Module 25: Muscle Tissue

Lesson 7: Cardiac Muscle Tissue

Mô Cơ Tim

Nội dung bài học:
Mỗi bài học (lesson) bao gồm 4 phần chính: Thuật ngữ, Luyện Đọc, Luyện Nghe, và Bàn Luận.
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Dưới đây là danh sách những thuật ngữ Y khoa của module Muscle Tissue.
Khái quát được số lượng thuật ngữ sẽ xuất hiện trong bài đọc và nghe sẽ giúp bạn thoải mái tiêu thụ nội dung hơn. Sau khi hoàn thành nội dung đọc và nghe, bạn hãy quay lại đây và luyện tập (practice) để quen dần các thuật ngữ này. Đừng ép bản thân phải nhớ các thuật ngữ này vội vì bạn sẽ gặp và ôn lại danh sách này trong những bài học (lesson) khác của cùng một module.

Medical Terminology: Muscle Tissue

acetylcholine (ACh)
neurotransmitter that binds at a motor end-plate to trigger depolarization
actin
protein that makes up most of the thin myofilaments in a sarcomere muscle fiber
action potential
change in voltage of a cell membrane in response to a stimulus that results in transmission of an electrical signal; unique to neurons and muscle fibers
aerobic respiration
production of ATP in the presence of oxygen
angiogenesis
formation of blood capillary networks
aponeurosis
broad, tendon-like sheet of connective tissue that attaches a skeletal muscle to another skeletal muscle or to a bone
ATPase
enzyme that hydrolyzes ATP to ADP
atrophy
loss of structural proteins from muscle fibers
autorhythmicity
heart’s ability to control its own contractions
calmodulin
regulatory protein that facilitates contraction in smooth muscles
cardiac muscle
striated muscle found in the heart; joined to one another at intercalated discs and under the regulation of pacemaker cells, which contract as one unit to pump blood through the circulatory system. Cardiac muscle is under involuntary control.
concentric contraction
muscle contraction that shortens the muscle to move a load
contractility
ability to shorten (contract) forcibly
contraction phase
twitch contraction phase when tension increases
creatine phosphate
phosphagen used to store energy from ATP and transfer it to muscle
dense body
sarcoplasmic structure that attaches to the sarcolemma and shortens the muscle as thin filaments slide past thick filaments
depolarize
to reduce the voltage difference between the inside and outside of a cell’s plasma membrane (the sarcolemma for a muscle fiber), making the inside less negative than at rest
desmosome
cell structure that anchors the ends of cardiac muscle fibers to allow contraction to occur
eccentric contraction
muscle contraction that lengthens the muscle as the tension is diminished
elasticity
ability to stretch and rebound
endomysium
loose, and well-hydrated connective tissue covering each muscle fiber in a skeletal muscle
epimysium
outer layer of connective tissue around a skeletal muscle
excitability
ability to undergo neural stimulation
excitation-contraction coupling
sequence of events from motor neuron signaling to a skeletal muscle fiber to contraction of the fiber’s sarcomeres
extensibility
ability to lengthen (extend)
fascicle
bundle of muscle fibers within a skeletal muscle
fast glycolytic (FG)
muscle fiber that primarily uses anaerobic glycolysis
fast oxidative (FO)
intermediate muscle fiber that is between slow oxidative and fast glycolytic fibers
fibrosis
replacement of muscle fibers by scar tissue
glycolysis
anaerobic breakdown of glucose to ATP
graded muscle response
modification of contraction strength
hyperplasia
process in which one cell splits to produce new cells
hypertonia
abnormally high muscle tone
hypertrophy
addition of structural proteins to muscle fibers
hypotonia
abnormally low muscle tone caused by the absence of low-level contractions
intercalated disc
part of the sarcolemma that connects cardiac tissue, and contains gap junctions and desmosomes
isometric contraction
muscle contraction that occurs with no change in muscle length
isotonic contraction
muscle contraction that involves changes in muscle length
lactic acid
product of anaerobic glycolysis
latch-bridges
subset of a cross-bridge in which actin and myosin remain locked together
latent period
the time when a twitch does not produce contraction
motor end-plate
sarcolemma of muscle fiber at the neuromuscular junction, with receptors for the neurotransmitter acetylcholine
motor unit
motor neuron and the group of muscle fibers it innervates
muscle tension
force generated by the contraction of the muscle; tension generated during isotonic contractions and isometric contractions
muscle tone
low levels of muscle contraction that occur when a muscle is not producing movement
myoblast
muscle-forming stem cell
myofibril
long, cylindrical organelle that runs parallel within the muscle fiber and contains the sarcomeres
