Certificate in Physiotherapy Chapter 1. Introduction to Physiology and Biochemistry
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Course lesson

Chapter 1. Introduction to Physiology and Biochemistry

Part 1 | Basics of Physiology

1 Learning Objectives

By the end of this section you will be able to …

  1. Define “physiology” and outline its interdisciplinary relationship with physiotherapy.
  2. Explain the concept of homeostasis and identify the key components of physiological control systems.
  3. Describe negative- and positive-feedback regulation, including at least three clinical examples relevant to rehabilitation.
  4. Recognise how ageing, disease and exercise modify homeostatic set-points, shaping assessment and treatment decisions in physiotherapy practice.

2 Definition & Scope of Physiology in Physiotherapy

AspectExplanationPhysiotherapy Touch-point
Physiology (classic definition)Scientific study of normal function in living organisms—from molecular to whole-body levelGuides safe exercise dosing, vital-sign monitoring, modality parameters
Scope for PTs• Cellular energetics (ATP, pH)
• Neuro-muscular transmission
• Cardiorespiratory dynamics
• Endocrine & metabolic adaptation
• Integumentary repair
Exercise prescription, electrotherapy, pulmonary rehab, wound care
Why PTs must master physiology1. Predict systemic response to intervention
2. Detect adverse events early
3. Translate pathology into functional goals
Example: Knowing β-blocker effect on HR
use RPE instead of HR training zones

Key Point: Anatomy tells us where and what; physiology tells us how and how much—crucial for evidence-based rehabilitation.


3 Homeostasis – The Core Concept

ComponentDefinitionExample in PT Context
VariablePhysiological parameter kept within limitsBlood glucose during therapeutic exercise
Sensor / ReceptorDetects change; sends afferent signalPancreatic β-cell senses ↑ glucose
Control (Integrating) CentreCompares with set-point; plans responseHypothalamus for temperature; spinal cord for stretch reflex
EffectorExecutes corrective actionSweat glands for cooling; quadriceps reflex to prevent knee buckling
Negative FeedbackOutput negates the original stimulus → stability↑ BP → baroreflex ↓ HR/BP (orthostatic training)
Positive FeedbackOutput amplifies stimulus → rapid change, self-limitingClot formation after injury; contraction cascade in labour
Dynamic Nature of Set-points
SituationVariable ShiftClinical Implication
FeverBody temp set-point ↑ 1-2 °CActive limb movement CI until temp normal
Endurance trainingResting HR set-point ↓ (bradycardia)Lower HR response—use HR reserve not absolute HR for intensity
AgeingBaroreflex sensitivity ↓Gradual positional changes to avoid dizziness in older adults

4 Physiological Regulation Pathways

  1. Neural (fast, point-to-point)
    Reflex latency ~ 50 ms → stretch reflex governs postural adjustments during balance training.
  2. Hormonal (slow-to-medium, broadcast)
    Adrenaline surge raises HR & BP during high-intensity interval—factor in rest intervals.
  3. Autocrine / Paracrine (local)
    Nitric-oxide release by endothelial cells causes local vasodilation → warm-up improves muscle perfusion.
  4. Intrinsic Rhythms (circadian)
    Cortisol peaks 06 – 09 h; schedule demanding therapy when alertness high for stroke patients.

5 Clinical Examples Linking Homeostasis to Physiotherapy

PT ScenarioMonitored VariableFeedback Loop at WorkIntervention Adjusted?
Early ambulation post-MIBP & HRBaroreflex; sympathetic driveKeep RPE ≤ 11; sit if SBP drops 20 mm Hg
Hydrotherapy for CP childCore temperatureThermoregulatory vasodilation & sweatingLimit session to 30 min at 34 °C water
Inspiratory muscle training in COPDPaCO₂ / pHChemoreceptor-driven ↑ ventilationTitrate load to 30 % PImax to avoid fatigue
Isometric quad set with ValsalvaIntrathoracic pressure / BPPositive feedback— ↑ BP may overshootCoach exhale on effort to break loop

6 Self-Check Quiz (answers below)

  1. Define homeostasis in one sentence.
  2. Which feedback type is involved in lactation?
  3. Name the primary sensor for arterial O₂ tension and its location.
  4. During prolonged standing a patient faints. Which homeostatic circuit failed to compensate?
  5. Why can beta-blockers mask early signs of hypoglycaemia in diabetic patients?

