Observation of microvasculature in intestinal wall after burn in rats

OBJECTIVE: To investigate the relationship between intestinal mucosa injury and changes in stereologic parameters for its vessels. STUDY DESIGN: PAS stain was used to observe the basement membrane of intestinal epithelium. To measure the parameters of microvasculature by stereology, microvasculature was shown by alkaline phosphatase stain. Diamine oxidase (DAO) activity was determined by spectrophotometry. RESULTS: Red mucus became thinner than that of the control group; basement membrane was disrupted at 3 post burn hours (PBH). Changes became more serious at 6 and 12 PBH. Villus height and crypt depth appeared shortened at post burn. Microvasculature diameter was reduced. Mean section area at 12 PBH was significantly lower than that of the control group (p < 0.01). Mean circumference at 6 PBH was 19.43 +/- 1.59 microm and in the control group 23.84 +/- 4.17 microm. After burn injury, DAO activity in the intestine was reduced, falling to minimum at 12 PBH (p < 0.01), and in plasma was raised significantly, reaching peak at 12 PBH (p < 0.05). CONCLUSION: Our results suggest disruption of basement membrane, reduction of microvasculature diameter and DAO activity in intestine will appear at post burn, which induces decreased blood flow in intestine and damage to intestinal mucosa.     

Pericardial delivery of omega-3 fatty acid: a novel approach to reducing myocardial infarct sizes and arrhythmias

O2-carrying fluids based on hemoglobin (Hb) are in various stages of clinical trials to determine their suitability as O2-carrying plasma expanders. Polymerized Hb solutions are characterized by their vasoactivity, low O2 affinity, oncotic effect, prolonged shelf life, and stability. Physiological responses to facilitated O2 transport after exchange transfusion with polymerized bovine Hb (PBH) were studied in the hamster window chamber model during acute moderate anemia to determine how PBH affects microvascular perfusion and tissue oxygenation. The anemic state [29% hematocrit (Hct)] was induced by hemodilution with a plasma expander (70 kDa dextran). After hemodilution, animals were randomly assigned to different exchange transfusion groups. Study groups were based on the concentration of PBH used, namely: PBH at 13 g Hb/dl [PBH13], PBH diluted to 8 (PBH8) or 4 (PBH4) g Hb/dl in albumin solution at matching colloidal osmotic pressure (COP), and no PBH (only albumin solution) at matching COP (PBH0). Measurement of systemic parameters, microvascular hemodynamics, capillary perfusion, and intravascular and tissue O2 levels was performed at 18% Hct. Restitution of O2-carrying capacity with PBH13 increased arterial pressure and triggered vasoconstriction, low perfusion, and high peripheral resistance. PBH4 and PBH0 exhibited lower arterial pressures compared with PBH13. Exchange transfused animals with PBH8 and PBH4 better maintained perfusion and functional capillary density than PBH13. Blood gas parameters and acid-base balance were recovered proportional to microvascular perfusion. Arterial O2 tensions were improved with PBH4 and PBH8 by preventing O2 precapillary release and increasing O2 reserve. Further studies to establish PBH optimal dosage, efficacy, safety, and its effect on outcome are indicated before Hb-based O2-carrying blood substitutes are implemented in routine practice.     

Role of brain lactic acidosis in hypoxic depression of respiration

The role of lactic acidosis of progressive brain hypoxia (PBH) as both a central chemoreceptor stimulant and a general respiratory depressant was assessed by preventing lactate formation both locally and globally with dichloroacetate (DCA). Phrenic nerve activity (PN) and ventral medullary pH (Vm pH) responses to PBH (1% CO-40% O2-balance N2) were determined in anesthetized, paralyzed, peripherally chemodenervated, vagotomized cats while fraction of end-tidal CO2 (FETCO2) and mean arterial blood pressure (MABP) were maintained constant. Topical DCA near the central chemoreceptors prevented the progressive Vm acidosis of PBH and was associated with a slightly greater depression of PN for any given level of brain hypoxia [75 +/- 12% base-line mock cerebrospinal fluid compared with 63 +/- 11% base-line topical DCA at O2 content of arterial blood (CaO2) of 7.5 ml O2/dl]. Systemic DCA also prevented the progressive acidosis of PBH and significantly altered the profile of depression with PBH. Before DCA, PBH produced a progressive reduction in PN after reducing CaO2 by 20%. After DCA, PN was not significantly depressed until CaO2 was reduced to very low levels, whereupon there was a sharp decline in PN. Before DCA, reducing CaO2 to 6 ml O2/dl reduced PN by 41 +/- 16%, whereas after DCA there was no significant reduction in PN (4 +/- 5%). We conclude that 1) lactic acidosis near the central chemosensitive regions does produce a small stimulation of respiration during PBH but that 2) the overwhelming response to central lactic acidosis of PBH is respiratory depression.     

