Transcript CHAPTER15A
CHAPTER 15 CARDIOVASCULAR SYSTEM www.sirinet.net Information 7,000L/day Beats 2.5 billion times/ lifetime Cardiovascular system HEART SIZE: 14cm X 9cm HEART LOCATION www.cayuga-cc.edu HEART LOCATION en.wikipedia.org PULMONARY CIRCUIT invest-trial.org SYSTEMIC CIRCUIT http://classes.midlandstech.com/carterp/Courses/bio211/chap18/Slide7.jpg PERICARDIUM en.wikipedia.org PERICARDIUM www.cayuga-cc.edu PERICARDIUM www.cayuga-cc.edu PERICARDIUM FIBROUS PERICARDIUM PARIETAL PERICARDIUM INNER LINING OF FIBROUS PERICARDIUM VISCERAL PERICARDIUM OUTER; TOUGH; DENSE CONNECTIVE TISSUE; FOR PROTECTION; COVERS THE HEART PARICARDIAL CAVITY FILLED WITH FLUID? PERICARDIUM www.cayuga-cc.edu HEART WALL EPICARDIUM THE VISCERAL PERICARDIUM PROTECTS HEART (REDUCES FRICTION) CONNECTIVE TISSUE COVERED BY EPITHELIAL TISSUE; CAPILLARIES AND NERVES; MAY HAVE FAT MYOCARDIUM MIDDLE LAYER CARDIAC MUSCLE; MUSLCE FIBERS SEPARATED BY CONNECTIVE TISSUE; HAS BLOOD VESSELS; LYMPH VESSELS AND NERVES ENDOCARDIUM CONNECTIVE TISSUE COVERED BY EPITHELIAL TISSUE; ; BLOOD VESSELS; PERKINJIE FIBERS; LINES HEART CHAMBERS AND STRUCTURES PERICARDIUM en.wikipedia.org HEART en.wikipedia.org MYOCARDIUM radiology.uchc.edu INTERNAL HEART CHAMBERS en.wikipedia.org PARTS ATRIA HAVE AURICLES ATRIOVENTRICULAR ORIFICE HAS A-V VALVE ATRIOVENTRICULAR SULCHUS INTERVENTRICULAR SULCHUS TRICUSPID VALVE RIGHT SIDE BICUSPID VALVE/MITRAL VALVE LEFT SIDE CHORDAE TENDONAE PAPILLARY MUSCLES SEMI LUNAR VALVES www.pbs.org SKELETON OF HEART DENSE CONECTIVE TISSUE RINGS FROM AORTA AND PULMONARY TRUNK THROUGH HEART DENSE CONNECTIVE TISSUE IN SEPTUM VALVE ATTACHMENTS; MUSCLE ATTACHMENTS; KEEP ORIFICES FROM EXPANDING BLOOD FLOW www.pbs.org BLOOD SUPPLY TO HEART CORONARY ARTERIES OFF AORTA BRANCHES TRAVEL ALONG ATRIOVENTRICULAR SULCHUS, POSTERIOR INTERVENTRICULAR SULCHUS AND ANTERIOR INTERVENTRICULAR SULCHUS MANY CAPLILLARIES TO MYOCARDIUM ANASTOMOSES BETWEEN SMALL ARTERIOLS PROVIDE ALTERNATE BLOOD FLOW ? HEART ACTIONS ATRIA CONTRACT = ATRIAL SYSTOLE AS VENTRICLES RELAX = VENTRICULAR DIASTOLE THEN: VENTRICLES CONTRACT = VENTRICULAR SYSTOLE AND ATRIA RELAX = ATRIAL DIASTOLE = CARDIAC CYCLE HEART SOUNDS LUBB= AV VALVES CLOSING DUBB= SEMILUNAR VALVES CLOSING HEART MURMUR CARDIAC MUSCLE www.siumed.edu CARDIAC MUSCLE FIBERS INTERCALATED DISC/3D/INTERWOVEN FUNCTIONAL SYNCYTIUM ATRIAL SYNCYTIUM VENTRICULAR SYNCYTIUM HEART CONTRACTION SPECIALIZED MYOFIBRILS FOR SENDING CARDIAC IMPULSES SA NODE: PACEMAKER BENEATH EPICARDIUM OF RT ATRIUM NEAR SUPERIOR VENA CAVA REACH THRESHOLD SPONTANEOUSLY AND BY SELF INCREASED PERMEABILITY TO SODIUM AND CALCIUM AND DECREASED PERMEABILITY TO POTASSIUM RHYTHMIC: 80 