The effect of tonicity and hypertonic solutions on microvascular permeability

Mechanobiological Adaptation to Hyperosmolarity Enhances Barrier Function in Human Vascular Microphysiological System

In infectious disease such as sepsis and COVID-19, blood vessel leakage treatment is critical to prevent fatal progression into multi-organ failure and ultimately death, but the existing effective therapeutic modalities that improve vascular barrier function are limited. Here, this study reports that osmolarity modulation can significantly improve vascular barrier function, even in an inflammatory condition. 3D human vascular microphysiological systems and automated permeability quantification processes for high-throughput analysis of vascular barrier function are utilized. Vascular barrier function is enhanced by >7-folds with 24-48 h hyperosmotic exposure (time window of emergency care; >500 mOsm L^-1 ) but is disrupted after hypo-osmotic exposure (<200 mOsm L^-1 ). By integrating genetic and protein level analysis, it is shown that hyperosmolarity upregulates vascular endothelial-cadherin, cortical F-actin, and cell-cell junction tension, indicating that hyperosmotic adaptation mechanically stabilizes the vascular barrier. Importantly, improved vascular barrier function following hyperosmotic exposure is maintained even after chronic exposure to proinflammatory cytokines and iso-osmotic recovery via Yes-associated protein signaling pathways. This study suggests that osmolarity modulation may be a unique therapeutic strategy to proactively prevent infectious disease progression into severe stages via vascular barrier function protection.

Transport and Lymphatic Uptake of Biotherapeutics Through Subcutaneous Injection

Drug transport and uptake in the subcutaneous tissue receives increasing attention in biomechanical and pharmaceutical researches, as subcutaneous administration becomes a common approach for the delivery of biotherapeutics, such as monoclonal antibodies. In this paper, high-fidelity numerical simulations are used to investigate the mechanisms governing drug transport and absorption in the subcutaneous tissue, which is expressed as a porous medium modeled by Darcy's law. The effects of tissue properties (permeability and porosity), the injection flow rate, and the vascular permeability of lymphatic vessels on the lymphatic uptake are studied. Additionally, an empirical formula for the lymphatic uptake during the injection is developed based on the numerical results. The roles of lymphatic drainage, blood perfusion, osmotic pressure, and the drug binding to the cells and the extracellular matrix in the lymphatic uptake are systematically studied. Furthermore, the drug distribution and absorption in a multi-layered porous medium are investigated to illustrate the effect of heterogeneity of permeability, as the permeability varies over a wide range in different layers of the tissue (such as dermis, subcutaneous tissue, muscle). While the interstitial pressure plays an essential role in the mechanisms regulating the absorption of free monoclonal antibodies, the binding and metabolism of drug proteins also affect the drug absorption by reducing the total free monoclonal antibodies.

The role of hypertonic saline dextran in trauma resuscitation

Modern trauma management has recognized the importance of using conservative fluid resuscitation regimes in order to prevent complications from fluid overload arising. Hypertonic/hyperoncotic fluids appear to provide an ideal means of facilitating this, requiring only small volumes to rapidly elevate blood pressure. Hypertonic saline dextran (HSD) was introduced in 1985 but its take up has been slow, a large part of this has been due to the lack of human trials and concerns about complications.

The current evidence has been reviewed and it is clear that HSD is an efficient means of correcting hypotension, doing so mainly by the mobilizing endogenous water. It is becoming apparent that early administration has the potential to modulate the inflammatory cascade in patients at risk of developing adult respiratory distress syndrome (ARDS) and multiorgan failure. This is reflected in the handful of human trials that show a trend towards increased survival (particularly for head injuries) and a possible reduction in ARDS. The side effect profile appears to be good, even in the presence of dehydration or penetrating trauma.

Published human trials have methodological problems and lack of power of study this has led to a reliance on animal studies. Clearly there is great potential, but before large-scale prehospital usage can be justified further well-conducted randomized human trials are needed.

Chylomicrons combined with endotoxin moderate microvascular permeability

Triglyceride-rich lipoprotein-bound endotoxin (CM-LPS) inhibits the host innate immune response to sepsis by attenuating the hepatocellular response to pro-inflammatory cytokine stimulation. This 'cytokine tolerance' in hepatocytes is a transient, receptor-dependent process that correlates with internalization of CM-LPS via low density lipoprotein (LDL) receptors. Since endothelial cells are integral to the immune response and similarly express LDL receptors, we hypothesized that CM-LPS could be internalized and ultimately attenuate the deleterious effects of pro-inflammatory molecules like tumor necrosis factor-α (TNF-α) and platelet activating factor (PAF) on endothelial permeability. Here, we show that CM-LPS complexes induce cytokine tolerance in endothelial cells. In rats, TNF-α increased hydraulic conductivity 2.5-fold over baseline and PAF increased it 5-fold; but, pretreatment with CM-LPS or an attenuated analog (CM-LPS*) inhibited these changes. Nuclear/cytoplasmic levels of p65 were reduced after TNF-α-stimulation in endothelial cell monolayers pretreated with CM-LPS, a finding consistent with inhibition of nuclear factor (NF)-κB translocation. Also consistent with inhibition was stabilized intercellular adhesion, as illustrated with antibody to VE-cadherin using confocal microscopy. These results provide additional support for the integral role of lipoproteins in the innate immune response to infection and lend further credence to developing lipid-based therapy for Gram-negative sepsis.

