Sauerstoffbindungskurve
Oxygen saturation curve
Oxygen affinity curve
Bohr Effekt
The decrease in the oxygen affinity of haemoglobin in the presence of low pH or high CO2
Haldane Effekt
"The Haldane effect is a physicochemical phenomenon which describes the increased capacity of blood to carry CO2 under conditions of decreased haemoglobin saturation"
Baroreceptor Reflex
Sensors: pressure (carotid sinus and aortic arch)
Afferent: vagus and glossopharyngeal nerves
Processor: nucleus of the solitary tract and nucleus ambiguus
Efferent: vagus nerve and sympathetic chain
Effect: increased HR and BP in response to a fall in BP
Bainbridge Reflex
Afferent: vagus (atrial stretch)
Processor: nucleus of the solitary tract and the caudal ventral medulla
Effect: increased RA pressure produces an increased heart rate;
Chemoreceptor Reflex
Afferent: carotid / aortic chemoreceptors (low PaO2 and/or high PaCO2)
Effect: bradycardia and hypertension in response to hypoxia (also secondary tachycardia from Bainbridge and Hering-Breuer reflexes)
Cushing Reflex
Afferent: mechanosensors in the rostral medulla?
Processor: rostral ventrolateral medulla
Efferent: sympathetic fibres to the heart and peripheral smooth muscle
Effect: hypertension and baroreflex-mediated bradycardia
Bezold-Jarisch-Reflex
Afferent: vagus (mechanical/chemical sttimuli to the cardiac chambers)
Processor: nucleus of the solitary tract
Effect: hypotension and bradycardia in response to atrial stimulation
Oculocardiac reflex
Afferent: trigeminal nerve (pressure to the globe of the eye)
Processor: sensory nucleus of CN V; nucleus of the solitary tract
Effect: vagal bradycardia, systemic vasoconstriction, cerebral vasodilation
Diving reflex
Afferent: trigeminal nerve (cold temperature; pressure of immersion)
Vasovagal Reflex
Barcroft-Edholm reflex
Afferent: emotional distress, hypovolaemia
Processor: unknown
Effect: bradycardia, systemic vasodilation, hypotension
Respiratory Sinus arrythmia
Afferent: central respiratory pacemaker
Processor: nucleus ambiguus
Efferent: vagus nerve, via the cardiac ganglion
Effect: cyclical increase of heart rate during inspiration
Balance of bainbridge and baroreceptor reflex
increased intracranial pressure, and consists of the following triad:
Hypertension
Bradycardia
Irregular respiration
Periphere Chemorezeptoren
periphere Chemorezeptoren: Es handelt sich um Glomuszellen, die als Gefäßknäuel über Seitenäste von benachbarten großen Arterien versorgt werden. Sie gehören im Verhältnis zu ihrer Masse zu den am besten durchbluteten Organen (ca. 20ml/min*g; vgl. Gehirn ca. 0,8 ml/min*g). Man unterscheidet Typ-I und Typ-II Glomuszellen. Sie befinden sich bilateral an der Teilungsstelle (Bifurkation) der Arteria carotis communisim Glomus caroticum und in der Aorta im Glomus aorticum - von dort ziehen sie bis in die Arteria subclavia dextra.
Sie registrieren den arteriellen Sauerstoffpartialdruck(paO2) und können so eine Hypoxie erfassen. Die Informationen werden als Impulse über den Nervus vagus und den Nervus glossopharyngeus an das Atemzentrumweitergegeben.
Azidose/erhöhtes CO2/H +Ionen/Hypoperfusion/Hyperthermie/ CO steigern Ventilation
Central chemorezeptors
zentrale Chemorezeptoren: Sie liegen im Atemzentrum der Medulla oblongata des ZNS und messen den Kohlendioxidpartialdruck (paCO2), registrieren jedoch keine Hypoxie. Zudem werden sie durch einen Abfall des pH-Wertes im Liquor stimuliert.[1] h+Ionen
Ventrolaterale Medulla
Innerhalb der Bluthirn Schranke
Respiratory resistance
Respiratory system resistance is mainly a combination of resistance to gas flow in the airways and resistance to deformation of tissues of both the lung and chest wall.
