Alterations In Homeostasis Shock. Homeostasis What is homeostasis????? Homeostasis is an (ideal or...

Alterations In Homeostasis

Shock

Homeostasis

• What is homeostasis?????• Homeostasis is an (ideal or virtual) state of equilibrium, in which

all body systems are working and interacting in an appropriate way to fulfill all the needs of the person and/or the body. When homeostasis is interrupted (e.g. by response to a stressor), the body tries to restore it by adjusting one or more physiological processes. This stress-adaption mechanism includes activation of the Hypothalamic-Pitauitary-Andrenal Axis (HPA Axis) with the autonomous nervous system and endocrine reactions of the body.

• Severe stressors or long lasting adjustment demands can cause severe imbalance of this steady state. This might cause not only psychological distress but also psycho-somatic disorders.

Shock• Can occur when any part of the cardiovascular

system does not function properly for any reason• Begins with abnormal cellular metabolism that

occurs when too little oxygen is delivered to tissues

• Shock is a condition in which a systemic decrease in perfusion to tissue and organs leads to poor gas and nutrient exchange. Delays in recognition and treatment can lead to irreversible shock, multisystem organ failure, and death.

• Types of shock and their causes vary because shock is a manifestation of a pathologic condition rather than a disease state. More then one type of shock can be present at one timie

Process of Shock

• Initial stage (early shock)

• Nonprogressive stage (compensatory stage)

• Progressive stage (intermediate stage)

• Refractory stage (irreversible stage)

Initial stage (early shock) Reversible

• Pathophysiology

Nonprogressive Stage (Compensatory)• Pathophysiology

Progressive Stage (Intermediate Stage)

• Pathophysiology

Refractory stage (Irreversible Stage)• Pathophysiology

Multiple Organ Dysfunction Syndrome• Pathophysiology

Effects of Shock on Body Systems• Cardiovascular System

Effects of Shock on Body Systems• Respiratory System

Effects of Shock on Body Systems• GI System/Renal

Effects of Shock on Body Systems• Neurologic System

Effects of Shock on Body Systems• Skin, Temperature, and Thirst

CollaborationCollaboration

Diagnostic testDiagnostic test

Pharmacologic Pharmacologic TherapiesTherapies

Oxygen Therapy

Endotrachial Tube

Vented Patient

Inline Sterile Suction

Ventilator

Nutrition/Fluid Therapy

Pain and Comfort

Clinical TherapiesClinical Therapies

Central Venous Catheter

CVP

Normal CVP: 0-6mm HgIncreased CVP: • Aggressive fluid resuscitation• right-sided heart failure with venoconstriction • renal failure• tricuspid or pulmonic valvular disorders • right ventricular infarction • COPD • pulmonary embolis • pulmonary hypertension.

What does the patient look like? dyspnea, crackles,distended neck veins

CVP

Decreased CVP• Hypovolemia-relative or actual• Hemmorhage• Vasodilitation• Diuretics• Fliud shifts-sepsis

What does the patient look like? TachycardiaCVP will fall before the patient becomes

hypotensive.

Complication of CVP Catheters

• Infection

• Thrombosis

• Hemorrhage

• Arrhythmia

• Pneumothorax

• Cardiac Tamponade

Pulmonary Artery Catheter

• Used to continuously monitor right atrium (RA) and pulmonary artery (PA) pressures.

• Swan-Ganz Catheter

• Insertion sites: subclavian, internal or external jugular, femoral, brachial.

PA Catheter

PA Catheter in the RA

PA Catheter in the RV

PA Catheter in the PA

PA Catheter in a Pulmonary Arteriole

Left Heart Preload/PCWP

PAOP=PCWP=LVEDP=left heart preload

Measures filling pressures in the left heart

Normal: 5-12mmHg

PAD=PCWP in the absence of pulmonary hypertension

PCWP

PCWP normally correlates with volume

Low PCWP indicates hypovolemia (Volume expanders, packed RBC)

High PCWP indicates hypervolemia (diuretics, venodilators)

Cardiac Output/Cardiac Index

Normals: CO: 4-8L/min; CI:2.5-4.0L/min/m2

What can cause Low CO/CI:• HR: Fast or slow• Preload: decreased from diuresis, dehydration, fluid

shifts, hypovolemia, vasodilitation• Afterload: Increased from vasoconstriction secondary

to HTN, compensatory vasoconstriction• Contractility: Decreased from MI, HF, cardiomyopathy,

cardiogenic shock, cardiac tamponade

Cardiac Output/Cardiac Index

High CO/CI:

• Anxiety

• Compensatory response in pulmonary edema

• Increased metabolic states (fever, hyperthyroid)

• sepsis

Right Heart Afterload

• Right heart afterload=pulmonary vascular resistance (PVR)

• Normal: 50-250 dynes/sec/cm2

• Increased in acute lung injury

Left Heart Afterload

• Left heart afterload=systemic vascular resistance (SVR)

• Normal: 800-1200 dynes/sec/cm2

Increased Afterload (SVR)

• Use of vasopressors

• Aortic stanosis

• hypothermia

• hypertension

Increased Afterload (SVR)

• Treatment– Vasodilators (nipride, NTG)

– Ace Inhibitors (captopril, enalapril)

– Calcium channel blockers (verapamil nifedipine)

Decreased Afterload (SVR)

• Sepsis/septic shock

• Anaphylactic Shock

• Neurogenic Shock

• Treatment– Levophed– Neosynephrine– Dopamine– Vasopressin

Arterial line

Indication for an A-line

• Critically ill patients with intra-aortic balloon pumps

• Monitor the effects of potent vasodilators and vasopressors

• Frequent ABG testing

• Morbid obesity

• Burn patients

Nursing ProcessNursing Process• Assessment

– Health History– Physical Examination

• Nursing Diagnosis

• Plan

• Implantation

• Evaluation