Answers

  1. Maintenance of a stable internal environment by coordinated physiological responses despite external change.
  2. Positive feedback via oxytocin release from posterior pituitary.
  3. Peripheral chemoreceptors in the carotid bodies at the bifurcation of the common carotid artery.
  4. Baroreceptor reflex (negative feedback regulating BP).
  5. They blunt sympathetic adrenergic symptoms (tachycardia, tremor) that normally alert the patient to low glucose.

7 • Suggested Learning Activities

ActivityPurpose
Set-point Shift Simulation (computer lab)Model HR, BP, temp changes during exercise & recovery
Homeostasis Role-PlayStudents act as sensor, integrator, effector to visualise feedback loops
Vitals Monitoring PracticumRecord HR/BP before & after postural change; identify compensatory patterns

8 Key Take-Home Points

  • Physiology underpins every clinical decision a physiotherapist makes—from safe mobilisation post-surgery to writing aerobic programmes.
  • Homeostasis is dynamic, not static; understanding shifting set-points is crucial for individualised care.
  • Feedback mechanisms can be therapeutically harnessed (training) or inadvertently disrupted (over-stretch, heat, Valsalva)—stay vigilant.

Part 2 | Introduction to Biochemistry

1 Learning Objectives

On completing this section you will be able to …

  1. Explain why biochemistry matters to physiotherapists and give three concrete clinical examples.
  2. Recall the core chemical principles—atomic structure, bonding, water chemistry, pH, buffers, energy coupling—that underpin human physiology.
  3. Describe the four major classes of biomolecules and relate each to tissue structure or metabolism important in rehabilitation.
  4. Interpret common biochemical data (e.g., blood glucose, creatine-kinase, lactate) and adjust treatment plans accordingly.

2 Why Biochemistry for Physiotherapists?

Physiological ProcessBiochemical BasisPT Relevance
Muscle contractionATP hydrolysis by myosin ATPase; Ca²⁺ binding to troponinGuides rest intervals in strength programmes; explains fatigue ↓ ATP
Bone remodellingCollagen cross-linking, hydroxy-apatite mineralisation (Ca²⁺, PO₄³⁻, vitamin D)Weight-bearing exercise ↑ osteoblast activity; nutrition advice on Ca²⁺, Vit D
Energy supply during exerciseGlycolysis, Krebs cycle, oxidative phosphorylationHIIT taps anaerobic glycolysis → ↑ lactate; aerobic endurance uses β-oxidation
Inflammation & healingCytokines, prostaglandins, collagen synthesis (vit C co-factor)Plan loading around inflammatory vs proliferative phases; advise vit C for tendon repair
Nerve conductionNa⁺/K⁺ ATPase gradients; neurotransmitter synthesis (ACh, GABA)Electrotherapy parameters & fatigue risk in neuropathies

Bottom line: Biochemistry translates cellular events into functional outcomes—the core of evidence-based rehabilitation.


3 Essential Chemical Principles

ConceptKey PointsClinical Link
Atoms & IonsH, C, N, O = 96 % body mass; Ca²⁺, Na⁺, K⁺, Cl⁻ crucial ionsNa⁺–K⁺ imbalance alters nerve excitability—watch electrolyte labs before NMES
Chemical BondsCovalent (strong) in proteins; Ionic in bone salts; H-bonds in DNA & waterWound collagen cross-link density affects tensile strength; glycosaminoglycan H-bonding retains water in cartilage
WaterHigh heat capacity & solvent of life; 60 % body weightHydration status influences thermoregulation during hydrotherapy
pH & BuffersBlood pH 7.35-7.45; bicarbonate buffer + respiratory compensationHigh-intensity exercise ↓ pH; cue active recovery and breathing control
Concentration / OsmosisOsmotic pressure drives capillary exchange; albumin maintains oncotic pressureEdema management—muscle pump & compression garments aid venous/lymph return
Energy TransferATP ⇄ ADP + Pi + 7.3 kcal; NAD⁺/FAD redox pairsCreatine supplementation ↑ phospho-creatine buffer → may aid high-load rehab

