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HMS, BM EQ-Bank 893

A competitive swimmer has just consumed a pre-race meal two hours before an important race.

Describe how the digestive and endocrine systems work with the nervous and muscular systems to prepare the body for this high-intensity performance.   (5 marks)

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Sample Answer

Meal digestion (first hour):

  • Stomach and intestines break down carbohydrates into glucose
  • Proteins digest into amino acids for muscle support
  • Fats are processed slowly for sustained energy

Nutrient absorption and storage:

  • Blood glucose levels rise as nutrients enter bloodstream
  • Insulin release facilitates glucose uptake into muscles
  • Muscle glycogen stores increase in preparation
  • Amino acids circulate for muscle repair needs

Pre-race nervous activation (approaching race):

  • Nervous system reduces digestive activity
  • Blood flow shifts from stomach to muscles
  • Alertness and focus increase
  • Stress hormones begin releasing

Hormonal preparation:

  • Adrenaline elevates heart rate and breathing
  • Cortisol mobilises additional energy stores
  • Blood glucose rises for immediate use
  • Muscles become more sensitive to nerve signals

System coordination features:

  • Digestive system provides fuel while nervous system times its use
  • Hormones link all systems together
  • Muscles receive nutrients through blood while preparing for action
  • All four systems synchronise for optimal race readiness
Show Worked Solution

Sample Answer

Meal digestion (first hour):

  • Stomach and intestines break down carbohydrates into glucose
  • Proteins digest into amino acids for muscle support
  • Fats are processed slowly for sustained energy

Nutrient absorption and storage:

  • Blood glucose levels rise as nutrients enter bloodstream
  • Insulin release facilitates glucose uptake into muscles
  • Muscle glycogen stores increase in preparation
  • Amino acids circulate for muscle repair needs

Pre-race nervous activation (approaching race):

  • Nervous system reduces digestive activity
  • Blood flow shifts from stomach to muscles
  • Alertness and focus increase
  • Stress hormones begin releasing

Hormonal preparation:

  • Adrenaline elevates heart rate and breathing
  • Cortisol mobilises additional energy stores
  • Blood glucose rises for immediate use
  • Muscles become more sensitive to nerve signals

System coordination features:

  • Digestive system provides fuel while nervous system times its use
  • Hormones link all systems together
  • Muscles receive nutrients through blood while preparing for action
  • All four systems synchronise for optimal race readiness

HMS, BM EQ-Bank 888

A sprinter is positioned in the starting blocks of a 100-metre race.

Explain how the nervous, muscular and circulatory systems work together from the "on your marks" command to the first few seconds of the race.   (5 marks)

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Sample Answer

“On your marks” phase:

  • The nervous system heightens alertness and prepares motor pathways for action.
  • This causes heart rate to begin increasing through nerve signals to the heart.
  • As a result, the circulatory system prepares to deliver more oxygen to muscles.

“Set” position:

  • Nerve signals activate muscles to create tension in legs and arms.
  • This muscle tension enables explosive force production when the gun fires.
  • Meanwhile, blood flow increases to leg muscles through vasodilation.
  • This increased blood flow ensures muscles have oxygen for immediate use.

Gun fired – first seconds:

  • The nervous system sends rapid signals to leg muscles.
  • These signals trigger powerful muscle contractions in quadriceps and glutes.
  • Consequently, the sprinter drives forcefully off the blocks.
  • Heart rate increases rapidly because muscles demand more oxygen.
  • This coordination between all three systems produces maximum acceleration.

System integration:

  • The interaction shows how nerve signals control both muscle action and heart response.
  • While the nervous system coordinates movement, the circulatory system supports energy needs.
  • Therefore, successful sprint starts require all three systems working together instantly.
Show Worked Solution

Sample Answer

“On your marks” phase:

  • The nervous system heightens alertness and prepares motor pathways for action.
  • This causes heart rate to begin increasing through nerve signals to the heart.
  • As a result, the circulatory system prepares to deliver more oxygen to muscles.

“Set” position:

  • Nerve signals activate muscles to create tension in legs and arms.
  • This muscle tension enables explosive force production when the gun fires.
  • Meanwhile, blood flow increases to leg muscles through vasodilation.
  • This increased blood flow ensures muscles have oxygen for immediate use.

