reverse-transcriptase PCR (RT-PCR)
Polymerase chain reaction (PCR) and reverse-transcriptase PCR (RT-PCR)
ELISA (Enzyme-linked immunosorbent assay)
DNA cloning
Fluorescence in situ hybridization
Gel electrophoresis and genetic testing
Lactose intolerance
Down syndrome (Trisomy 21)
Edwards syndrome (Trisomy 18)
Patau syndrome (Trisomy 13)
Huntington disease
Fragile X syndrome
Myotonic dystrophy
Friedreich ataxia
Prader-Willi syndrome
Angelman syndrome
Polycystic kidney disease
Familial adenomatous polyposis
Alpha-thalassemia
Beta-thalassemia
Miscellaneous genetic disorders: Pathology review
Muscular dystrophies and mitochondrial myopathies: Pathology review
Autosomal trisomies: Pathology review
Mitochondrial myopathy
Gestational diabetes
Placental abruption
Preeclampsia & eclampsia
Fetal alcohol syndrome
Testicular tumors: Pathology review
Disorders of sex chromosomes: Pathology review
Prostate disorders and cancer: Pathology review
Uterine disorders: Pathology review
Cervical cancer: Pathology review
Ovarian cysts and tumors: Pathology review
Vaginal and vulvar disorders: Pathology review
Breast cancer: Pathology review
Congenital TORCH infections: Pathology review
Disorders of sexual development and sex hormones: Pathology review
Complications during pregnancy: Pathology review
Amenorrhea: Pathology review
Adrenergic antagonists: Alpha blockers
Androgens and antiandrogens
PDE5 inhibitors
Aromatase inhibitors
Uterine stimulants and relaxants
Estrogens and antiestrogens
Progestins and antiprogestins

Transcript

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The human body consists of hundreds of muscles, which come in all different shapes and sizes. Each muscle’s particular structure allows it to perform a specific function.

The muscles are attached to bones or other tissues, to help us maintain position, perform movements and even protect some organs.

Ok, now muscle tissue is made up of contractile cells, often called muscle fibers. Muscle tissue can be grouped into 3 types; skeletal, cardiac and smooth muscle.

Skeletal muscles connect to the skeleton and other structures like the eyes to help with movement and stability of the body.

These muscles are voluntary, meaning that we have active control of them to perform movements, like flexing your elbow.

Cardiac muscle is the muscle tissue that makes up the walls of the heart. These muscles contract in a rhythmic way to pump blood to the whole body and they are involuntary meaning that we can’t consciously control this type of muscle.

Lastly, is smooth muscle, which mainly lies in the walls of blood vessels and hollow organs. In blood vessels, smooth muscle helps contract the vessel walls to alter their diameter, which helps control blood flow.

In hollow organs, smooth muscles perform rhythmic contractions called peristaltic contractions, which moves the contents of these organs in one direction, like food in the stomach or small intestine.

Smooth muscle is also under involuntary control. Alright, now muscles come in a variety of shapes that help serve their specific functions.

For example, a flat muscle has parallel fibers, and often has a flat sheet-like tendon called an aponeurosis - as is the case for the external oblique muscle covering the abdomen.

Next is a quadrate muscle, which describes a square muscle with four equal sides. An example of a quadrate muscle is the famous six pack, anatomically called the rectus abdominis, which is a long paired muscle that is divided into square-like portions by bands of connective tissue.

Pennate muscles, on the other hand, have their fibers attaching obliquely to a tendon. These muscles can be grouped into unipennate, bipennate or multipennate muscles depending on the relationship between the muscle fascicles and the tendon.

Unipennate muscle fibers go in one direction, and merge on one side of its tendon, like the extensor digitorum longus muscle in the leg.

Bipennate muscles look more like a feather, having oblique fibers on both sides of the tendon, like the rectus femoris of the anterior thigh.

And multipennate muscles have fascicles in different directions, attaching to a branched central tendon, like the deltoid muscle, covering the shoulder.

Next are fusiform muscles, which have a thick muscle belly that becomes tapered at both ends. An example of a fusiform muscle would be the biceps brachii.

Speaking of bi-ceps brachii, multiheaded or multibellied muscles have more than one head of attachment or more than one contractile belly.

Both the biceps brachii and triceps brachii muscles, have two and three fusiform heads, respectively, and thus could also be referred to as multiheaded.

Examples of multibellied muscles include the gastrocnemius muscle in the leg, or the digastric muscle under the jaw which both have two bellies.

Next up are the convergent muscles, which are large muscles that arise from multiple points, but their fibers converge to insert into a single point.

A good example is the pectoralis major muscle of the anterior chest wall. This muscle arises from the sternum, ribs, and clavicle, but inserts into a single spot on the humerus.

Lastly, are circular or sphincteral muscles, which are indeed shaped like a circle. Typically, these muscles surround a body opening, and their circular shape causes constriction of the opening during contraction.

For example, the orbicularis oris surrounds the mouth and when contracted, it helps constrict the oral opening, seen when puckering your lips when whistling.

Okay, now let’s take a deep breath and have a quick quiz! Can you identify the shapes of these muscles? Alright, now muscles attach to different body parts, including bones, cartilage, skin or even other muscles.

For example, many facial muscles attach to the skin of the face, which allows facial muscles to move the skin of the face to produce facial expressions like smiling.

Now, every muscle arises from a point, called the origin, and inserts into a point, called the insertion. Typically, the origin is proximal meaning that it is closer to the trunk of the body.

Key Takeaways

Humans' muscular system consists of hundreds of muscles that carry out many different functions. It is made up of skeletal muscles, which are voluntary muscles that we can control, and smooth muscles, which are involuntary muscles that we cannot control. Skeletal muscles are attached to bones by tendons, and when they contract, they pull on the bones and move the body. Smooth muscles line the walls of blood vessels and organs such as the stomach and intestines, and they contract to move substances through these vessels or organs.

Sources

  1. "Clinically Oriented Anatomy" Lippincott Williams & Wilkins (2013)
  2. "Atlas of Human Anatomy" Saunders/Elsevier (2014)
  3. "Anatomy, Bone Markings" StatPearls (2020 Jan)