4 Macromolecules – Quick Reference

ClassMonomerPhysiological RoleRehab Touch-Point
CarbohydratesGlucose, glycogenRapid ATP; cell-surface recognitionCarb timing for glycogen re-synthesis post-exercise
LipidsFatty acids, triglycerides, phospholipidsEnergy store, membrane fluidityEssential fatty acids modulate inflammation (ω-3 intake)
Proteins20 amino acidsEnzymes, contractile filaments, carriersAdequate protein (1.2–1.6 g·kg⁻¹) for muscle hypertrophy
Nucleic AcidsNucleotidesGenetic code, ATPSatellite-cell activation in muscle repair depends on DNA transcription

5 Energy Systems Overview

SystemLocationDurationFuelKey EnzymesPT Application
ATP-PCr (alactic)Cytosol0-10 sPhospho-creatineCreatine kinase1-RM lifts, plyometrics
Anaerobic GlycolysisCytosol10-120 sMuscle glycogenPhosphofructokinaseHIIT; monitor lactate
Aerobic OxidativeMitochondria>2 minGlucose, fatty acidsCitrate synthase, ETC complexesEndurance walking programmes
β-oxidationMitochondrial matrix20 min → hoursFFA from adiposeAcyl-CoA dehydrogenaseLong, low-intensity cardio for obese clients

6 Clinical Chemistry Markers Every PT Should Know

MarkerNormal RangeWhat It IndicatesPT Action Point
Fasting glucose70-100 mg·dL⁻¹Energy supply; diabetes riskIf < 70 or > 250 mg·dL⁻¹ postpone vigorous exercise
Creatine-Kinase (CK)♂ 40-200 U/L
♀ 20-180 U/L
Muscle damage (rhabdomyolysis)After eccentric session CK may rise; monitor hydration, load progression
Lactate (rest)0.5-2.0 mmol·L⁻¹Anaerobic metabolismUse lactate threshold to set endurance intensity
pH (arterial)7.35-7.45Acid–base balanceCOPD exacerbation may show pH < 7.30; hold chest PT if unstable

7 Self-Check Quiz (answers below)

  1. Which property of water helps maintain stable core temperature during a 30-minute cycling session?
  2. Identify the buffer pair that regulates blood pH and state its Henderson–Hasselbalch equation.
  3. Why does a low-carbohydrate diet impair high-intensity exercise performance?
  4. Name the enzyme that converts pyruvate to lactate and explain why lactate is not a “waste” product.
  5. Give two biochemical reasons muscle protein synthesis is blunted in the elderly.

Answers

  1. Water’s high specific heat capacity absorbs excess heat with minimal temperature rise.
  2. Bicarbonate–carbonic acid buffer; pH = 6.1 + log ([HCO₃⁻]/0.03 × PaCO₂).
  3. Glycolysis depends on stored muscle glycogen; low carbohydrate means limited substrate → early fatigue.
  4. Lactate dehydrogenase (LDH); lactate shuttled to heart/slow muscle & liver (Cori cycle) for ATP or gluconeogenesis.
  5. ↓ Anabolic hormone (IGF-1) signalling and ↑ chronic inflammation (inflamm-aging) activate proteolysis pathways.

8 Key Take-Home Points

  • Biochemistry explains the “why” behind physiological responses—energy supply, tissue repair, acid–base balance.
  • Water, ions, pH and ATP are foundational themes; disturbances show up in vitals and lab values every PT should interpret.
  • Integrating biochemical insight with anatomy and physiology enables precise, safe rehabilitation programming.