Upsala J Med Sci 91: 45-52, 1986 

Effect of N-Acetylcysteine on Fibrin 
Deposition in the Rat Lung due to 

Intravascular Coagulation 
Thomas Wegener,1.2. Rolf Wallin' and Tom Saldeen' 
De artments of 'Forensic Medicine, 'Lung Medicine, and 

'Clinical Physiology, University of Uppsala, Sweden 

ABSTRACT 

Intravascular coagulation was induced in rats by i.p. injection of a 
fibrinolysis inhibitor, tranexamic acid (AMCA, 200 mg/kg B.W.), and i.v. 

injection of bovine thrombin (500 NIH unitslkg B.W.) and the fibrin 

deposition in the lungs was assessed with I-labelled fibrinogen. 
125 

Treatment with N-acetylcysteine (NAC) partly prevented the deposition 

of fibrin in the lungs, and the disappearance of fibrinogen from the 

blood, but did not seem to influence the elimination of fibrin in the 

lungs. The results indicate that NAC may counteract pulmonary damage in 

this experimental model, by inhibiting intravascular fibrin formation. 

INTRODUCTION 

N-acetylcysteine (NAC) has been shown to have preventive or 

therapeutic effects on two types of experimental pulmonary damage ( 3 , 1 3 ) .  

Bernard et a1 (3) claimed that NAC, as a free radical scavenger, has a 
favourable effect in endotoxin-induced ARDS (adult respiratory distress 

syndrome), in sheep. 
Wegener et a1 ( 1 3 )  found that in another ARDS model in the rat, NAC 

counteracted the pulmonary damage by diminishing the increase in lung 

weight and reducing of the microscopically observed interstitial and 

alveolar oedema. In addition, after administration of NAC less fibrin 
was found in precapillary arterioles by a semiquantitative method , 
suggesting that NAC may decrease the formation of fibrin or increase its 

elimination from the lungs. 

45 



The aim of this study was t o  quantify the fibrin deposition in the 
rats with pulmonary damage treated and not treated with NAC, using a 
method employing I-labelled fibrinogen (lo), and to determine I 
whether NAC could diminish the trapping of fibrin in the lungs or 
increase its elimination. 

125 

MATERIAL AND METHODS 

Animals. Male Sprague-Dawley rats (ALAB, Sollentuna, Sweden), 
weighing 195 to 210 g, were used. They were allowed free access to food 
and tap water. 

Substance. Human fibrinogen KABI (grade L) and tranexamic acid 
(trans-4-aminomethyl-cyclohexane-carboxylic acid, abbreviated to AMCA 
were kindly supplied by Kabi-Vitrum AB, Stockholm, Sweden). 

R 
Bovine thrombin (Topostasine , Hoffman-La Roche, Switzerland) was 

used. 
R 

N-acetylcysteine (Fluimucil , 100mg/ml aqueous solution pH 6.5, 
Zambon SPA, Milano-Vincenza, Italy) was generously supplied by the 

producing company. 
R 

Pentobarbital (Inactin , Byk-Gulden, Konstanz, FRG) was used for 
anaesthesia. 

125 
Human fibrinogen was labelled with I, using the iodine 

monochloride method ( 6 ) .  As human fibrinogen has been shown to give the 
same result as rat fibrinogen in the present context, and has greater 
stability (2), it was chosen for these experiments. 

Procedure. Labelled fibrinogen solution (2.5 mlfkg body weight B.W.) 

containing about 2.5 mg of protein and 518 KBq/ml was injected into a 
tail vein in the rat 24 h before the experiment took place. This 
procedure was carried out under light ether anaesthesia. 

About one hour before the experiment began, 0.5 g of Inactin was 
dissolved in 10 ml of sodiumchloride (9 mgfml, isotonic solution) and 2.5 

ml/kg (B.W.) was injected intraperitoneally (i.p.). Sodiumchloride was 
abbreviated to saline. To ensure a free airway, all animals were 
tracheostomized. During the experiment the body temperature was kept 
constant at 38 C with an infrared lamp. Pulmonary damage was induced 
by an i.p. injection of AMCA, 200 mglkg B.W., followed 10 min later by a 
lO-minute infusion of bovine thrombin, 500 NIH unitslkg B.W., given into 
a tail vein by means of an infusion pump. Thrombin administration must 

be combined with AMCA in order to cause pulmonary damage similar to that 

Seen in Patients with posttraumatic pulmonary insufficiency ( 1 , 6 , 7 ) .  NAC 

0 

46 



was administered i.v. twice in the first experiment and once in the second 

experiment in a dose of 125 mg/kg B.W. 

The first experiment comprised 15 rats, divided into three groups. 1. 
Labelled fibrinogen + Thrombin + AMCA + NAC (n=6) 2. Labelled fibrinogen 
+ Thrombin + AMCA + Saline ( S )  (n=6) 3. Labelled fibrinogen + Saline 
(n=3). Saline served as a control fluid to give equal injection volumes. 

The experiment was carried out as described in Table 1. 

Experimental mod& Table 1 

h 
-24 0’ 5‘ 15’ - 25‘ 45‘ 105’ 

125 
1. I-fibrinogen NAC AMCA Thrombin NAC Killed 

125 
2. I-fibrinogen S AMCA Thrombin 5 Killed 

Killed 
125 

3 .  I-fibrinogen S S S 5 

At 105 min the animals were killed by aortic exsanguination. 