Glucagon-like peptide-1 protects mesenteric endothelium from injury during inflammation

Glucagon-like peptide-1 (GLP-1) is a proglucagon-derived hormone with cellular protective actions. We hypothesized that GLP-1 would protect the endothelium from injury during inflammation. Our aims were to determine the: (1) effect of GLP-1 on basal microvascular permeability, (2) effect of GLP-1 on increased microvascular permeability induced by lipopolysaccaride (LPS), (3) involvement of the GLP-1 receptor in GLP-1 activity, and (4) involvement of the cAMP/PKA pathway in GLP-1 activity. Microvascular permeability (L(p)) of rat mesenteric post-capillary venules was measured in vivo. First, the effect of GLP-1 on basal L(p) was measured. Second, after systemic LPS injection, L(p) was measured after subsequent perfusion with GLP-1. Thirdly, L(p) was measured after LPS injection and perfusion with GLP-1+GLP-1 receptor antagonist. Lastly, L(p) was measured after LPS injection and perfusion with GLP-1+inhibitors of the cAMP/PKA pathway. Results are presented as mean area under the curve (AUC)+/-SEM. GLP-1 had no effect on L(p) (AUC: baseline=27+/-1.4, GLP-1=1+/-0.4, p=0.08). LPS increased L(p) two-fold (AUC: LPS=54+/-1.7, p<0.0001). GLP-1 reduced the LPS increase in L(p) by 75% (AUC: LPS+GLP-1=34+/-1.5, p<0.0001). GLP-1 antagonism reduced the effects of GLP-1 by 60% (AUC: LPS+GLP-1+antagonist=46+/-2.0, p<0.001). The cAMP synthesis inhibitor reduced the effects of GLP-1 by 60% (AUC: LPS+GLP-1+cAMP inhibitor=46+/-1.5, p<0.0001). The PKA inhibitor reduced the effects of GLP-1 by 100% (AUC: LPS+GLP-1+PKA inhibitor=56+/-1.5, p<0.0001). GLP-1 attenuates the increase in microvascular permeability induced by LPS. GLP-1 may protect the endothelium during inflammation, thus decreasing third-space fluid loss.

Effect of hypertonic saline pre-treatment on ischemia-reperfusion lung injury in pig

BACKGROUND

Hypertonic saline may be administered in the setting of lung transplantation but may affect the development of ischemia-reperfusion lung injury. This study investigated the effects of the pre-treatment by intravenous hypertonic saline in a pig model of single lung ischemia-reperfusion.

METHODS

Forty-three pigs (34 +/- 4 kg) under mechanical ventilation were randomly assigned to a left lung ischemia-reperfusion alone or preceded by 4-ml/kg 7.5% hypertonic saline, 33-ml/kg normal saline, or by the infusion of the vasodilator nicardipine. Animals without ischemia served as controls. After euthanasia, the left lung was sampled for histologic analysis and measurement of lung water and alveolar-capillary permeability.

RESULTS

Ischemia-reperfusion resulted in high-permeability pulmonary edema, hypoxemia, and increased interleukin-6 serum level. Hypertonic saline pre-treatment worsened pulmonary edema of the left lung (6.6 +/- 0.7 vs 4.8 +/- 0.8 ml/kg of body weight, p < 0.05) and resulted in a higher ratio of the protein level in the alveolar fluid to the serum protein level (0.41 +/- 0.04 vs 0.21 +/- 0.09, p < 0.05) and in a higher histologic damage score (11 [range, 9-11.75] vs 6.5 [range, 4.5-7.5], p < 0.05) without promoting pulmonary or systemic inflammation. Lung injury was affected neither by normal saline nor by nicardipine pre-treatment. Nicardipine did not influence the deleterious effect of hypertonic saline.

CONCLUSIONS

Pre-treatment by intravenous hypertonic saline worsened ischemia-reperfusion lung injury independently of its effects on the cardiac index or pulmonary circulation but probably through a direct effect of hyperosmolarity on endothelial permeability.