Gun fired – first seconds:

  • The nervous system sends rapid signals to leg muscles.
  • These signals trigger powerful muscle contractions in quadriceps and glutes.
  • Consequently, the sprinter drives forcefully off the blocks.
  • Heart rate increases rapidly because muscles demand more oxygen.
  • This coordination between all three systems produces maximum acceleration.

System integration:

  • The interaction shows how nerve signals control both muscle action and heart response.
  • While the nervous system coordinates movement, the circulatory system supports energy needs.
  • Therefore, successful sprint starts require all three systems working together instantly.

HMS, BM EQ-Bank 887

A tennis player executes a powerful serve.

Describe how the skeletal, muscular, nervous, and circulatory systems work together to generate power and accuracy in this movement.   (5 marks)

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Sample Answer

Skeletal system features:

  • Provides rigid levers through the arm, shoulder, and spinal joints.
  • Joints transfer force from the legs through the kinetic chain to the racquet.
  • Rotational capabilities of the shoulder joint enable the wide range of motion.
  • A stable base is provide through hip and knee alignment.

Muscular system characteristics:

  • Generates force through sequential activation from the ground up. 
  • This activation maximises power throughout the serve.
  • Leg muscles initiate the movement (gastrocnemius, quadriceps)
  • Trunk muscles rotate (obliques, erector spinae)
  • Arm muscles complete the action (deltoids, triceps, wrist flexors).
  • Fast twitch fibres dominate for explosive power.

Nervous system components:

  • Timing and sequencing of muscle contractions coordinated through motor units.
  • Visual processing for ball and target location.
  • Motor neurons activate fast-twitch muscle fibres for explosive power.
  • Cerebellar control for smooth multi-joint movement.

Circulatory system functions:

  • Increased blood flow to active muscles.
  • Localised vasodilation in working areas.
  • Oxygen and nutrient delivery.
  • This supports the high energy demands of the serve.
Show Worked Solution

Sample Answer

Skeletal system features:

  • Provides rigid levers through the arm, shoulder, and spinal joints.
  • Joints transfer force from the legs through the kinetic chain to the racquet.
  • Rotational capabilities of the shoulder joint enable the wide range of motion.
  • A stable base is provide through hip and knee alignment.

Muscular system characteristics:

  • Generates force through sequential activation from the ground up. 
  • This activation maximises power throughout the serve.
  • Leg muscles initiate the movement (gastrocnemius, quadriceps)
  • Trunk muscles rotate (obliques, erector spinae)
  • Arm muscles complete the action (deltoids, triceps, wrist flexors).
  • Fast twitch fibres dominate for explosive power.

Nervous system components:

  • Timing and sequencing of muscle contractions coordinated through motor units.
  • Visual processing for ball and target location.
  • Motor neurons activate fast-twitch muscle fibres for explosive power.
  • Cerebellar control for smooth multi-joint movement.

Circulatory system functions:

  • Increased blood flow to active muscles.
  • Localised vasodilation in working areas.
  • Oxygen and nutrient delivery.
  • This supports the high energy demands of the serve.

HMS, BM EQ-Bank 886

During an archery competition, an athlete must control their breathing while aiming.

Outline how the respiratory and nervous systems interact to enhance accuracy during the aiming phase.   (3 marks)

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Sample Answer

Breathing control:

  • Nervous system signals respiratory muscles to slow breathing rate.
  • Breath held briefly at end of exhalation phase.
  • Reduced diaphragm movement minimises body sway.

Neural regulation:

  • Parasympathetic activation lowers heart rate during aim.
  • Decreased pulse strength reduces rifle/bow movement.
  • Proprioceptors relay body position data to brain.

Focus enhancement:

  • Controlled breathing activates calming neural pathways.
  • Reduced respiratory rate decreases physiological arousal.
  • Oxygen levels maintained through efficient gas exchange.
Show Worked Solution

Sample Answer

Breathing control:

  • Nervous system signals respiratory muscles to slow breathing rate.
  • Breath held briefly at end of exhalation phase.
  • Reduced diaphragm movement minimises body sway.

Neural regulation:

  • Parasympathetic activation lowers heart rate during aim.
  • Decreased pulse strength reduces rifle/bow movement.
  • Proprioceptors relay body position data to brain.

Focus enhancement:

  • Controlled breathing activates calming neural pathways.
  • Reduced respiratory rate decreases physiological arousal.
  • Oxygen levels maintained through efficient gas exchange.

