Cardiovascular effects of epinephrine during rewarming from hypothermia in an intact animal model.

Rewarming from accidental hypothermia is often complicated by "rewarming shock," characterized by low cardiac output (CO) and a sudden fall in peripheral arterial pressure. In this study, we tested whether epinephrine (Epi) is able to prevent rewarming shock when given intravenously during rewarming from experimental hypothermia in doses tested to elevate CO and induce vasodilation, or lack of vasodilation, during normothermia. A rat model designed for circulatory studies during experimental hypothermia and rewarming was used. A total of six groups of animals were used: normothermic groups 1, 2, and 3 for dose-finding studies, and hypothermic groups 4, 5, and 6. At 20 and 24 degrees C during rewarming, group 4 (low-dose Epi) and group 5 (high-dose Epi) received bolus injections of 0.1 and 1.0 microg Epi, respectively. At 28 degrees C, Epi infusion was started in groups 4 and 5 with 0.125 and 1.25 microg/min, respectively. Group 6 served as saline control. After rewarming, both CO and stroke volume were restored in group 4, in contrast to groups 5 and 6, in which both CO and stroke volume remained significantly reduced (30%). Total peripheral resistance was significantly higher in group 5 during rewarming from 24 to 34 degrees C, compared with groups 4 and 6. This study shows that, in contrast to normothermic conditions, Epi infused during hypothermia induces vasoconstriction rather than vasodilation combined with lack of CO elevation. The apparent dissociation between myocardial and vascular responses to Epi at low temperatures may be related to hypothermia-induced myocardial failure and changes in temperature-dependent adrenoreceptor affinity.     

Is oxygen supply a limiting factor for survival during rewarming from profound hypothermia?

It has been postulated that unsuccessful resuscitation of victims of accidental hypothermia is caused by insufficient tissue oxygenation. The aim of this study was to test whether inadequate O2 supply and/or malfunctioning O2 extraction occur during rewarming from deep/profound hypothermia of different duration. Three groups of rats (n = 7 each) were used: group 1 served as normothermic control for 5 h; groups 2 and 3 were core cooled to 15 degrees C, kept at 15 degrees C for 1 and 5 h, respectively, and then rewarmed. In both hypothermic groups, cardiac output (CO) decreased spontaneously by > 50% in response to cooling. O2 consumption fell to less than one-third during cooling but recovered completely in both groups during rewarming. During hypothermia, circulating blood volume in both groups was reduced to approximately one-third of baseline, indicating that some vascular beds were critically perfused during hypothermia. CO recovered completely in animals rewarmed after 1 h (group 2) but recovered to only 60% in those rewarmed after 5 h (group 3), whereas blood volume increased to approximately three-fourths of baseline in both groups. Metabolic acidosis was observed only after 5 h of hypothermia (15 degrees C). A significant increase in myocardial tissue heat shock protein 70 after rewarming in group 3, but not in group 2, indicates an association with the duration of hypothermia. Thus mechanisms facilitating O2 extraction function well during deep/profound hypothermia, and, despite low CO, O2 supply was not a limiting factor for survival in the present experiments.     

Effects of sympathetic stimulation during cooling on hypothermic as well as posthypothermic hemodynamic function

