Fat Embolism Does Not Alter Cardiac Structure or Induce Pathological Changes in a Rat Model.

INTRODUCTION: Fat embolism (FE) encompasses conditions in which fatty substance becomes embedded in a tissue/organ. Fat emboli most commonly affect the lungs in a trauma setting. This can lead to both significant pathology locally and systemically including changes in structure, inflammatory response, activation of the renin-angiotensin system, and subsequent hypoxia. In fact, changes in skin, brain, lungs, and kidneys have been noted in FE syndrome. Because there is an extensive record of pathology reports on this condition without evidence of direct cardiac involvement, as well as our studies showing apparent complete recovery after the acute embolism, we hypothesized that structural changes similar to the lung and at the same time course would not be observed in the heart. METHODS: We used a rat model of FE previously described by our group where we have documented significant lung pathology. In this study, we analyzed both pulmonary and cardiac structure, histology, and gene expression at 48 h and 10 wks post fat injection to mimic FE. RESULTS: Despite severe inflammatory evidence and structural changes to the lung and vasculature up to 10 wks after FE, we found no significant alterations to cardiovascular morphometry including lumen patency ratio, adventitia/media ratio, fibrosis content, and heart chamber/wall dimensions in stained histological sections. Additionally, genetic markers of cardiac pathological hypertrophy were not significantly elevated 48 h or 10 wks after fat treatment. Oil Red O staining showed increased fat droplet content within lung and aorta tissue, but not in the myocardium. CONCLUSIONS: Our study suggests that, in contrast to the lungs, the heart is more resistant to the inflammatory and remodeling responses that result from FE, possibly due to the organ-specific differences in fat retention.

Evidence for angiotensin mediation of the late histopathological effects of pulmonary fat embolism: Protection by losartan in a rat model.

PURPOSE: In a model of fat embolism using triolein-treated rats, we have reported that the acute pulmonary histopathological changes at 48 hrs were ameliorated by the angiotensin AT1 receptor blocker losartan, the angiotensin converting enzyme inhibitor captopril, and the direct renin inhibitor aliskiren. Although much of the pathology had declined by 3 weeks, the changes persisted at 6 weeks. The purpose of the study was to extends the time course investigation to 10 weeks and to examines whether the fat embolism effects continue to be blocked by losartan when given at a late time period. MATERIALS AND METHODS: Unanesthetized rats were challenged with i.v. triolein or saline. After 6 weeks, one group received saline or losartan i.p. and the losartan group also received losartan in the drinking water. At 10 weeks, the experiment was terminated. RESULTS: Confirming previous results, the fat embolism group showed normal weight gain at 6 weeks without apparent distress and also appeared normal at 10 weeks. However, at 10 weeks the lungs showed inflammatory and fibrotic changes that were greater than those found at 6 weeks. These changes were reduced by losartan. CONCLUSIONS: These findings show that the effects of fat embolism continue to progress to 10 weeks after the initial insult with triolein. The fact that the protective effects of losartan treatment started at 6 weeks supports the involvement of the renin-angiotensin system in late as well as early stages of the histopathological changes following fat embolism. It also supports the use of angiotensin blockade in clinical situations even long after an initial trauma where fat embolism is suspected.

Renin-Angiotensin Blockade Reduces Readmission for Acute Chest Syndrome in Sickle Cell Disease.

Rationale Acute chest syndrome (ACS) is a life-threatening complication of sickle cell disease (SCD). Current treatment is supportive-supplemental oxygen, transfusions, and antibiotics. Prevention of ACS may reduce morbidity and mortality in patients with SCD. Acute chest syndrome appears similar to pulmonary fat embolism (PFE), a complication of severe skeletal trauma or orthopedic procedures from pulmonary micro-vessel blockage by bone marrow fat. Vascular obstruction and bone marrow necrosis occur in PFE and ACS.  Pulmonary fat embolism rat models have shown that angiotensin-converting enzyme inhibitors (ACEI) and angiotensin II receptor blockers (ARB) mitigate damage in PFE. These medications could work similarly in ACS. We hypothesize that time to readmission after one hospitalization for ACS will be reduced in patients taking ACEI or ARB compared to patients who are not. Methods This is a retrospective cohort study. Inclusion criteria are adults (18 to 100 years) with sickle cell anaemia (HbSS), hemoglobin SC (HbSC) disease, sickle cell thalassemia (HbSßThal), hospitalized with ACS over 16 years (January 1, 2000, to March 31, 2016); patients who take and don't take ACEI or ARB. Children (<18 years old), elderly adults (>100 years old), pregnant patients, and patients with sickle cell trait were excluded. Data was collected from the Health Facts database, which contains de-identified information from the electronic medical records of hospitals in which Cerner© has a data use agreement. Kaplan-Meier estimates explored a time-to-event model of ACS readmission. Multivariable analysis (age, gender, smoking history) was conducted using Cox proportional hazards regression. Results were reported around a 95% confidence interval. Results There were 6972 patients in total. Of which, 9.6% (n = 667) reported taking ACEI or ARB. Results for the covariates were: average age of 38 years old; 63% female (n = 4366/6969); 16% smokers (n = 1132). Readmission rates were higher for patients not taking ACEI/ARB than those who did: 0.44 (95% CI 0.43, 0.46) versus 0.28 (95% CI 0.24, 0.31) at one year, and 0.56 (95% CI 0.55, 0.58) versus 0.33 (95% CI 0.29, 0.37) at two years. Age had the strongest effect on readmission rates for patients taking ACEI/ARB (adjusted hazards ratio 0.78 [95% CI 0.68, 0.91]). Conclusion Patients with SCD who reported taking ACEI or ARB had lower readmission rates for ACS; age was the strongest covariate. Our results may have a significant impact on the prevention of ACS. Prospective studies comparing ACEI or ARB therapy versus placebo are needed to confirm this preventative effect.