It is usually expressed as a change in pressure per unit flow, usually in cmH2O per litre per second.
Its reciprocal is conductance. Normally, specific airway conductance is used, which is conductance expressed per unit of lung volume.
The total resistance of the respiratory system is composed of several contributing factors:
Resistance from deformation of the tissues (important at all flow rates)
Tissue resistance from lung parenchyma (~70%)
Tissue resistance from chest wall (~30% )
Inertance of air and thoracic tissues (important at high respiratory rates)
Compression of intrathoracic gas (important mainly with high respiratory pressures)
Resistance from air flow friction, which in turn depends on
Reynolds number, which depends on
Airway diameter (increases with lung volume)
Airway length (increases with lung volume)
Flow rate
Gas density
Gas viscosity
Proportion of turbulent flow (at high flow, upper airways)
Proportion of laminar flow (low flow rates and in the lower airways)
In normal airways, the flow is mainly laminar (turbulent flow is localised to the upper airways)
Resistance to laminar flow increases in proportion to flow rate and is described by the Hagen-Poiseuilee equation, being affected by the following factors:
Airway length
The fourth power of airway diameter
Resistance to turbulent flow increases exponentially with flow rate, and the main determinant of the rate of pressure change is the density of the gas.
Airways resistance
Factors which affect airway resistance
Gas properties which affect the type of flow
Gas density (increased density leads to increased turbulence and hence increased resistance)
Gas viscosity (increased viscosity promotes laminar flow and hence decreases resistance)
Factors which affect airway diameter
Lung volume (resistance decreases with higher volume)
Physiological variation in airway diameter
Pathological conditions which affect airway diameter:
Mechanical obstruction or compression
Extrinsic, eg. by tumour
Dynamic compression, eg. due to gas trapping or forceful expiratory effort
Artificial airways and their complications, eg. endotracheal tube becoming kinked
Decreased internal crossection
Oedema
Mucosal or smooth muscle hypertrophy
Encrusted secretions
Decreased smooth muscle tone
Bronchodilators
Sympathetic nervous system agonists
Increased smooth muscle tone
Bronchospasm
Irritants, eg. histamine
Parasympathetic nervous system agonists
Factors which affect airway length
Lung volume (increasing volume stretches and elongates the bronchi)
Artificial airways (increase the length in the case of an ETT, or decrease it in the case of a tracheostomy)
Factors which affect flow rate
Respiratory rate (increased respiratory rate produces an increase in the flow rate for each breath)
Inspiratory and expiratory work (eg. voluntary forced expiration for spirometry)
Inspiratory flow pattern generated by a mechanical ventilator
Other factors which affect respiratory resistance as a whole:
Factors which influence pulmonary vascular resistance
Pulmonary blood flow:
Increased blood flow results in decreases pulmonary vascular resistance in order for pulmonary arterial pressure to remain stable
This is due to:
Distension of pulmonary capillaries (mainly), and
Recruitment of previously collapsed or narrowed capillaries
Lung volume:
Relationship between lung volume and PVR is "U"-shaped
Pulmonary vascular resistance is lowest at FRC
At low lung volumes, it increases due to the compression of
larger vessels
At high lung volumes, it increases due to the compression of small vessels
Hypoxic pulmonary vasoconstriction
A biphasic process (rapid immediate vasoconstriction over minutes, then a gradual increase in resistance over hours)
Mainly due to the constriction of small distal pulmonary arteries
HPV is attenuated by:
Sepsis and pneumonia
hypothermia
iron infusion
Metabolic and endocrine factors:
Catecholamines, arachidonic acid metabolites (eg. thromboxane A2) and histamine increase PVR
Hypercapnia and (independently) acidaemia also increase pVR
Alkalaemia decreases PVR and suppresses hypoxic pulmonary vasoconstriction
Hypothermia increases PVR and suppresses hypoxic pulmonary vasoconstriction
Autonomic nervous system:
α1 receptors: vasoconstriction
β2 receptors: vasodilation
Muscarinic M3 receptors: vasodilation
Blood viscosity
PVR increases with increasing haematocrit
Drug effects:
Pulmonary vasoconstrictors: Adrenaline, noradrenaline and adenosine
Pulmonary vasodilators: Nitric oxide, milrinone, levosimendan, sildenafil, vasopressin, bosantan / ambrisantan, prostacycline and its analogs, calcium channel blockers and ACE-inhibitors.