HMS, BM EQ-Bank 884

A basketball player performs a jump shot.

Describe how the nervous, muscular, and skeletal systems interact to produce this coordinated movement.   (4 marks)

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Sample Answer

Preparation phase features:

  • Nervous system processes basket location and defender positions.
  • Motor cortex signals leg muscles for coordinated contraction.
  • Skeletal joints flex at ankles, knees and hips.
  • Muscles store elastic energy through eccentric loading.

Jump execution characteristics:

  • Agonist muscles (quadriceps, gastrocnemius) contract concentrically.
  • Antagonist muscles (hamstrings) relax to allow extension.
  • Skeletal levers provide mechanical advantage for upward force.
  • Proprioceptors relay body position information continuously.

Shot release coordination:

  • Fine motor control activates arm and hand muscles.
  • Skeletal alignment maintains balance during flight.
  • Visual feedback guides ball trajectory.
  • All systems synchronise for accurate timing.
Show Worked Solution

Sample Answer

Preparation phase features:

  • Nervous system processes basket location and defender positions.
  • Motor cortex signals leg muscles for coordinated contraction.
  • Skeletal joints flex at ankles, knees and hips.
  • Muscles store elastic energy through eccentric loading.

Jump execution characteristics:

  • Agonist muscles (quadriceps, gastrocnemius) contract concentrically.
  • Antagonist muscles (hamstrings) relax to allow extension.
  • Skeletal levers provide mechanical advantage for upward force.
  • Proprioceptors relay body position information continuously.

Shot release coordination:

  • Fine motor control activates arm and hand muscles.
  • Skeletal alignment maintains balance during flight.
  • Visual feedback guides ball trajectory.
  • All systems synchronise for accurate timing.

HMS, BM EQ-Bank 882 MC

A gymnast is performing a handstand. Which body systems are most directly involved in maintaining balance in this inverted position?

  1. Endocrine and digestive systems
  2. Nervous and skeletal systems
  3. Circulatory and respiratory systems
  4. Digestive and circulatory systems
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\(B\)

Show Worked Solution
  • B is correct: The nervous system detects body position and coordinates muscle adjustments while the skeletal system provides structural support.

Other Options:

  • A is incorrect: Endocrine and digestive systems don’t directly control balance.
  • C is incorrect: Circulatory and respiratory systems support activity but don’t maintain balance.
  • D is incorrect: Neither system has a primary role in balance control.

HMS, BM EQ-Bank 118

Analyse how body systems work together during the start, middle and end phases of a 5 km run.   (8 marks)

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Sample Answer:

Overview Statement:

  • A 5km run requires coordinated interactions between respiratory, circulatory, muscular, nervous and endocrine systems.
  • Their relationships change from initial mobilisation through steady state to fatigue management.

Component Relationship 1 – Start Phase (0-5 minutes):

  • Breathing rate increases rapidly causing more oxygen to enter the lungs.
  • This enables the heart to pump oxygenated blood to working muscles.
  • Adrenaline release triggers increased heart rate and vasodilation in leg muscles.
  • These changes work together to transition from rest to running pace.
  • Blood glucose provides immediate energy while the endocrine system mobilises stored fuel.

Component Relationship 2 – Middle Phase (5-20 minutes):

  • Respiratory and circulatory systems establish steady-state function at elevated levels.
  • This coordination maintains consistent oxygen delivery matching muscle demand.
  • The nervous system settles into efficient motor patterns reducing energy waste.
  • Muscles utilise oxygen aerobically which produces sustainable energy.
  • The stability reveals how systems synchronise for prolonged effort.

Component Relationship 3 – End Phase (20-30 minutes):

  • Muscle fatigue forces the nervous system to recruit additional motor units.
  • This compensation allows running form maintenance despite tiredness.
  • Breathing remains elevated to clear accumulating metabolic waste.
  • The circulatory system works harder to remove lactate and deliver oxygen.
  • These adjustments show how systems adapt to complete the distance.

Implications:

  • The analysis demonstrates that successful running requires dynamic system coordination.
  • Each phase demands different interaction patterns between the same systems.
  • Therefore, endurance performance depends on systems adapting their relationships throughout exercise.
Show Worked Solution

Sample Answer:

Overview Statement:

  • A 5km run requires coordinated interactions between respiratory, circulatory, muscular, nervous and endocrine systems.
  • Their relationships change from initial mobilisation through steady state to fatigue management.