Mitigating effects of captopril and losartan on lung histopathology in a rat model of fat embolism.

BACKGROUND: Fat embolization (FE) is an often overlooked and poorly understood complication of skeletal trauma and some orthopedic procedures. Fat embolism can lead to major pulmonary damage associated with fat embolism syndrome (FES). METHODS: A model of FE in unanesthetized rats, using intravenous injection of the neutral fat triolein, was used to study the potential therapeutic effect on lung histopathology of altering the production of, or response to, endogenous angiotensin (Ang) II. Either captopril, an Ang I converting enzyme inhibitor, or losartan, an Ang II type 1 receptor blocker, was injected 1 hour after FE by triolein injection. After euthanasia at 48 hours, histopathologic evaluation was used to compare the drug-treated animals with control animals that received only triolein. RESULTS: Histology of the lungs of rats treated only with triolein revealed severe, diffuse pathology. Alveolar septa showed severe, diffuse inflammation. Bronchial lumina showed severe mucosal epithelial loss. The media of the pulmonary small arteries and arterioles was thicker, and the lumen patency was reduced 60% to 70%. Trichrome staining confirmed the abundant presence of collagen in the media and adventitia, as well as collagen infiltrating the bronchial musculature. Both captopril and losartan treatments reduced the inflammatory, vasoconstrictor, and profibrotic effects present at 48 hours (p<0.001). With treatment, the vascular lumen remained patent, and the fat droplets were reduced in size and number. There was a reduction in the number of infiltrating leukocytes, macrophages, myofibroblasts, and eosinophils, along with a significant decrease in hemorrhage and collagen deposition (p<0.001). Pathologic changes in bronchial epithelium were also diminished. CONCLUSIONS: The results suggest that the use of drugs that act on the renin-Ang system might provide an effective and targeted therapy for fat embolism syndrome.

The renin inhibitor aliskiren protects rat lungs from the histopathologic effects of fat embolism.

BACKGROUND: Fat embolism (FE) and the consequent FE syndrome occurring after trauma or surgery can lead to serious pulmonary injury, including ARDS and death. Current treatment of FE syndrome is limited to supportive therapy. We have shown in a rat model that the renin angiotensin system plays a significant role in the pathophysiology of FE because drugs interfering with the renin angiotensin system, captopril and losartan reduce the histopathologic pulmonary damage. The purpose of the current study was to determine if inhibition of renin by aliskiren, an FDA-approved drug for treating hypertension, would produce effective protection in the same model. METHODS: The FE model used intravenous injection of the neutral fat triolein in unanesthetized rats. Intraperitoneal injections of saline or aliskiren at either 50 or 100 mg/kg were performed 1 hour after FE induction via triolein. Rats were euthanized at 48 hours, and various histologic stains were used to examine the lungs. RESULTS: (1) Fibrosis: rats treated with triolein showed significant fibrotic changes with increased collagen and myofibroblast activation (p < 0.0001 for both trichrome and α-smooth muscle actin staining). Aliskiren blocked this inflammatory and profibrotic process to a level indistinguishable from the controls (p < 0.0001 for both trichrome and α-smooth muscle actin staining). (2) Fat: rats treated with triolein showed a statistically significant increase in fat (p = 0.0006). Subsequent aliskiren administration at both doses reduced the size, distribution, and amount of fat droplets (low dose, p = 0.0095; high dose, p = 0.0028). (3) Vessel patency: the low dose of aliskiren blocked the reduction of lumen patency observed after triolein administration (p = 0.0058). CONCLUSIONS: Aliskiren protected the lungs of rats from gross and histopathologic FE-induced pulmonary damage at 48 hours. Clinical implications include the use of aliskiren both prophylactically (before certain orthopedic procedures) and therapeutically (after severe trauma) to prevent the consequent severe pulmonary pathologic sequelae.

