A.B.J. (Johan) Groeneveld

Increased systemic microvascular albumin flux in septic shock

Lymph/plasma (L/P) albumin ratios were followed in a patient with a traumatic thoracic duct lymph fistula, during septic shock when lymph flow was high and at recovery when lymph flow was low. Higher albumin ratios were found during the former. On both occassions, the P-L difference of radioactive counts/min per gram was followed for 6 h after i.v. injection of 51Cr human serum albumin (HSA). Equilibration half times between plasma and lymph amounted to 0.85 h during septic shock and 2.49 h at recovery. The data indicate that systemic microvascular albumin flux had increased during shock in our patient. Increased permeability may have been responsible.

Literature of resuscitationAbdominal compressions increase vital organ perfusion during CPR in dogs: Relation with efficacy of thoracic compressions: Ann Emerg Med 1995; 25/3 (375–385)

STUDY OBJECTIVE Abdominal compressions can be interposed between the thoracic compressions of standard CPR (SCPR). The resulting interposed abdominal compression CPR (IAC-CPR) may increase blood pressures and patient survival, particularly if applied as a primary technique after in-hospital cardiac arrest. We used a predominant cardiac compression canine model to study the effects of IAC-CPR on blood pressures and total and vital organ perfusion as a function of time after cardiac arrest and efficacy of SCPR. DESIGN In a crossover design, we measured blood pressures and total and regional blood flow (radioactive microspheres) during 6-minute episodes of mechanical SCPR and IAC-CPR, both early (4 to 16 minutes) and late (18 to 30 minutes) after induction of ventricular fibrillation in eight dogs (weight, 25 to 33 kg) under neuroleptanalgesia/anesthesia. RESULTS During IAC-CPR, the ascending aortic-right atrial pressure gradient increased (P < .05), and retrograde pressure pulses contributed to the rise of ascending aortic pressure. Within 2 minutes after the start of IAC-CPR, end-tidal CO2 fraction increased by 0.6 +/- 0.4 vol% (P < .05), suggesting enhanced venous return. IAC-CPR enhanced (P < .05) total forward blood flow (574 +/- 406 versus 394 +/- 266 mL/minute during SCPR for the early phase) and vital organ perfusion (including myocardium), in both early and late phases. The IAC-CPR-induced augmentation of blood flow was greater if perfusion was relatively high during SCPR. CONCLUSION Compared with predominant cardiac compressions alone (SCPR), the addition of interposed abdominal compressions (IAC-CPR) improves total and vital organ oxygen delivery through enhanced venous return and perfusion pressures.

Abdominal compressions increase vital organ perfusion during CPR in dogs: Relation with efficacy of thoracic compressions: Ann Emerg Med 1995; 25/3 (375–385)

STUDY OBJECTIVE Abdominal compressions can be interposed between the thoracic compressions of standard CPR (SCPR). The resulting interposed abdominal compression CPR (IAC-CPR) may increase blood pressures and patient survival, particularly if applied as a primary technique after in-hospital cardiac arrest. We used a predominant cardiac compression canine model to study the effects of IAC-CPR on blood pressures and total and vital organ perfusion as a function of time after cardiac arrest and efficacy of SCPR. DESIGN In a crossover design, we measured blood pressures and total and regional blood flow (radioactive microspheres) during 6-minute episodes of mechanical SCPR and IAC-CPR, both early (4 to 16 minutes) and late (18 to 30 minutes) after induction of ventricular fibrillation in eight dogs (weight, 25 to 33 kg) under neuroleptanalgesia/anesthesia. RESULTS During IAC-CPR, the ascending aortic-right atrial pressure gradient increased (P < .05), and retrograde pressure pulses contributed to the rise of ascending aortic pressure. Within 2 minutes after the start of IAC-CPR, end-tidal CO2 fraction increased by 0.6 +/- 0.4 vol% (P < .05), suggesting enhanced venous return. IAC-CPR enhanced (P < .05) total forward blood flow (574 +/- 406 versus 394 +/- 266 mL/minute during SCPR for the early phase) and vital organ perfusion (including myocardium), in both early and late phases. The IAC-CPR-induced augmentation of blood flow was greater if perfusion was relatively high during SCPR. CONCLUSION Compared with predominant cardiac compressions alone (SCPR), the addition of interposed abdominal compressions (IAC-CPR) improves total and vital organ oxygen delivery through enhanced venous return and perfusion pressures.

Abdominal compressions increase vital organ perfusion during CPR in dogs: Relation with efficacy of thoracic compressions

STUDY OBJECTIVE Abdominal compressions can be interposed between the thoracic compressions of standard CPR (SCPR). The resulting interposed abdominal compression CPR (IAC-CPR) may increase blood pressures and patient survival, particularly if applied as a primary technique after in-hospital cardiac arrest. We used a predominant cardiac compression canine model to study the effects of IAC-CPR on blood pressures and total and vital organ perfusion as a function of time after cardiac arrest and efficacy of SCPR. DESIGN In a crossover design, we measured blood pressures and total and regional blood flow (radioactive microspheres) during 6-minute episodes of mechanical SCPR and IAC-CPR, both early (4 to 16 minutes) and late (18 to 30 minutes) after induction of ventricular fibrillation in eight dogs (weight, 25 to 33 kg) under neuroleptanalgesia/anesthesia. RESULTS During IAC-CPR, the ascending aortic-right atrial pressure gradient increased (P < .05), and retrograde pressure pulses contributed to the rise of ascending aortic pressure. Within 2 minutes after the start of IAC-CPR, end-tidal CO2 fraction increased by 0.6 +/- 0.4 vol% (P < .05), suggesting enhanced venous return. IAC-CPR enhanced (P < .05) total forward blood flow (574 +/- 406 versus 394 +/- 266 mL/minute during SCPR for the early phase) and vital organ perfusion (including myocardium), in both early and late phases. The IAC-CPR-induced augmentation of blood flow was greater if perfusion was relatively high during SCPR. CONCLUSION Compared with predominant cardiac compressions alone (SCPR), the addition of interposed abdominal compressions (IAC-CPR) improves total and vital organ oxygen delivery through enhanced venous return and perfusion pressures.

Changes in Systemic Microvascular Permeability in Sepsis and Septic Shock

Generalized soft tissue edema both in dependent and nondependent parts of the body is a remarkable feature of severe sepsis and septic shock. Usually, septic patients need substantial intravascular volume replacement, much greater than could be anticipated on the basis of measurable fluid losses [3]. Fluid balances are strongly positive in many cases to become negative when the patient recovers, a tendency which is often not observed in nonsurvivors [15]. Marked persistent peripheral edema may therefore be an ominous prognostic sign. Tissue edema may have a number of serious clinical sequelae like generalized organ dysfunction, interference with oxygen diffusion from the intravascular compartment to the cell (longer diffusion distances) and abnormalities in drug metabolism due to changes in the volume of distribution [3]. Several mechanisms can be involved in the formation of edema in septic patients. Microvascular fluid exchange is governed by the Starling forces [11, 13].