Component Relationship 1 – Start Phase (0-5 minutes):

  • Breathing rate increases rapidly causing more oxygen to enter the lungs.
  • This enables the heart to pump oxygenated blood to working muscles.
  • Adrenaline release triggers increased heart rate and vasodilation in leg muscles.
  • These changes work together to transition from rest to running pace.
  • Blood glucose provides immediate energy while the endocrine system mobilises stored fuel.

Component Relationship 2 – Middle Phase (5-20 minutes):

  • Respiratory and circulatory systems establish steady-state function at elevated levels.
  • This coordination maintains consistent oxygen delivery matching muscle demand.
  • The nervous system settles into efficient motor patterns reducing energy waste.
  • Muscles utilise oxygen aerobically which produces sustainable energy.
  • The stability reveals how systems synchronise for prolonged effort.

Component Relationship 3 – End Phase (20-30 minutes):

  • Muscle fatigue forces the nervous system to recruit additional motor units.
  • This compensation allows running form maintenance despite tiredness.
  • Breathing remains elevated to clear accumulating metabolic waste.
  • The circulatory system works harder to remove lactate and deliver oxygen.
  • These adjustments show how systems adapt to complete the distance.

Implications:

  • The analysis demonstrates that successful running requires dynamic system coordination.
  • Each phase demands different interaction patterns between the same systems.
  • Therefore, endurance performance depends on systems adapting their relationships throughout exercise.

HMS, BM EQ-Bank 117

Analyse how the skeletal, muscular and nervous systems work together differently in a power clean versus a deadlift.   (8 marks)

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Sample Answer

Overview Statement:

  • Power cleans and deadlifts require different interactions between skeletal, muscular and nervous systems.
  • Their relationships vary in timing, force production and movement complexity.

Component Relationship 1 – Movement Speed and Neural Control:

  • Power cleans require the nervous system to coordinate explosive multi-joint movements in under one second.
  • This rapid timing triggers sequential muscle activation from legs to shoulders to arms.
  • Deadlifts involve slower neural control allowing sustained force over 2-4 seconds.
  • The speed difference reveals how neural demands change with movement velocity.
  • Fast movements require precise timing while slow movements need sustained neural drive.

Component Relationship 2 – Force Transfer Through Skeleton:

  • In power cleans, joints act as sequential levers transferring force upward through the body.
  • This creates momentum that travels through hips, spine, shoulders and arms.
  • Deadlifts use the skeletal system as a rigid framework maintaining vertical force.
  • The contrast shows how skeletal function changes with movement type.
  • Dynamic lifts utilise joint mobility while static lifts depend on skeletal stability.

Component Relationship 3 – Muscle Activation Patterns:

  • Power clean muscles fire sequentially, each group building on the previous one’s momentum.
  • This wave-like pattern enables explosive acceleration of the barbell.
  • Deadlift muscles contract simultaneously to produce steady upward force.
  • These patterns demonstrate how the nervous system adapts muscle control to movement demands.

Implications:

  • The analysis reveals that the same three systems can interact in fundamentally different ways.
  • This flexibility allows humans to perform both explosive and grinding movements effectively.
  • Therefore, training programs must consider not just which systems to train, but how they should interact.
Show Worked Solution

Sample Answer

Overview Statement:

  • Power cleans and deadlifts require different interactions between skeletal, muscular and nervous systems.
  • Their relationships vary in timing, force production and movement complexity.

Component Relationship 1 – Movement Speed and Neural Control:

  • Power cleans require the nervous system to coordinate explosive multi-joint movements in under one second.
  • This rapid timing triggers sequential muscle activation from legs to shoulders to arms.
  • Deadlifts involve slower neural control allowing sustained force over 2-4 seconds.
  • The speed difference reveals how neural demands change with movement velocity.
  • Fast movements require precise timing while slow movements need sustained neural drive.

Component Relationship 2 – Force Transfer Through Skeleton:

  • In power cleans, joints act as sequential levers transferring force upward through the body.
  • This creates momentum that travels through hips, spine, shoulders and arms.
  • Deadlifts use the skeletal system as a rigid framework maintaining vertical force.
  • The contrast shows how skeletal function changes with movement type.
  • Dynamic lifts utilise joint mobility while static lifts depend on skeletal stability.