Fat embolism sensitizes rats to a "second hit" with lipopolysaccharide: An animal model of pulmonary fibrosis.

BACKGROUND: Pulmonary fat embolism (FE) in patients after major bone fracture and other trauma may lead to acute respiratory distress, but few clinical evidence of lung injury remains, and there is a dearth of histopathologic information after the initial recovery. We recently reported histologic changes in the lungs of a patient who died after cesarian delivery, which were similar to a rat model of FE. In this model, we found that despite an apparent full recovery, modest fibrotic damage persisted up to 6 weeks. We tested whether at that time, an additional insult could exacerbate the effects. METHODS: Triolein (0.2 mL intravenously administered) was given to 18 rats and saline to 18 controls. Six weeks later, each group received (intraperitoneal) lipopolysaccharide (LPS, 3 mg/kg; n = 9) or saline (n = 9). At necropsy 48 hours later, lungs and organs were harvested for study. Lung parenchymal, vascular, and bronchial damage was scored by two pathologists and by Image J analysis. RESULTS: Animals given LPS after triolein showed reduced pulmonary arterial medial diameters compared with those that received LPS alone (p < 0.04). Lung small arterial patency (lumen) was reduced after triolein and even more after combined LPS and triolein (p = 0.018). Triolein increased fibrotic markers (trichrome and smooth muscle actin staining), and this was more severe after LPS. At 6 weeks, fat droplets remained in the lungs, localizing to the subpleural septa. These were smaller and more widespread after LPS. CONCLUSION: This report describes an animal model to study exacerbation of lung histopathology induced by FE using a known pulmonary toxicant, LPS (a "second hit"). Vascular and fibrotic lung damage was more severe when LPS was given to rats 6 weeks after triolein compared with LPS alone. FE rendered the lungs extra sensitive to a second hit long after apparent clinical recovery. This experimental model of fat embolism provides useful informations for the treatment of patients suffering for similar conditions.

Persistent and progressive pulmonary fibrotic changes in a model of fat embolism.

BACKGROUND: Fat embolism (FE) after trauma and some orthopedic procedures is known to cause acute lung injury, including acute respiratory distress syndrome. However, its potential long-term effects on the lung are unknown. A previous study using a rat model of FE found significant histopathologic changes in the lungs after intravenous injection of triolein for up to 11 days. This study detailed the persistence of the lung damage and investigated the input of the renin-angiotensin system in its pathology. METHODS: Unanesthetized rats were injected via the tail vein with 0.2 mL saline or triolein. After euthanasia, at 3 weeks or 6 weeks, lung sections were stained to highlight cellular structure, presence of collagen and fat, or immunolabeled for smooth muscle actin or angiotensin peptides. RESULTS: At 3 weeks or 6 weeks after triolein injection, there was no dilatation of the heart or inferior vena cava, no congestion of the liver or spleen, no adventitial edema, nor was fluid present in alveoli or pleural cavity as reported in animals at earlier time points. Persisting pathology included reduced lumen patency, thickening of the media of small arteries and arterioles, and vascular and septal inflammation. Although the fat content of the lung decreased from week 3 to week 6, there was a progressive increase in collagen, smooth muscle actin, and angiotensin peptides. CONCLUSIONS: This model extends the effect of FE on pulmonary pathology to 6 weeks, revealing persistent vasculitis, septal inflammation, and progressive fibrotic changes which are associated with increased presence of angiotensin peptides.

Fat embolism: evolution of histopathological changes in the rat lung.

The pathophysiology of Fat Embolism Syndrome (FES) is poorly understood and subject to some controversy. Evaluation of the evolution of histological changes in the lungs of patients with FES is impractical. The current theories of FES were established through acute clinical observations and acute animal experiments, but sequential changes in the histology of lungs over a prolonged period have not been made. The progressive effects of fat embolization of the lungs were examined in a rat model over a period of 11 days. Triolein, a major bone marrow fat, was administered to conscious Sprague-Dawley rats via the caudal vein. Rats were euthanized at 24, 48, 96 h, and 11 days, but some died within a few hours. Histomorphometric evaluations of lung tissue were made, including stains for fat, collagen, and smooth muscle actin. Arterial and arteriolar patency decreased progressively up to 96 h, but returned toward normal after 11 days. A striking finding was the very early presence of inflammation and fibrosis after only several hours, persisting up to 11 days. The results of this study provide evidence of both very early and prolonged changes due to fat embolization.