Development of the muscular system

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Development of the muscular system

MSK Module Content

MSK Module Content

Resting membrane potential
Action potentials in myocytes
Neuron action potential
Neuromuscular junction and motor unit
Sliding filament model of muscle contraction
Cholinergic receptors
Lambert-Eaton myasthenic syndrome
Neuromuscular junction disorders: Pathology review
Myasthenia gravis
Myalgias and myositis: Pathology review
Pediatric orthopedic conditions: Clinical
Muscle weakness: Clinical
Slow twitch and fast twitch muscle fibers
Muscle spindles and golgi tendon organs
Muscle contraction
Skeletal muscle histology
Muscular system anatomy and physiology
Lower back pain: Clinical
Back pain: Pathology review
Systemic lupus erythematosus (SLE): Clinical
Osteoporosis
Child abuse: Clinical
Non-steroidal anti-inflammatory drugs
Rheumatoid arthritis
Physiological changes during exercise
Polymyositis
Lordosis, kyphosis, and scoliosis
Spinal disc herniation
Acetaminophen (Paracetamol)
Osteochondroma
Scleroderma
Skeletal system anatomy and physiology
Bone remodeling and repair
Legg-Calve-Perthes disease
Genu varum
Inflammatory myopathies: Clinical
Muscular dystrophies and mitochondrial myopathies: Pathology review
Mitochondrial myopathy
Inclusion body myopathy
Monoclonal antibodies
Spondylolysis
Spondylosis
Spondylitis
Bone disorders: Pathology review
Muscular dystrophy
Mixed connective tissue disease
Cartilage histology
Raynaud phenomenon
Scleroderma: Pathology review
Osteoarthritis
Cartilage structure and growth
Fibrous, cartilage, and synovial joints
Septic arthritis
Slipped capital femoral epiphysis
Bone tumors
Osgood-Schlatter disease (traction apophysitis)
Achondroplasia
Rheumatoid arthritis: Clinical
Developmental dysplasia of the hip
Bone tumors: Pathology review
Neck trauma: Clinical
Spinal cord reflexes
Pediatric bone and joint infections: Clinical
Paget disease of bone
Bone histology
Pediatric bone tumors: Clinical
Anatomy clinical correlates: Bones, joints and muscles of the back
Joints of the wrist and hand
Osteomalacia and rickets
Osteomalacia
Osteopetrosis
Osteoporosis medications
Osteosclerosis
Osteogenesis imperfecta
Osteomyelitis
Clostridium perfringens
Necrotizing fasciitis
Skin and soft tissue infections: Clinical
Brachial plexus
Anatomy of the brachial plexus
Klumpke paralysis
Anatomy clinical correlates: Wrist and hand
Muscles of the hand
Achilles tendon rupture
Rotator cuff tear
Somatosensory receptors
Carpal tunnel syndrome
Patellar tendon rupture
Ankylosing spondylitis
Marfan syndrome
Polymyalgia rheumatica
Reactive arthritis
Seronegative arthritis: Clinical
Psoriatic arthritis
Juvenile idiopathic arthritis
Seronegative and septic arthritis: Pathology review
Rheumatoid arthritis and osteoarthritis: Pathology review
Ehlers-Danlos syndrome
Alport syndrome
Gout
Gout and pseudogout: Pathology review
Antigout medications
Nucleotide metabolism
Joint pain: Clinical
Lesch-Nyhan syndrome
Thoracic outlet syndrome
Introduction to the muscular system
Introduction to the skeletal system
Development of the muscular system
Torticollis
Pigeon toe
Neuromuscular blockers
Myotonic dystrophy
Development of the axial skeleton
Development of the limbs
Muscles of the back
Anatomy of the arm
Anatomy clinical correlates: Clavicle and shoulder

Transcript

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Content Reviewers

Rishi Desai, MD, MPH

The muscular system starts taking shape when the embryo is just a flat little pancake made up of two layers: the epiblast on the dorsal, or back, side, and the hypoblast on the ventral, or front, side.

A line called the primitive streak appears on the epiblast “back” of this two-layered creature.

Cells migrate along the primitive streak during gastrulation, leading to a now three-layered embryo pancake, with each layer containing germ cells that form organs and tissues of the body.

The ventral, or bottom, germ layer is called endoderm, the dorsal, or top, germ layer is called ectoderm, and the layer in between these two is called mesoderm.

Collectively, these germ cells produce all of the organs and tissues in the body.

During week 3, the embryo transitions from a flat organism to a more tubular creature by folding along its longitudinal and lateral axes.

At the same time, a solid rod of mesoderm called the notochord forms on the midline of the embryo.

Above the notochord, the ectoderm invaginates to form the neural tube, an early precursor of the central nervous system.

This is the embryo’s first symmetry axis, and the mesoderm on either side of the neural tube differentiates into three distinct portions: immediately flanking the neural tube there’s the paraxial mesoderm; next, there’s the intermediate mesoderm; and finally, the lateral plate mesoderm.

Between the cells of the lateral plate mesoderm, small gaps appear and coalesce to form the intraembryonic coelom, a cavity inside the embryo’s body.

This cavity separates the lateral plate mesoderm into two layers: a parietal layer that’s in contact with the ectoderm, and a visceral layer that’s in contact with the endoderm.

The paraxial and lateral plate mesoderm will become the skeletal muscles in our body.

Before the mesoderm cells develop into skeletal muscle, they first organize into cell blocks called somites.

Somites arise in pairs from a combination of paraxial mesoderm cells and mesenchyme, which is a soupy fetal tissue containing pluripotent cells.

Around day 20 of development, somites begin to form in the occipital region of the embryo, which is at the base of the head.

Somites continue to form cranio-caudally, or from head-to-tail end of the embryo, with about three pairs forming each day.

Up to 40 somite pairs form by the end of week 5. Some degenerate, while the rest go on to form bone and muscle structures.

Each somite undergoes a split, with cells from the ventral portion forming sclerotome, creating the vertebrae and the ribs.

Cells from the dorsomedial lip of the somite (the top right layer of cubes here) mix with some cells from the ventrolateral lip in the opposite corner of the cube (the bottom left) to form a new, mixed tissue called dermomyotome.

Dermomyotome cells further differentiate into dermatome and myotome cells, which turn into the dermis layer of the skin and into muscles, respectively.

Now, fast forwarding a bit, the muscles of the myotome start to develop.

One way to categorize the muscles is according to their innervation.

Key Takeaways

Development of the muscular system starts at around week d of gestation. The muscular system begins with the formation of muscle cells called myoblasts. Myoblasts originate from the mesoderm and fuse together to form long and multinucleated fibers called muscle fibers. Muscle fibers are attached by collagenous connective tissues, and the entire muscle is enclosed in a fibrous capsule. All skeletal and cardiac muscles and most smooth muscles arise from mesoderm cells, except pupillary muscles and the sweat and mammary glands, which arise from ectoderm.