myogram
instrument used to measure twitch tension
myosin
protein that makes up most of the thick cylindrical myofilament within a sarcomere muscle fiber
myotube
fusion of many myoblast cells
neuromuscular junction (NMJ)
synapse between the axon terminal of a motor neuron and the section of the membrane of a muscle fiber with receptors for the acetylcholine released by the terminal
neurotransmitter
signaling chemical released by nerve terminals that bind to and activate receptors on target cells
oxygen debt
amount of oxygen needed to compensate for ATP produced without oxygen during muscle contraction
pacesetter cell
cell that triggers action potentials in smooth muscle
pericyte
stem cell that regenerates smooth muscle cells
perimysium
connective tissue that bundles skeletal muscle fibers into fascicles within a skeletal muscle
power stroke
action of myosin pulling actin inward (toward the M line)
pyruvic acid
product of glycolysis that can be used in aerobic respiration or converted to lactic acid
recruitment
increase in the number of motor units involved in contraction
relaxation phase
period after twitch contraction when tension decreases
sarcolemma
plasma membrane of a skeletal muscle fiber
sarcomere
longitudinally, repeating functional unit of skeletal muscle, with all of the contractile and associated proteins involved in contraction
sarcopenia
age-related muscle atrophy
sarcoplasm
cytoplasm of a muscle cell
sarcoplasmic reticulum (SR)
specialized smooth endoplasmic reticulum, which stores, releases, and retrieves Ca++
satellite cell
stem cell that helps to repair muscle cells
skeletal muscle
striated, multinucleated muscle that requires signaling from the nervous system to trigger contraction; most skeletal muscles are referred to as voluntary muscles that move bones and produce movement
slow oxidative (SO)
muscle fiber that primarily uses aerobic respiration
smooth muscle
nonstriated, mononucleated muscle in the skin that is associated with hair follicles; assists in moving materials in the walls of internal organs, blood vessels, and internal passageways
somites
blocks of paraxial mesoderm cells
stress-relaxation response
relaxation of smooth muscle tissue after being stretched
synaptic cleft
space between a nerve (axon) terminal and a motor end-plate
T-tubule
projection of the sarcolemma into the interior of the cell
tetanus
a continuous fused contraction
thick filament
the thick myosin strands and their multiple heads projecting from the center of the sarcomere toward, but not all to way to, the Z-discs
thin filament
thin strands of actin and its troponin-tropomyosin complex projecting from the Z-discs toward the center of the sarcomere
treppe
stepwise increase in contraction tension
triad
the grouping of one T-tubule and two terminal cisternae
tropomyosin
regulatory protein that covers myosin-binding sites to prevent actin from binding to myosin
troponin
regulatory protein that binds to actin, tropomyosin, and calcium
twitch
single contraction produced by one action potential
varicosity
enlargement of neurons that release neurotransmitters into synaptic clefts
visceral muscle
smooth muscle found in the walls of visceral organs
voltage-gated sodium channels
membrane proteins that open sodium channels in response to a sufficient voltage change, and initiate and transmit the action potential as Na+ enters through the channel
wave summation
addition of successive neural stimuli to produce greater contraction
Nội dung này đang được cập nhật.
Dưới đây là các bài văn nằm ở bên trái. Ở bên phải là các bài luyện tập (practice) để đánh giá khả năng đọc hiểu của bạn. Sẽ khó khăn trong thời gian đầu nếu vốn từ vựng của bạn còn hạn chế, đặc biệt là từ vựng Y khoa. Hãy kiên nhẫn và đọc nhiều nhất có kể, lượng kiến thức tích tụ dần sẽ giúp bạn đọc thoải mái hơn.
Cardiac muscle tissue is only found in the heart. Highly coordinated contractions of cardiac muscle pump blood into the vessels of the circulatory system. Similar to skeletal muscle, cardiac muscle is striated and organized into sarcomeres, possessing the same banding organization as skeletal muscle (Figure 1). However, cardiac muscle fibers are shorter than skeletal muscle fibers and usually contain only one nucleus, which is located in the central region of the cell. Cardiac muscle fibers also possess many mitochondria and myoglobin, as ATP is produced primarily through aerobic metabolism. Cardiac muscle fibers cells also are extensively branched and are connected to one another at their ends by intercalated discs. An intercalated disc allows the cardiac muscle cells to contract in a wave-like pattern so that the heart can work as a pump.