Reversal of hemoglobin-induced vasoconstriction with sustained release of nitric oxide

Erythrocyte free hemoglobin (Hb) induces vasoconstriction due to nitric oxide (NO) scavenging, limiting the NO available for vascular smooth muscle. The central objective of this study was to restore NO bioavailability using long-lived circulating NO-releasing nanoparticles (NO-np) to reverse the vasoconstriction and hypertension induced by polymerized bovine Hb (PBH) NO scavenging. PBH (13 g/dl) was infused in a volume equal to 10% of the animal blood volume. Intravascular NO supplementation was provided with an infusion of NO-np (10 and 20 mg/kg body wt). This study was performed using the hamster window chamber model to concurrently access systemic and microvascular hemodynamics. Infusion of PBH increased blood pressure and induced vasoconstriction. Treatment with 10 and 20 mg/kg NO-np reduced the blood pressure and vasoconstriction induced by PBH. Moreover, the higher dose of NO-np decreased blood pressure and induced vasodilation compared with baseline, respectively. Treatment with NO-np to decrease PBH-induced vasoconstriction increased methemoglobin levels and plasma nitrite and nitrate. In conclusion, NO-np counteracted both systemic hypertension and decreased the vasoconstrictor effects of PBH infusion, improving systemic and microvascular function. Based on the observed physiological properties, NO-np has clear potential as a therapeutic agent to replenish NO in situations where NO production is impaired, insufficient, or consumed, thereby preventing vascular complications.     

Microvascular pressure and functional capillary density in extreme hemodilution with low- and high-viscosity dextran and a low-viscosity Hb-based O2 carrier

Blood losses are usually corrected initially by the restitution of volume with plasma expanders and subsequently by the restoration of oxygen-carrying capacity using either a blood transfusion or possibly, in the near future, oxygen-carrying plasma expanders. The present study was carried out to test the hypothesis that high-plasma viscosity hemodilution maintains perfused functional capillary density (FCD) by preserving capillary pressure. Microvascular pressure responses to extreme hemodilution with low- (LV) and high-viscosity (HV) plasma expanders and an exchange transfusion with a polymerized bovine cell-free Hb (PBH) solution were analyzed in the awake hamster window chamber model (n = 26). Systemic hematocrit was reduced from 50% to 11%. PBH produced a greater mean arterial blood pressure than the nonoxygen carriers. FCD was higher after a HV plasma expander (70 +/- 15%) vs. PBH (47 +/- 12%). Microvascular pressure spanning the capillary network was higher after a HV plasma expander (16-19 mmHg) compared with PBH (12-16 mmHg) and a LV plasma expander (11-14 mmHg) but lower than control (22-26 mmHg). FCD was found to be directly proportional to capillary pressure. The use of a HV plasma expander in extreme hemodilution maintained the number of perfused capillaries and tissue perfusion by comparison with a LV plasma expander due to increased mean arterial blood pressure and capillary pressure. The use of PBH increased mean arterial pressure but reduced capillary pressure due to vasoconstriction and did not maintain FCD.     

Cervical sympathetic and phrenic nerve responses to progressive brain hypoxia

To determine if depression of central respiratory output during progressive brain hypoxia (PBH) can be generalized to other brain stem outputs, we examined the effect of PBH on the tonic (tSCS) and inspiratory-synchronous (iSCS) components of preganglionic superior cervical sympathetic (SCS) nerve activity. Peak phrenic and SCS activity were measured in nine anesthetized, paralyzed, peripherally chemodenervated, vagotomized cats. PBH was produced by inhalation of 0.5% CO in 40% O2 while blood pressure and end-tidal CO2 were maintained constant. A progressive reduction in arterial O2 content from 14.3 +/- 0.6 to 4.5 +/- 0.3 vol% caused a 79 +/- 7% depression of peak phrenic activity and an 84 +/- 10% reduction of iSCS activity, but tSCS activity increased 42 +/- 21%. During CO2 rebreathing, iSCS activity increased in parallel with peak phrenic activity while tSCS activity was unchanged. The slopes of the CO2 responses of both phrenic (6.3 +/- 1.2%max/mmHg) and iSCS (4.6 +/- 0.8%max/mmHg) activity were unaffected by PBH. In four of nine hypocapnic and three of nine hypoxic studies, inspiratory activity in the SCS nerve was observed even after completely silencing the phrenic neurogram.(ABSTRACT TRUNCATED AT 250 WORDS)     

Triangularis sterni and phrenic nerve responses to progressive brain hypoxia.