This experimental study was performed to explore hemodynamic effects of a moderate dose epinephrine (Epi) during hypothermia and to test the hypothesis whether sympathetic stimulation during cooling affects myocardial function following rewarming. Two groups of male Wistar rats (each, n=7) were cooled to 15 degrees C, maintained at this temperature for 1 h, and then rewarmed. Group 1 received 1 microg/min Epi, i.v., for 1 h during cooling to 28 degrees C, a dose known to elevate cardiac output (CO) by approximately 25% at 37 degrees C. Group 2 served a saline solution control. At 37 degrees C, Epi infusion elevated CO, left ventricular systolic pressure, maximum rate of left ventricle pressure rise, and mean arterial pressure. During cooling to 28 degrees C, these variables, with the exception of mean arterial pressure, decreased in parallel to those in the saline solution group. In contrast, in the Epi group, mean arterial pressure remained increased and total peripheral resistance was significantly elevated at 28 degrees C. Compared with corresponding prehypothermic values, most hemodynamic variables were lowered after 1 h at 15 degrees C in both groups (except for stroke volume). After rewarming, alterations in hemodynamic variables in the Epi-treated group were more prominent than in saline solution controls. Thus, before cooling, continuous Epi infusion predominantly stimulates myocardial mechanical function, materialized as elevation of CO, left ventricular systolic pressure, and maximum rate of left ventricle pressure rise. Cooling, on the other hand, apparently eradicates central hemodynamic effects of Epi and during stable hypothermia, elevation of peripheral vascular vasopressor effects seem to take over. In contrast to temperature-matched, non-Epi stimulated control rats, a significant depression of myocardial mechanical function occurs during rewarming following a moderate sympathetic stimulus during initial cooling.     

Myocardial gene expression profiling of rewarming shock in a rodent model of accidental hypothermia

Background

Severe accidental hypothermia represents a cardiovascular emergency associated with high mortality and poor recovery of cardiac function. The biochemical changes occurring within the heart during the development of hypothermia and subsequent resuscitation are not known.

Methods

By mRNA expression profiling, we have characterized gene expression changes occurring within the myocardium in an intact rat model of accidental hypothermia during cooling to a core temperature of 15 °C and subsequent rewarming to 37 °C. During the rewarming phase, these animals develop a profound low-output cardiac failure.

Results

Hypothermia induces expression of known mediators of thermotolerance, including heat-shock protein 70 and several factors involved in protection against apoptotic cell death. Upregulation of genes involved in autophagy and increased abundance of autophagosomal vesicles suggest involvement of autophagic degeneration in the development of myocardial dysfunction occurring during rewarming from hypothermia. Rewarming from hypothermia also induces expression of several pro-inflammatory genes involved in the nuclear factor kappa B (NFκB) signaling cascade.

Conclusions

Our data demonstrate that rewarming from hypothermia is associated with the induction of a cellular stress–response, including upregulation of autophagy and activation of pro-inflammatory signaling cascades. These data provide a framework for understanding the molecular changes that occur during induction of and rewarming from severe hypothermia, and identifies potential targets for cardioprotective interventions in resuscitation of victims of hypothermia.     

Myocardial mechanical dysfunction and calcium overload following rewarming from experimental hypothermia in vivo

Rewarming patients from accidental hypothermia are regularly complicated with cardiovascular instability ranging from minor depression of cardiac output to fatal circulatory collapse also termed “rewarming shock”. Since altered Ca²⁺ handling may play a role in hypothermia-induced heart failure, we studied changes in Ca²⁺ homeostasis in in situ hearts following hypothermia and rewarming. A rat model designed for studies of the intact heart in a non-arrested state during hypothermia and rewarming was used. Rats were core cooled to 15 °C, maintained at 15 °C for 4 h and thereafter rewarmed. As time-matched controls, one group of animals was kept at 37 °C for 5 h. Total intracellular myocardial Ca²⁺ content ([Ca²⁺]_i) was measured using ⁴⁵Ca²⁺. Following rewarming we found a significant reduction of stroke volume and cardiac output compared to prehypothermic control values as well as to time-matched controls. Likewise, we found that hypothermia and rewarming resulted in a more than six-fold increase in [Ca²⁺]_i to 3.01 ± 0.43 μmol/g dry weight compared to 0.44 ± 0.05 μmol/g dry weight in normothemia control. These findings indicate that hypothermia-induced alterations in the Ca²⁺-handling result in Ca²⁺ overload during hypothermia, which may contribute to myocardial failure during and after rewarming.     

Renal Dnase1 Enzyme Activity and Protein Expression Is Selectively Shut Down in Murine and Human Membranoproliferative Lupus Nephritis

Background

Deposition of chromatin-IgG complexes within glomerular membranes is a key event in the pathogenesis of lupus nephritis. We recently reported an acquired loss of renal Dnase1 expression linked to transformation from mild to severe membranoproliferative lupus nephritis in (NZBxNZW)F1 mice. As this may represent a basic mechanism in the progression of lupus nephritis, several aspects of Dnase1 expression in lupus nephritis were analyzed.