[Controlled hypernatremia]

Hypernatremia exerts its main effect on the brain through the osmotic gradient it creates on either side of the blood brain barrier, which is impermeable to sodium. This generates a transfer of water from the intracellular to the vascular sector leading to temporary cell shrinkage. Osmoregulation permits cerebral cells to accumulate osmoactive molecules in order to restore their initial volume. It has been demonstrated in animals with brain injury that intracellular dehydration occurs essentially in the nonlesioned hemisphere. In most experimental studies, the reduction in cerebral volume obtained by hypertonic saline (HS) perfusion is accompanied by an intracranial pressure decrease, even under hemorrhagic shock conditions. Initially, clinical studies successfully used HS, as an alternative to mannitol, in the treatment of acute and refractory intracranial hypertension. Then continuous infusion of HS, with the objective of inducing hypernatremia, had produced encouraging effects on intracranial pressure control. However, these results were limited to non-randomized studies, without control groups and mainly in pediatric patients. Nevertheless, the use of HS on intracranial hypertension, refractory to conventional treatments, could be reasonable under strict monitoring of natremia as well as its adverse effects.

Albumin impacts the effects of tonicity on microvascular hydraulic permeability

BACKGROUND

An increase in tonicity shrinks endothelial cells. This cell shrinkage may open inter-endothelial gaps and allow more fluid to escape from the microvasculature. This increase in microvascular permeability is not supported by clinical studies suggesting that water is pulled into the vascular space, not lost into the interstitium. We hypothesized that albumin influences the change in trans-endothelial water movement caused by alterations in tonicity by a mechanism other than oncotic pressure.

MATERIALS AND METHODS

Hydraulic permeability (L(p)) was measured in rat mesenteric venules using the Landis micro-occlusion model. Measures of L(p) were obtained after successive perfusions with 1% albumin solution (BSA) of varying sodium chloride (NaCl) concentrations (85, 135, 185, and 235 mm) (n = 6). Additional venules were perfused with 7% NaCl followed by 7% NaCl + BSA and L(p) measured (n = 6). Units for L(p) are x10(-7) cm/sec(-1) cm/H(2)O(-1).

RESULTS

As the NaCl concentration in BSA increased from 85 mm to 235 mm, L(p) decreased from 1.93 +/- 0.41 to 0.97 +/- 0.11. Compared to results without albumin, BSA with 185 mm NaCl decreased L(p) from 3.93 +/- 0.08 to 1.25 +/- 0.18 (P = 0.04), and BSA with 235 mm NaCl decreased L(p) from 6.14 +/- 0.05 to 0.96 +/- 0.11 (P = 0.002). There was a three-fold decrease in L(p) when BSA was added to the 7% NaCl solution (P = 0.02).

CONCLUSIONS

Albumin attenuated the increase in L(p) that is associated with higher NaCl concentrations. Because this model controls for oncotic pressure, albumin may impact L(p) by a mechanism other than oncotic force. Albumin appears to stabilize the endothelial barrier during HS perfusion and prevents the loss of intravascular fluid. Appropriate albumin levels may play an important clinical role in modulating trans-endothelial fluid efflux during HS administration.

Osmotic regulation of cell function and possible clinical applications

Inflammation and immunosuppression can cause acute respiratory distress syndrome, multiple organ failure, and sepsis, all of which are lethal posttraumatic complications in trauma patients. Prevention of the inflammation and immunosuppression has been a main focus of trauma researcher for many years. Recently, hypertonic resuscitation has attracted attention as a possible therapeutic approach to counteract such deleterious immune responses in trauma patients. We have begun to understand how hypertonic fluids affect immune cell signaling, and a number of experimental and clinical studies have started to reveal valuable information on the clinical efficacy and the limitations of hypertonic resuscitation fluids. Knowledge of how osmotic cues regulate immune cell function will enable us to fully exploit the clinical potential of hypertonic resuscitation to reduce inflammatory and anergic complications in trauma patients.

The impact of albumin on hydraulic permeability: comparison of isotonic and hypertonic solutions