IMPULSES/MINUTE; PARASYMPATHETIC INHIBITS CONTRACTIONS TO ~70/MINUTE SA NODE /hyperphysics.phy-astr.gsu.edu INTERNODAL ATRIAL MUSCLE FIBERS CONDUCT IMPULSES TO DISTANT REGIONS OF ATRIA GAP JUNCTIONS ALLOW IMPULSE TO SPREAD THROUGH MYOCARDIUM BOTH ATRIA CONTRACT ATRIA AND VENTRICLES SEPARATED BY FIBROUS SKELETON OF HEART ONLY CONDUCTION TO VENTRICLES IS THROUGH JUNCTIONAL FIBERS JUNCTIONAL FIBERS TO AV NODE INFERIOR PART OF SEPTUM UNDER ENDOCARDIUM ONLY CONNECTION BETWEEN ATRIA AND VENTRICLES JUNCTIONAL FIBERS HAVE SMALL DIAMETERS: SPEED? IMPORTANCE? IMPULSE TO AV BUNDLE/BUNDLE OF HIS LARGE FIBERS BUNDLE ENTERS INTERVENTRICULAR SEPTUM; BRANCHES TO BOTH SIDES TO LARGE PURKINJE FIBERS BUNDLE OF HIS radiology.uchc.edu HEART ELECTRICAL PHENOMENA /hyperphysics.phy-astr.gsu.edu PERKINJIE FIBERS www.siumed.edu PURKINJE FIBERS CARRY IMPULSE THROUGH VENTRICLES FASTER THAN CELL TO CELL CONDUCTION: WHY NOT IN ATRIA? MUSCLES ARANGED IN WHORLS SO CONTRACT IN TWISTING MOTION FIBERS GO TO APEX FIRST SO APEX CONTRACTS FIRST MOVING BLOOD UP WHERE ARE THE PULMONARY ARTERY AND AORTIC OPENINGS? WHY? ELECTROCARDIOGRAM ELECTRICAL CHANGES IN MUSCLE P WAVE: SA NODE TRIGGERS IMPULSE FOR ATRIAL CONTRACTION QRS WAVES: DEPOLARIZATION OF VENTRICLES BEFORE CONTRACTION; THICKER SO MORE CHANGE T WAVE: VENTRICLE REPOLARIZATION INDICATES PROBLEMS WITH HEART PQ INTERVAL: SA NODE THROUGH AV NODE HEART CONTRACTION hyperphysics.phy-astr.gsu.edu REGULATION OF CARDIAC CYCLE CONTROLLED BY PARASYMPATHETIC AND SYMPATHETIC NS EFFECTS? PARASYMPATHETIC SEND VIA VAGUS NERVES CONTINUALLY WHICH RELEASE ACETYLCHOLINE TO SA AND AV NODE TO BRAKE HEART ACTION SYMPATHETIC SEND VIA VAGUS NERVES OCCAISIONALLY TO SA AND AV NODE RELEASE EPINEPHRINE TO INCREASE CONTRACTIONS CONTROL BY BOTH ORIGINATES IN MEDULLA OBLONGATA HAS CARDIOINHIBITOR AND CARDIOACCELERATOR REFLEX CENTERS RECEIVE INFO FROM CARDIOVASCULAR SYSTEM BLOOD PRESSURE EFFECT BARORECEPTORS OF AORTA AND CAROTID ARTERIES DETECT BLOOD PRESSURE CHANGES HIGHER PRESSURE STIMULATES IMPULSE TO CARDIOINHIBITOR REFLEX CENTER AND PARASYMPATHETIC NS DECREASES HEART RATE STRETCH RECEPTORS OF VENA CAVA DETECT HIGH PRESSURE SEND IMPULSE TO CARDIOACCELERATOR REFLEX CENTER AND SYMPATHETIC NS STIMULATES HEART OTHER CONTROLS CEREBRUM AND HYPOTHALAMUS CAN INCREASE OR DECREASE IT TEMPERATURE: HIGHER INCREASES IT LOWER DECREASES IT SURGERY? IONS MOST IMPORTANT: K+ Ca++ K: HIGH: DECREASES RATE & FORCE, MAY BLOCK CONDUCTION (CARDIAC ARREST) LOW: ARRHYTHMIA Ca: HOW DOES SA DIFFER FROM SKELETAL MUSCLE? SO WHERE DOES Ca COME FROM? HIGH: INCREASES CONTRACTION; TETANIC LOW: SLOWS HEART CONTRACTION BLOOD VESSELS TYPES: ARTERIES; ARTERIOLES; CAPPILLARIES; VENULES; VEINS