Intercalated discs are part of the sarcolemma and contain two structures important in cardiac muscle contraction: gap junctions and desmosomes. A gap junction forms channels between adjacent cardiac muscle fibers that allow the depolarizing current produced by cations to flow from one cardiac muscle cell to the next. This joining is called electric coupling, and in cardiac muscle it allows the quick transmission of action potentials and the coordinated contraction of the entire heart. This network of electrically connected cardiac muscle cells creates a functional unit of contraction called a syncytium. The remainder of the intercalated disc is composed of desmosomes. A desmosome is a cell structure that anchors the ends of cardiac muscle fibers together so the cells do not pull apart during the stress of individual fibers contracting (Figure 2).

Contractions of the heart (heartbeats) are controlled by specialized cardiac muscle cells called pacemaker cells that directly control heart rate. Although cardiac muscle cannot be consciously controlled, the pacemaker cells respond to signals from the autonomic nervous system (ANS) to speed up or slow down the heart rate. The pacemaker cells can also respond to various hormones that modulate heart rate to control blood pressure.

The wave of contraction that allows the heart to work as a unit, called a functional syncytium, begins with the pacemaker cells. This group of cells is self-excitable and able to depolarize to threshold and fire action potentials on their own, a feature called autorhythmicity; they do this at set intervals which determine heart rate. Because they are connected with gap junctions to surrounding muscle fibers and the specialized fibers of the heart’s conduction system, the pacemaker cells are able to transfer the depolarization to the other cardiac muscle fibers in a manner that allows the heart to contract in a coordinated manner.

Another feature of cardiac muscle is its relatively long action potentials in its fibers, having a sustained depolarization “plateau.” The plateau is produced by Ca++ entry though voltage-gated calcium channels in the sarcolemma of cardiac muscle fibers. This sustained depolarization (and Ca++ entry) provides for a longer contraction than is produced by an action potential in skeletal muscle. Unlike skeletal muscle, a large percentage of the Ca++ that initiates contraction in cardiac muscles comes from outside the cell rather than from the SR.

OpenStax. (2022). Anatomy and Physiology 2e. Rice University. Retrieved June 15, 2023. ISBN-13: 978-1-711494-06-7 (Hardcover) ISBN-13: 978-1-711494-05-0 (Paperback) ISBN-13: 978-1-951693-42-8 (Digital). License: Attribution 4.0 International (CC BY 4.0). Access for free at openstax.org.

Cardiac muscle tissue is only found in the heart. LM × 1600. (Micrograph provided by the Regents of University of Michigan Medical School © 2012)

Intercalated discs are part of the cardiac muscle sarcolemma and they contain gap junctions and desmosomes.

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Dưới đây là video và các luyện tập (practice) của bài này. Nghe là một kĩ năng khó, đặc biệt là khi chúng ta chưa quen nội dung và chưa có nhạy cảm ngôn ngữ. Nhưng cứ đi thật chậm và đừng bỏ cuộc.
Xem video và cảm nhận nội dung bài. Bạn có thể thả trôi, cảm nhận dòng chảy ngôn ngữ và không nhất thiết phải hiểu toàn bộ bài. Bên dưới là script để bạn khái quát nội dụng và tra từ mới.
Script:
  1. Cardiac muscle, found exclusively in the heart, is a type of striated muscle.
  2. Its fibers, which are characterized by a single nucleus, are branched and interconnected through intercalated discs.
  3. These discs play a crucial role, housing gap junctions for depolarization between cells and desmosomes that maintain fiber cohesion during heart contractions.
  4. When it comes to triggering contraction in cardiac muscle fibers, it follows a process similar to skeletal muscle, with calcium ions playing a key role.
  5. Unlike skeletal muscle, in cardiac muscle, calcium ions are released from the sarcoplasmic reticulum and also enter through voltage-gated calcium channels in the sarcolemma.
  6. Pacemaker cells are responsible for initiating the spontaneous contraction of cardiac muscle, acting as a functional unit known as a syncytium.
  7. This orchestration ensures the coordinated and rhythmic beating of the heart.
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