Methodology/Principal Findings

Total nuclease activity and Dnase1 expression and activity was evaluated using in situ and in vitro analyses of kidneys and sera from (NZBxNZW)F1 mice of different ages, and from age-matched healthy controls. Immunofluorescence staining for Dnase1 was performed on kidney biopsies from (NZBxNZW)F1 mice as well as from human SLE patients and controls. Reduced serum Dnase1 activity was observed in both mesangial and end-stage lupus nephritis. A selective reduction in renal Dnase1 activity was seen in mice with massive deposition of chromatin-containing immune complexes in glomerular capillary walls. Mice with mild mesangial nephritis showed normal renal Dnase1 activity. Similar differences were seen when comparing human kidneys with severe and mild lupus nephritis. Dnase1 was diffusely expressed within the kidney in normal and mildly affected kidneys, whereas upon progression towards end-stage renal disease, Dnase1 was down-regulated in all renal compartments. This demonstrates that the changes associated with development of severe nephritis in the murine model are also relevant to human lupus nephritis.

Conclusions/Significance

Reduction in renal Dnase1 expression and activity is limited to mice and SLE patients with signs of membranoproliferative nephritis, and may be a critical event in the development of severe forms of lupus nephritis. Reduced Dnase1 activity reflects loss in the expression of the protein and not inhibition of enzyme activity.     

Loss of heart phospholipid arachidonic acid without phospholipid peroxidation in anaesthetized rats rewarmed after prolonged deep hypothermia

Hypothermia–rewarming of the heart results in contractile dysfunction under in vitro as well as in vivo conditions. Increase in reactive oxygen species (ROS), lipid peroxidation and calcium overload are proposed mechanisms. In the first protocol of this study, the effect of putative phospholipase and calcium channel modulator mepacrine during deep hypothermia (4 h 14 °C) plus rewarming was tested in an isolated perfused rat heart model previously reported not to involve increase in lipid peroxides. Contractile function was measured under isovolumetric conditions using an intra-ventricular balloon connected to a transducer and recording system. Mepacrine completely reversed hypothermia–rewarming induced contractile failure in this model (LV dP/dt_max: 3236 ± 517 vs. 1058 ± 185 mm Hg/s in untreated hearts). In the second part of the study, lipid peroxidation of the heart was examined in vivo in anesthetized rats subjected to 4 h of deep hypothermia followed by rewarming. In this model recovery of heart function judged by cardiac output is decreased whereas blood pressure and heart rate recover fully. Peroxy conjugated diene isomers of unsaturated fatty acids were measured in heart phospholipids. The composition of the non-esterified fatty acids and the phospholipid fatty acid pool was examined in order to reveal signs of membrane remodeling. The results demonstrated no significant changes in phospholipid peroxidation after rewarming (91.07 ± 5.23 vs. 88.63 ± 7.73 nmol/g dry wt. in control). There was significant relative reduction in the content of arachidonic acid in the phospholipid fraction (29.55 ± 1.65 vs. 24.76 ± 1.48%). There was marked decrease in non-esterified fatty acids in myocardial tissue (1992 ± 291 vs. 1069 ± 189 nmol/g dry wt.), but a significant relative increase in arachidonic acid (20:4) in this fraction (3.46 ± 0.42 vs. 4.99 ± 0.30%). In conclusion, rewarming from deep hypothermia is not associated with increased phospholipid peroxidation. There is, however, a significant remodeling of the phospholipid fraction of myocardial lipids in vivo probably as a result of receptor or calcium stimulated phospholipase activity. Calcium or calcium stimulated phospholipase activity could contribute to posthypothermic contractile dysfunction.     