DIRECTIONS? FUNCTION? ARTERIAL & VENOUS PATHWAYS www.accessexcellence.org ARTERY & VEIN ANATOMY www.accessexcellence.org ARTERY www.cayuga-cc.edu ENDOTHELIUM SMOOTH SURFACE ? ALSO RELEASE ? RELEASE CHEMICALS TO DILATE OR CONSTRICT BLOOD FLOW NITRIC OXIDE TUNICA MEDIA ELASTIC CONNECTIVE TISSUE ? TUNICA ADVENTIA/EXTERNA ATTACHES TO TISSUE VASO VASORUM ? REGULATION OF DIAMETER SYMPATHETIC NS VASOMOTOR FIBERS STIMULATE SMOOTH MUSCLE TO CONTRACT: VASOCONSTRICTION INHIBITED: VASODILATION BLOOD FLOW ARTERIES ARTERIOLES METARTERIOLES CAPILLARIES ARTERIOVENOUS SHUNTS ARTERIOLE www.siumed.edu CAPILLARIES STRUCTURE ? FUNCTION ? PERMEABILITY: SLITS WHERE CELLS OVERLAP/THROUGH CELLS SIZE VARIES ? http://www.youtube.com/watch?feature=player _detailpage&v=Q530H1WxtOw CAPILLARY BED www.accessexcellence.org www.cayuga-cc.edu CAPILLARY TYPES CONTINUOUS: UNINTERRUPTED HAVE INTERCELLULAR CLEFTS BETWEEN TIGHT JUNCTIONS FENESTRATED SMALL PORES IN ENDOTHELIUM SINUSOIDAL: LARGER PORES DISCONTINUOUS SINUSOIDAL: SINUSOID, NO TIGHT JUNCTIONS CONTINUOUS CAPILLARY www.cayuga-cc.edu FENESTRATED CAPILLARY www.cayuga-cc.edu SINUSOID CAPILLARY www.cayuga-cc.edu DISCONTINUOUS SINUSOIDAL CAPILLARIES www.bu.edu/histology BLOOD BRAIN BARRIER HOW? WHY? BLOOD BRAIN BARRIER users.ahsc.arizona.edu BLOOD BRAIN BARRIER www.angiochem.com web.sfn.org/content PRECAPILLARY SPHINCTER www.lib.mcg.edu CAPILLARY EXCHANGE DIFFUSION; LIPID SOLUBLE/INSOLUBLE FILTRATION HYDROSTATIC PRESSURE DUE TO CONTRACTION OF VENTRICLES CLOSER TO ARTERIOLE END OF BED: FILTRATION OSMOTIC PRESSURE: DUE TO IMPERMEANT SOLUTE ONE SID EOF CELL MEMBRANE: PLASMA PROTIENS: PLASMA COLLOID OSMOTIC PRESSURE: REABSORPTION; CLOSER TO VENOUS END USUALLY MORE FLUID LEAVES THAN RETURNS (NEXT CHAPTER) WHEN WOULD MORE EXIT ? CAPILLARY TRANSPORT users.ahsc.arizona.edu CPPILARY TRANSPORT Figure 3 Transport mechanisms at the BBB. 1 = paracellular diffusion (sucrose), 2 = transcellular diffusion (ethanol), 3 = ion channel (K+ gated), 4 = ion-symport channel (Na+/K+/Clcotransporter), 5 = ion-antiport channel (Na+/H+ exchange), 6 = facilitated diffusion (Glucose via GLUT-1), 7 = active efflux pump (P-glycoprotein), 8 = active-antiport transport (Na+/K+ ATPase), 9 = receptor mediated endocytosis (transferrin & insulin) VEIN www.cayuga-cc.edu ARTERY vs. VEIN www.siumed.edu ARTERY vs. VEIN www.siumed.edu VEINS VALVES ? BLOOD RESERVOIRS: (25%) ARTERIAL BLOOD PRESSURE SYSTOLIC PRESSURE: DIASTOLIC PRESSURE VENTRICLES CONTRACT ATRIA CONTRACT ARTERIAL WALLS RECOIL AFTER BLOOD ENTERS: PULSE FACTORS AFFECTING BLOOD PRESSURE STROKE VOLUME 70 ml CARDIAC OUTPUT= STROKE VOLUME X HEART RATE IF STROKE VOLUME OR HEART RATE INCREASE BLOOD VOLUME: ~5L; 