Component Relationship 3 – Muscle Activation Patterns:

  • Power clean muscles fire sequentially, each group building on the previous one’s momentum.
  • This wave-like pattern enables explosive acceleration of the barbell.
  • Deadlift muscles contract simultaneously to produce steady upward force.
  • These patterns demonstrate how the nervous system adapts muscle control to movement demands.

Implications:

  • The analysis reveals that the same three systems can interact in fundamentally different ways.
  • This flexibility allows humans to perform both explosive and grinding movements effectively.
  • Therefore, training programs must consider not just which systems to train, but how they should interact.

HMS, BM EQ-Bank 115

Analyse how the nervous and respiratory systems work together during high-intensity interval training.   (8 marks)

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Sample Answer

Overview Statement:

  • High-intensity interval training requires precise coordination between nervous and respiratory systems.
  • Their relationships control oxygen delivery, monitor metabolic demands, and adapt breathing patterns throughout work-recovery cycles.

Component Relationship 1 – Neural Control of Breathing:

  • The motor cortex activates muscles while the medulla oblongata simultaneously controls breathing rate.
  • During work intervals, breathing rate increases significantly in response to neural signals.
  • CO2 sensors directly influence the respiratory centre to increase the amount of air breathed per breath.
  • This relationship enables rapid oxygen uptake matching muscle demands.
  • The connection demonstrates how nerve centres coordinate movement with breathing.

Component Relationship 2 – Feedback Systems:

  • Special sensors in the body detect rising CO2 and falling O2 levels during intense work.
  • These sensors trigger nerve signals that adjust breathing depth and rate.
  • The nervous system responds by increasing both respiratory rate and the amount of air per breath.
  • This interaction reveals how body signals control breathing changes.
  • Recovery breathing remains elevated due to continued neural stimulation.

Component Relationship 3 – Training Adaptations:

  • Repeated HIIT sessions lead to improved neural-respiratory coordination.
  • Neural pathways become more efficient at anticipating breathing needs.
  • This adaptation results in faster respiratory responses between intervals.
  • Trained athletes develop better synchronisation of breathing with work phases.

Implications:

  • The interdependence shows that HIIT effectiveness relies on neural-respiratory integration.
  • This means training improves both systems together, not separately.
  • Therefore, optimal HIIT performance requires developing neural control alongside respiratory capacity.
Show Worked Solution

Sample Answer

Overview Statement:

  • High-intensity interval training requires precise coordination between nervous and respiratory systems.
  • Their relationships control oxygen delivery, monitor metabolic demands, and adapt breathing patterns throughout work-recovery cycles.

Component Relationship 1 – Neural Control of Breathing:

  • The motor cortex activates muscles while the medulla oblongata simultaneously controls breathing rate.
  • During work intervals, breathing rate increases significantly in response to neural signals.
  • CO2 sensors directly influence the respiratory centre to increase the amount of air breathed per breath.
  • This relationship enables rapid oxygen uptake matching muscle demands.
  • The connection demonstrates how nerve centres coordinate movement with breathing.

Component Relationship 2 – Feedback Systems:

  • Special sensors in the body detect rising CO2 and falling O2 levels during intense work.
  • These sensors trigger nerve signals that adjust breathing depth and rate.
  • The nervous system responds by increasing both respiratory rate and the amount of air per breath.
  • This interaction reveals how body signals control breathing changes.
  • Recovery breathing remains elevated due to continued neural stimulation.

Component Relationship 3 – Training Adaptations:

  • Repeated HIIT sessions lead to improved neural-respiratory coordination.
  • Neural pathways become more efficient at anticipating breathing needs.
  • This adaptation results in faster respiratory responses between intervals.
  • Trained athletes develop better synchronisation of breathing with work phases.

Implications:

  • The interdependence shows that HIIT effectiveness relies on neural-respiratory integration.
  • This means training improves both systems together, not separately.
  • Therefore, optimal HIIT performance requires developing neural control alongside respiratory capacity.

HMS, BM EQ-Bank 112

Analyse how THREE body systems work together to maintain balance during a gymnastics beam routine.   (6 marks)

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Sample Answer – Nervous system, muscular system and skeletal system

Overview Statement:

  • Balance during beam routines requires nervous, muscular and skeletal systems working interdependently.
  • Their relationships create continuous adjustments maintaining equilibrium on the narrow apparatus.