Left ventricular dysfunction following rewarming from experimental hypothermia

This study was aimed at elucidating whetherventricular hypothermia-induced dysfunction persisting after rewarmingthe unsupported in situ dog heart could be characterized as a systolic,diastolic, or combined disturbance. Core temperature of 8 mongrel dogswas gradually lowered to 25°C and returned to 37°C over aperiod of 328 min. Systolic function was described by maximum rate ofincrease in left ventricular (LV) pressure(dP/dt_max),relative segment shortening (SS%), stroke volume (SV), and theload-independent contractility index, preload recruitable stroke work(PRSW). Diastolic function was described by the isovolumic relaxationconstant () and the LV wall stiffness constant(K_p). Comparedwith prehypothermic control, a significant decrease in LV functionalvariables was measured at 25°C:dP/dt_max 2,180 ± 158 vs. 760 ± 78 mmHg/s, SS% 20.1 ± 1.2 vs.13.3 ± 1.0%, SV 11.7 ± 0.7 vs. 8.5 ± 0.7 ml, PRSW 90.5 ± 7.7 vs. 29.1 ± 5.9 J/m · 10²,K_p 0.78 ± 0.10 vs. 0.28 ± 0.03 mm¹, and  78.5 ± 3.7 vs. 25.8 ± 1.6 ms. After rewarming, the significant depression ofLV systolic variables observed at 25°C persisted: dP/dt_max 1,241 ± 108 mmHg/s, SS% 10.2 ± 0.8 J, SV 7.3 ± 0.4 ml, and PRSW52.1 ± 3.6 m · 10², whereasthe diastolic values ofK_p and  returned to control. Thus hypothermia induced a significant depressionof both systolic and diastolic LV variables. After rewarming, diastolicLV function was restored, in contrast to the persistently depressed LVsystolic function. These observations indicate that cooling inducesmore long-lasting effects on the excitation-contraction coupling and the actin-myosin interaction than on sarcoplasmicreticulum Ca²⁺trapping dysfunction or interstitial fluid content, makingposthypothermic LV dysfunction a systolic perturbation.

     

Effects of milrinone on left ventricular cardiac function during cooling in an intact animal model

A significant reduction in immunogenicity has been observed in some frozen-thawed tissues after cryopreservation. The objective of this study was to evaluate the effects of programmed cryopreservation on immunogenicity of rabbit bladder mucosa and on the extent of immunological rejection caused by the allograft. This study would provide theoretical support for the application of allogenic frozen-thawed bladder mucosa in the treatment of urethral stricture. Forty-two adult male New Zealand rabbits were used in this study. The immunogenicity was detected by mixed lymphocyte reaction using the allograft of bladder mucosa (fresh and frozen-thawed) and spleen lymphocytes. Twelve urethral stricture models were established in New Zealand rabbits for substitution urethroplasty using the allograft of bladder mucosa, which were divided into fresh and frozen-thawed group. Two weeks after operation, lymphocyte proliferation was detected in both blood and spleen of recipient rabbits. At the same time, immunohistochemical staining of urethral allograft was performed and the expression of CD3, CD4 and CD8 were observed. The mRNA of bladder mucosa (fresh and frozen-thawed) was extracted and the expressions of RLA-I, RLA-II and RLA-III gene were detected by real-time PCR. By mixed lymphocyte reaction, we found that allogenic lymphocyte proliferation stimulated by frozen-thawed bladder epithelial cells was significantly weaker than that of the fresh cells. The blood and spleen lymphocytes from fresh bladder mucosa group showed significantly higher proliferation rate than frozen-thawed group. Compared with the fresh group, the expression of CD3+ and CD8+ T cells infiltrated in the operation locus of bladder mucosa urethroplasty was significantly decreased in the frozen-thawed group. However, the expressions of RLA genes did not change significantly after the freeze-thaw procedure. This study demonstrates for the first time that a programmed freeze-thaw procedure of rabbit bladder mucosa could reduce its immunogenicity in allogenic bladder mucosa urethroplasty and thus restrict the extent of immunological rejection, therefore, provides theoretical support for the application of frozen-thawed bladder mucosa in the treatment of urethral stricture.