Activity of the respiratory muscles that are not normally active during eupnea (genioglossal and abdominal) has been shown to be more vulnerable to hypoxic depression than inspiratory diaphragmatic activity. We hypothesized that respiratory muscles that are active at eupnea would be equally vulnerable to isocapnic progressive brain hypoxia (PBH). Phrenic (PHR) and triangularis sterni nerve (TSN) activity were recorded in anesthetized peripherally chemodenervated vagotomized ventilated cats. Hypercapnia [arterial PCO2 (PaCO2) = 57 +/- 3 (SE) Torr] produced parallel increases in peak PHR and TSN activity. PBH [0.5% CO-40% O2-59.5% N2, arterial O2 content (CaO2) reduced from 13.1 +/- 1.0 to 3.7 +/- 0.3 vol%] resulted in parallel decreases of peak PHR and TSN activity to neural apnea. PBH was continued until PHR gasping ensued (CaO2 = 2.9 +/- 0.2 vol%); TSN activity remained silent during gasping. After 6-12 min of recovery (95% O2-5% CO2; CaO2 = 7.8 +/- 0.8 vol%; PaCO2 = 55 +/- 2 Torr), peak PHR activity was increased to 110 +/- 18% (% of activity at 9% CO2) whereas peak TSN activity was augmented to 269 +/- 89%. The greater augmentation of TSN activity during the recovery period could not be explained solely by hypercapnia. In conclusion, we found that 1) TSN expiratory and PHR inspiratory activities are equally vulnerable to hypoxic depression and 2) recovery from severe hypoxia is characterized by a profound augmentation of TSN expiratory activity.     

Increased tissue PO2 and decreased O2 delivery and consumption after 80% exchange transfusion with polymerized hemoglobin

The O2-carrying blood substitute based on polymerized bovine hemoglobin (PBH) was used to determine efficacy in maintaining tissue Po2 after an 80% isovolemic blood exchange leading to a hematocrit of 19% [5.4 g Hb/dl from red blood cells (RBCs) and 6.3 g Hb/dl from PBH]. Effects were studied in terms of O2 delivery, O2 extraction, and tissue Po2 at the microcirculatory level at 1, 12, and 24 h after exchange transfusion in awake hamsters prepared with a window chamber model. At 1 h after exchange, arteriolar and venular diameters were decreased compared with baseline. Arteriolar diameter did not fully recover at 12 h after exchange, but venular diameter returned to normal. At 24 h after exchange, arteriolar and venular diameters were not different from baseline. Combining diameter and flow velocity data allowed us to calculate arteriolar and venular flows. At 1 h after exchange, arteriolar and venular flow was reduced compared with baseline. Arteriolar flow was lower at 12 h after exchange and recovered after 24 h. The number of capillaries with RBC passage [functional capillary density (FCD)] at 1 h after exchange with PBH was significantly lower than baseline. FCD remained decreased at 12 h; at 24 h after exchange transfusion, FCD was fully recovered. Tissue Po2 was maximal at 1 h after exchange and decreased progressively at 12 and 24 h after exchange. O2 release to the tissue was minimal at 1 h and increased at 12 and 24 h after exchange. These results suggest the impairment of tissue O2 metabolism after introduction of PBH into the circulation, which is mitigated as PBH concentration declines.     

Reversed brain size sexual dimorphism accompanies loss of parental care in white sticklebacks

Uncovering factors that shape variation in brain morphology remains a major challenge in evolutionary biology. Recently, it has been shown that brain size is positively associated with level of parental care behavior in various taxa. One explanation for this pattern is that the cognitive demands of performing complex parental care may require increased brain size. This idea is known as the parental brain hypothesis (PBH). We set out to test the predictions of this hypothesis in wild populations of threespine stickleback (Gasterosteus aculeatus). These fish are commonly known to exhibit (1) uniparental male care and (2) sexual dimorphism in brain size (males>females). To test the PBH, we took advantage of the existence of closely related populations of stickleback that display variation in parental care behavior: common marine threespine sticklebacks (uniparental male care) and white threespine sticklebacks (no care). To begin, we quantified genetic differentiation among two common populations and three white populations from Nova Scotia. We found overall low differentiation among populations, although F_ST was increased in between‐type comparisons. We then measured the brain weights of males and females from all five populations along with two additional common populations from British Columbia. We found that sexual dimorphism in brain size is reversed in white stickleback populations: males have smaller brains than females. Thus, while several alternatives need to be ruled out, the PBH appears to be a reasonable explanation for sexual dimorphism in brain size in threespine sticklebacks.     

Perchloric acid-soluble proteins and protein-bound hexoses in serum and tissues of normal, hypo-and hyperthyroid rats.

The total content of perchloric acid-soluble proteins (PCA-SP) and protein-bound hexoses (PBH) were studied in blood serum and tissues (liver, kidney, lung, brain) of normal, hypo- and hyperthyroid rats. The results obtained indicate that the hyperthyroid state induced an increase in both PCA-SP and PBH in blood serum and studied tissue homogenates, and hypothyreosis causes a decrease of total glycoproteins content in all studied materials. The results were counted per 1 g of protein and in this way the nonspecific effect of thyroid hormones on the protein metabolism had no influence on the measurements.