Component Relationship 1 – Nervous to Muscular:

  • Inner ear organs and proprioceptors detect body position changes instantly.
  • These sensors directly cause muscles to contract for balance correction.
  • Vision works with body position sensors to show where the gymnast is in space.
  • The connection reveals how sensing movement enables quick muscle responses.
  • Such coordination shows why nerve signals and muscle actions must work together for balance.

Component Relationship 2 – Muscular to Skeletal:

  • Core muscles maintain constant isometric tension around the spine.
  • These contractions work through skeletal attachment points to stabilise posture.
  • Limb muscles interact with joint levers to create precise adjustments.
  • This connection shows how muscles use bones as mechanical advantages.
  • The relationship enables fine-tuned movements essential for beam performance.

Implications:

  • All three systems depend on continuous communication for successful balance.
  • Nerves sense position which causes muscles to move using bones as levers.
  • The interdependence means interruptions to any system affects balance ability.
  • Therefore, gymnastic training must develop all three systems equally.

Show Worked Solution

Sample Answer – Nervous system, muscular system and skeletal system

Overview Statement:

  • Balance during beam routines requires nervous, muscular and skeletal systems working interdependently.
  • Their relationships create continuous adjustments maintaining equilibrium on the narrow apparatus.

Component Relationship 1 – Nervous to Muscular:

  • Inner ear organs and proprioceptors detect body position changes instantly.
  • These sensors directly cause muscles to contract for balance correction.
  • Vision works with body position sensors to show where the gymnast is in space.
  • The connection reveals how sensing movement enables quick muscle responses.
  • Such coordination shows why nerve signals and muscle actions must work together for balance.

Component Relationship 2 – Muscular to Skeletal:

  • Core muscles maintain constant isometric tension around the spine.
  • These contractions work through skeletal attachment points to stabilise posture.
  • Limb muscles interact with joint levers to create precise adjustments.
  • This connection shows how muscles use bones as mechanical advantages.
  • The relationship enables fine-tuned movements essential for beam performance.

Implications:

  • All three systems depend on continuous communication for successful balance.
  • Nerves sense position which causes muscles to move using bones as levers.
  • The interdependence means interruptions to any system affects balance ability.
  • Therefore, gymnastic training must develop all three systems equally.

HMS, BM EQ-Bank 111

Discuss how the muscular and nervous systems work together in a skilled tennis serve versus a beginner's tennis serve.   (4 marks)

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*PEEL – Structure solution using separate PEEL methods for each side of the argument; [P] Identify the point, [E] expand on the point with a link to question asked, [Ev] apply evidence/examples, [L] linking sentence back to question.

Sample Answer

Arguments for skilled server efficiency:

  • [P] Skilled servers utilise automated motor programmes stored in their nervous system.
  • [E] These programmes enable rapid, unconscious muscle coordination throughout the serve sequence.
  • [Ev] Muscles fire in precise millisecond timing, creating smooth kinetic chains from ground to racquet.
  • [L] This automation therefore produces fluid, powerful serves without conscious thought interference.

Arguments highlighting beginner challenges:

  • [P] Novice players must consciously control each muscle group during their serve.
  • [E] Such deliberate control results in poorly timed muscle contractions and inefficient movement patterns.
  • [Ev] Each phase requires mental processing, leading to segmented motions and opposing muscle tensions.
  • [L] Consequently, this conscious processing prevents the smooth system integration needed for effectiveness.
Show Worked Solution

*PEEL – Structure solution using separate PEEL methods for each side of the argument; [P] Identify the point, [E] expand on the point with a link to question asked, [Ev] apply evidence/examples, [L] linking sentence back to question.

Sample Answer

Arguments for skilled server efficiency:

  • [P] Skilled servers utilise automated motor programmes stored in their nervous system.
  • [E] These programmes enable rapid, unconscious muscle coordination throughout the serve sequence.
  • [Ev] Muscles fire in precise millisecond timing, creating smooth kinetic chains from ground to racquet.
  • [L] This automation therefore produces fluid, powerful serves without conscious thought interference.