8% BODY WT PERIPHERAL RESISTANCE: BLOOD VS. WALLS: ARTERIAL RECOIL LESSENS PRESSURE/PULSE VICOSITY: RESISTENCE TO FLOW OF BLOOD MOLECULES INCREASED VISCOSITY ? CONTROL OF BLOOD PRESSURE DETERMINED BY CARDIAC OUTPUT x PERIPHERAL RESISTANCE LIMITED BY HOW MUCH RETURNS TO THE VENTRICLES USUALLY ONLY 60% IS PUMPED OUT OF VENTRICLE SO SYMPATHETIC STIMULATION CAN INCREASE MYOCARDIAL FIBERS STRETCH WHEN BLOOD ENTERS VENTRICLES MORE THEY STRETCH, HARDER THEY CONTRACT: FRANK-STARLING LAW OF THE HEART PRELOAD: BLOOD ENTERING VENTRICLES AND STRETCHING FIBERS AFTERLOAD: FORCE NEEDED TO OPEN SEMILUNAR VALVES FOR EJECTION HYPERTENSION INCREASES AFTERLOAD CARDIOINHIBITOR AND CARDIOACCELERATOR THINGS THAT INCREASE HEART RATE: EPINEPHRINE;EMOTIONS: FEAR, ANGER; EXERCISE; BODY TEMPERATURE RISE ARTERIOLE CONSTRICTION VASOMOTOR CENTER OF MEDULLA: CONTROLS VASODILATION OR CONSTRICTION BY SYMPATHETIC SYSTEM BARORECEPTORS OF AORTA SEND TO VASOMOTOR CENTER; ALSO PICKS UP PRESSURE LOSS: RELEASES EPINEPHRINE IMPORTANT CONTROL OF ARTERIOLES TO ABDOMINAL VISCERA: COULD CONTAIN MOST OF THE BLOOD OF BODY CHEMICALS OF CONTROL INCREASING CO2; DECREASING O2; LOWERING pH; RELAXES SMOOTH MUSCLE INCREASED BLOOD FLOW VASODILATORS: NITRIC OXIDE FROM ENDOTHELIAL CELLS AND BRANDYKININ FROM BLOOD VASOCONSTRICTION: ANGIOTENSIN AND ENDOTHELIN FROM ENDOTHELIUM VENOUS BLOOD FLOW BLOOD PRESSURE IS LOWER BLOOD FLOW: BLOOD PRESSURE; SKELETAL MUSCLE CONSTRICTION; RESPIRATORY MOVEMENTS; VASOCONSTRICTION VASOCONSTRICTION: LOW PRESSURE SYMPATHETIC REFLEXES STIMULATE SMOOTH MUSCLE CONTRACTION CENTRAL VENOUS PRESSURE PRESSURE IN RIGHT ATRIUM ? HIGH: INCREASES AND MORE PRESSURE IN VEINS HIGH BLOOD VOLUME OR VASOCONTRICTION INCREASES CVP HIGH CVP= EDEMA PULMONARY CIRCUIT RIGHT VENTRICLE CONTRACTS WITH LESS POWER SO LESS ARTERIAL PRESSURE HELPS WITH DIFFUSION OF O2 AND CO2 LIFE SPAN CHANGES PLAQUE (FAT) BUILD UP ON ATERIES ? CARDIAC OUTPUT STAYS THE SAME FOR MOST INCREASES WITH AGE DECREASES WITH THOSE HEART DISEASE CARDIAC MUSCLE DECLINES, DON’T DIVIDE: REPLACED BY FIBROUS CONNECTIVE TISSUE AND ADIPOSE TISSUE LEFT VENTRICLE 25% THICKER AT 80 SLOWS A LITTLE 8 ML LESS/YEAR VALVES THICKEN, BECOME MORE RIGID, MAY CALCIFY SA AND AV NODE AND BUNDLE OF HIS BECOME MORE ELASTIC SYSTOLIC BLOOD PRESSURE INCREASES: DECREASING SIZE AND ELASTICITY OF ARTERIES ARTERIES: TUNICA INTERNA THICKENS; MORE MUSCLE, MORE COLLAGEN, CALCIUM AND FAT: MORE RIGID ARTERIOLES HALF THEIR ELASTICITY AT 70; DON’T RESPOND WELL TO CHANGES IN TEMPERATURE VEINS: MORE CAOLLAGEN, MAY CALCIFY BUT NOT AS MUCH, USUALLY NOT AFFECTED OR OTHER VEINS TAKE OVER ENDOTHELIUM: LESS SMOOTH LESS CAPILLARIES EXERCISE HELPS SLOW MANY OF THESE CHANGES