Prostaglandine
cAMP
Vasoactive intestinal peptide
cAMP Vasodilatator in der Lunge
NO
cGMP vasodilatativ durch Calcium
Global Ventilation and perfusion
Global ventilation of the lungs is expressed as the minute volume , normally around 4L/min
This is affected by multiple factors, most notably pregnancy, PaCO2, PaO2, pH, body temperature, exercise and blood pressure
Global perfusion of the lungs is directly proportional to the cardiac output (normally 5L/min)
Therefore, this is affected by all the factors which affect cardiac output, which include exercise, metabolic rate, volume-sensing reflexes, autonomic tone, etc.
The global perfusion of the lungs is approximately 5L/min at rest
Global V/Q mismatch occurs when:
there is signficantly reduced ventilation with intact perfusion (shunt)
there is reduced perfusion (increased physiological dead space)
Regional differences in perfusion and ventilation develop because:
The global perfusion of the lungs occurs at a low pressure, which means that the hydrostatic pressure of the column of blood blood therefore has a significant influence.
Lung ventilation occurs predominantly because of the changes in the shape of the thoracic cavity which occur unevenly (i.e. the base expands more than the apex)
Regional changes in pulmonary arterial resistance (eg. due to atelectasis and hypoxic vasoconstriction) change the distribution of blood flow in response to the distribution of ventilation
Regional differences in perfusion and ventilation are affected by:
Posture and gravity (which affects the pressure in the hydrostatic column)
Factors which affect regional pulmonary blood flow:
Lung volume (atelectasis increases pulmonary vascular resistance)
Gravity (affects the direction of the hydrostatic gradient)
Pulmonary vascular architecture (some lung units are structurally advantaged)
Factors which affect regional ventilation:
Gravity (the weight of the lung) which produces a vertical gradient in pleural pressure
Posture, which changes the direction of this vertical gradient
Anatomical expansion ptential (i.e. bases have more room to expand than apices)
Lung compliance (more compliant lung regions, eg. lung bases, will be better ventilated at any given traspulmonary pressure
Pattern of breathing
Verhältnis Blood Flow/ Perfusion
West Zones
The lung can be divided into discrete regions according to the interplay between alveolar pressure, arterial pressure and venous pressure.
These regions are:
Zone 1, where alveolar pressure is higher than arterial or venous pressure;
Zone 2, where the alveolar pressure is lower than the arterial but higher than the venous pressure
Zone 3, where both arterial and venous pressure is higher than alveolar
Zone 4, where the interstitial pressure is higher than alveolar and pulmonary venous pressure (but not pulmonary arterial pressure)
Under normal circumstances, Zone 1 (a poorly perfused region containing a lot of dead space) does not exist, and only manifests in certain scenarios:
Positive pressure ventilation
Hypovolaemia, eg. haemorrhage
Non respiratory functions of the lung
Trap for airborne particles: generally, nothing larger than 2.5μm gets to the alveoli
Reservoir of blood: the lungs contain about 10% of the circulating blood volume
Route of drug administration (eg. nebulised steroids and bronchodilators)
Route of drug elimination (eg. volatile anaesthetics)
Metabolism (eg. conversion of of angiotensin-I, and degradation of neutrophil elastase by α1-antitrypsin)
Modulator of acid-base balance by virtue of CO2 elimination
Modulator of the clotting cascade: the lungs contain thromboplastin, heparin and tissue plasminogen activator
Filter for the bloodstream: particles larger than an RBC are trapped (~8 μm size barrier), which includes clots, tumour cells and other emboli
Antimicrobial and immune functions: Alveolar macrophages and sequestered neutrophils, mast cells in the lung and bronchi, immunoglobulin in the respiratory mucus (IgA)
Modulation of body temperature: heat loss can occur by respiration
Organ of speech: the lungs form a part of the system which permits communication by sound and language
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