Arguments highlighting beginner challenges:

  • [P] Novice players must consciously control each muscle group during their serve.
  • [E] Such deliberate control results in poorly timed muscle contractions and inefficient movement patterns.
  • [Ev] Each phase requires mental processing, leading to segmented motions and opposing muscle tensions.
  • [L] Consequently, this conscious processing prevents the smooth system integration needed for effectiveness.

HMS, BM EQ-Bank 108 MC

During a powerful golf swing, what best describes the respiratory system's interaction with other body systems?

  1. Only supports the circulatory system
  2. Coordinates with multiple systems to meet increased oxygen demands
  3. Works in isolation from other systems
  4. Reduces function to allow other systems to dominate
Show Answers Only

\(B\)

Show Worked Solution
  • B is correct: The respiratory system increases breathing to supply oxygen that multiple systems need during the powerful movement.

Other Options:

  • A is incorrect: The respiratory system supports more than just circulation
  • C is incorrect: No body system works in isolation during movement
  • D is incorrect: The respiratory system increases, not reduces, its function during exercise

HMS, BM EQ-Bank 107 MC

An athlete performs a complex gymnastics routine. How do the skeletal, muscular and nervous systems interact to maintain balance?

  1. Nerves receive sensory input, muscles respond, and skeleton provides stability
  2. Muscles contract randomly while nerves send signals to bones
  3. Skeletal system provides leverage while muscles and nerves are inactive
  4. Bones move independently of muscular and nervous input
Show Answers Only

\(A\)

Show Worked Solution
  • A is correct: The three systems work together with nerves detecting position, muscles making adjustments, and bones providing structural support.

Other Options:

  • B is incorrect: Muscle contractions are coordinated, not random
  • C is incorrect: Muscles and nerves are actively working, not inactive
  • D is incorrect: Bones cannot move without muscle and nerve involvement

HMS, BM EQ-Bank 106 MC

During sustained swimming, what is the primary role of the circulatory system in supporting movement?

  1. Only removes lactic acid from muscles
  2. Only increases oxygen delivery to active muscles
  3. Delivers oxygen and removes waste products from active muscles
  4. Only maintains core body temperature
Show Answers Only

\(C\)

Show Worked Solution
  • C is correct: The circulatory system delivers oxygen to muscles while removing waste products during swimming.

Other Options:

  • A is incorrect: Ignores oxygen delivery role.
  • B is incorrect: Misses waste removal function.
  • D is incorrect: Omits critical gas exchange function.

HMS, BM EQ-Bank 105 MC

A tennis player executes a powerful serve. Which statement best describes the nervous system's role?

  1. Only processes visual information from the ball toss
  2. Coordinates sensory input, muscle activation and balance
  3. Only controls muscle contraction timing
  4. Only maintains postural stability during the movement
Show Answers Only

\(B\)

Show Worked Solution

B is correct: The nervous system integrates visual input, coordinates muscle contractions throughout the body, and maintains balance during the serve.

Other Options:

  • A is incorrect: Omits muscle control aspects
  • C is incorrect: Ignores sensory processing required
  • D is incorrect: Misses coordination requirements

HMS, BM EQ-Bank 104 MC

During a sprinting action, what is occurring in the quadriceps and hamstrings?

  1. Both muscles contract concentrically
  2. Both muscles contract eccentrically
  3. Quadriceps contracts concentrically while hamstrings relax
  4. Quadriceps contracts concentrically while hamstrings contract eccentrically
Show Answers Only

\(D\)

Show Worked Solution
  • D is correct: During sprinting, the quadriceps shortens to extend the knee while the hamstrings lengthens to control the movement.

Other Options:

  • A is incorrect: Both cannot shorten simultaneously
  • B is incorrect: Both cannot lengthen simultaneously
  • C is incorrect: Hamstrings must control leg movement

HMS, BM EQ-Bank 103 MC

During a netball game, a player performs a layup shot. Which body systems are working together to execute this movement?

  1. Skeletal and respiratory only
  2. Muscular and circulatory only
  3. Skeletal, muscular and nervous
  4. Respiratory and circulatory only
Show Answers Only

\(C\)

Show Worked Solution
  • C is correct: The skeletal (provides framework), muscular (produces force) and nervous systems (timing and precision) work together to execute coordinated movement.

Other Options:

  • A is incorrect: Misses muscular control needed
  • B is incorrect: Omits skeletal framework required
  • D is incorrect: Misses skeletal and muscular components