Hypertonic saline, Dextran, and albumin have been advocated for rapid restoration of intravascular volume. The goal of this study was to define how albumin impacts the effects of hypertonic saline and Dextran on hydraulic permeability. We hypothesized that albumin would decrease the hydraulic permeability (L(p)) of isotonic and hypertonic solutions containing Dextran. Using the modified Landis micro-occlusion technique, single rat mesenteric venules were perfused with either Ringer's + 1% albumin (RA) or hypertonic saline + 1% albumin (HSA). In sequential cannulations of the venules, 1%, 2%, and 3% Dextran was added to the RA perfusion (n = 6) and the HSA perfusion (n = 6). These results were compared with similar studies completed without albumin. Albumin significantly decreased L(p) with all HS solutions studied compared with HS without albumin. Baseline L(p) measurements for RA and HSA solutions were 1.08 +/- 0.07 and 0.51 +/- 0.03, respectively. In the RA group, 2% and 3% Dextran was associated with a lower L(p) of 0.83 +/- 0.04 (P = 0.002) and 0.67 +/- 0.05 (P = 0.002), respectively. In the HSA group, 2% and 3% Dextran was associated with a lower L(p) of 0.37 +/- 0.02 (P = 0.001) and 0.32 +/- 0.02 (P < 0.0001), respectively. All values for L(p) are x 10(-7) cm x s(-1) x cmH2O(-1). Albumin maintains low hydraulic permeability levels during perfusion with hypertonic saline. In the setting of sufficient of endothelial albumin levels, hypertonic saline and Dextran may be advantageous when used for resuscitation by decreasing trans-endothelial fluid flux and augmenting intravascular volume.

Effect of hypertonic saline on microvascular permeability in the activated endothelium

INTRODUCTION

The effect of hypertonic saline (HTS) on microvascular permeability in microvessels with activated endothelial cells is unclear. We hypothesized that HTS and HTS with dextran would decrease hydraulic permeability after activation of the endothelium.

METHODS

Hydraulic permeability (L(p)) was measured in rat mesenteric venules using the modified Landis micro-occlusion technique. The effects of 185 mM HTS and HTS plus 2% dextran (HSD) were tested in the activated endothelium by measuring L(p) at baseline, after perfusion with ATP, and again after HTS (n = 6) or HSD (n = 6). ATP (10 microM) activated endothelial cells and increased L(p) 4-fold. Additional venules were used to test the effects of 135 mM NaCl (n = 6) and 235 mM (n = 6) NaCl after endothelial activation with ATP.

RESULTS

After endothelial activation with ATP, L(p) values were 6.05 +/- 1.63. Subsequent perfusion with HTS decreased L(p) to 2.05 +/- 0.52 (P = 0.01). In the HSD trails, L(p) values after ATP were 6.17 +/- 1.38. Perfusion with HSD decreased L(p) to 1.65 +/- 0.30 (P = 0.001). After endothelial activation, 135 mM NaCl had no effect on L(p); however, 185 mM NaCl decreased L(p) 3-fold and 235 mM NaCl decreased L(p) 6-fold. Units for L(p) are x10(-7) cm - s(-1). cmH(2)O(-1).

CONCLUSIONS

Both HTS and HSD decreased hydraulic permeability after endothelial activation. These findings suggest that HTS may decrease microvascular fluid loss during states of elevated microvascular leak. In addition to the ability of hypertonic solutions to withdraw intracellular water to increase plasma volume, these findings propose an endothelial barrier mechanism whereby HTS and HSD act to maintain intravascular volume.

Dextran modulates microvascular permeability: effect in isotonic and hypertonic solutions

Hypertonic saline solutions with Dextran (HSD) have been advocated for rapid restoration of intravascular volume. Dextran is thought to increase the duration of action of hypertonic saline (HS) by selectively partitioning the water in the vascular space that has been drawn out of cells by HS. The goal of this study was to define the microvascular permeability modulating activity of Dextran in both isotonic and hypertonic solutions. We hypothesized that Dextran would decrease hydraulic permeability (Lp). Using the modified Landis micro-occlusion technique, single rat mesenteric venules were perfused with either normal Ringers (NR) with 135 mM NaCl or HS with 185 mM NaCl. In sequential cannulations of the venules, 1%, 2%, and 3% of Dextran was added to the NR perfusion (n = 6) and the HS perfusion (n = 6). The Lp was measured at baseline and after perfusion with each Dextran concentration. Baseline Lp measurements for NR and HS solutions were 1.01 +/- 0.034 and 5.14 +/- 1.02, respectively. In the NR group, the 2% and 3% Dextran decreased permeability below baseline levels to 0.79 +/- 0.028 (P < 0.0001) and 0.66 +/- 0.028 (P < 0.0001), respectively. In the HS group, the 2% and 3% Dextran decreased permeability to 1.65 +/- 0.53 (P < 0.0001) and 0.99 +/- 0.2 (P < 0.0001), respectively. All values for Lp are x10(-7) cm s(-1) x cm H2O(-1). The addition of Dextran to isotonic and hypertonic solutions results in a decrease in microvessel permeability. This effect is more pronounced with the perfusion of hypertonic solutions. The results demonstrate the oncotic potential of Dextran and its ability to hold water in the vascular space. Dextran may have a beneficial effect when used for resuscitation with HS by decreasing microvascular permeability and augmenting intravascular volume.