The second experiment comprised 16 rats, divided into the same three 

groups as 
described above; group 1 (n=7) group 2 (n=5) and group 3 (n=4). 

Experimental model. Table 2. 

h 
-24 0’ 5’ 15‘ - 25’ 30’ 

1 .  lZ5I-f ibrinogen NAC AMCA Thrombin Killed 

2. lZ5I-f ibrinogen S AMCA Thrombin Killed 

I-fibrinogen S S 5 Killed 
125 

3. 

At 30 rnin the animals were killed by aortic exsanguination. 3 
< 

Blood was collected in plastic tubes containing either citrate or EDTA 

buffer. The lungs were quickly removed, perfused with isotonic saline 

solution, dissected free of connective tissue, cleaned with filter paper 

41 



and placed in weighed plastic tubes. The radioactivity of the left lung 
was determined. In the first experiment the right lung from each animal 
was homogenized. The homogenization procedure was made according to a 
method described previously by Busch et al(5) to determine how much of 
the labelled substance was precipitated (fibrin). 

Analysis. The fibrinogen concentration in citrate plasma was 
determined by the method of Nilsson and Olow ( 9 ) .  The fibrinogen values 

were corrected for the influence of the erythrocyte volume fraction (EVF) 
upon the citrate dilution of plasma. 

EVF: Aortic blood was drawn into EDTA tubes, and EVF determinations 
were made in triplicate in micro-EVF tubes after centrifugation at 10 000 
x g for 5 min. 

Radioactivity: The radioactivity in weighed samples of tissue, blood 
and labelled fibrinogen was measured in the plastic tubes using a (EDTA) 

gamma spectrometer. 
Calculations. The fibrin content in the lungs was calculated from a 

formula presented previously by Busch et a1 ( 4 )  and modified by Diffang 
et a1 ( 6 ) .  

In short, F = I / Q  ( Tex 
organ (mg/g); Q is tie fa:tor for converting I radioactivity to mg 
fibrin, consisting of the mean relative specific radioactivity (cpm x 
10 /g) of plasma fibrinogen in control rats; T is the total 

- T ) where F is the amount of fibrin in the 
125 

3 

125 exp I radioactivity in the tissue specimen in the experimental rat (cpm 
3 125 

x 10 /g); T is the mean I radioactivity in the tissue specimen 
in control rats (cpm x 10 /g) = (plasma + extravascular radioactivity). C 3 

Statistical methods. Conventional methods as described by Snedecor 
(12) were used. Differences between the groups were tested by Student’s 
t-test and to confirm significance at the 5% level also by 
Wilcoxon-White’s two-sample ranks test. The results are given as mean 
and S.D. and degrees of significance are indicated as follows: *= ~(0.05, 
**= p<o.o1, ***= p<O.OOl. 

RESULTS 

The amount of fibrin in the whole lung or per g lung tissue was 
significantly lower (p<O.OOl) in both experiments of rats with pulmonary 
damage that had received NAC-treatment than in such rats not treated with 

NAG. The same results were obtained for homogenized lungs in the first 

48 



experiment although the mean difference was somewhat smaller (Table 3 and 

4 )  
The fibrinogen level in non-NAC-treated animals with pulmonary damage 

was significantly lower (Table 3 and 4 )  than in those with pulmonary 
damage, that were treated with NAC. 

Table 3. Experiment 1 
Erythrocyte volume fraction (EVF) and blood and lung 
fibrinogen 1251 radioactivities and fibrin content in 
the lung (mean values and SD). 

Groups 1 (n=6) 2 (n=6) 3 (n=3) 

EVF 40 5 40 2 36 2 

Blood 
cpm x 10 / g  

Whole lung 
cpm x 1O3/g 

17.6 8.1 7.4 2.8 35.2 6.0 

22.6 12.7*** 77.4 !' 11.7 9.7 ! 1.4 

Homogenized lung, 18.4 11.7*** 54.2 10.1 7.3 2.0 
cpm x 103/g 

Whole lung fibrin, 0.5 0.5*** 3.0 0.6 0 
mg/g lung tissue 

Homogenized lung 0.5 0.5*** 2.1 : 0.5 0 
fibrin, mg/g lung 
tissue 

Fibrinogen in blood, 1.60 : 0.49** 0.55 0.38 2.64 0.12 
g/L 

Level of significance: * ~(0.05, * *  p<O.OI, * * *  p<O.OOl 

Table 4. Experiment 2 
Fibrinogen and fibrin content in the lung (mean values 
and SD) . 

Groups 1 (n=7) 2 (n=5) 3 (n=4) 

Whole lung fibrin 
mg/g lung tissue 3.09 0.34*** 5.34 f 0.69 0 
Fibrinogen in blood 
g/L 1.07 0.22* 0.43 0.69 2.55 0.15 

(n=3) 

Level of significance: * p<O.O5, * *  p<O.Ol, * * *  p<O.001 

4-868571 49 



Fig. 1 shows that there is no difference in the elimination rate of 
fibrin between animals treated or untreated with NAC. 

6 

4 

2 

- 

Fibrin (mg/g) 
in whole lung 

1 

* * *  1 

0 5 1 0  50 8 0  

Thrombin 
infusion 

Time after end of 
thrombin infusion (min) 

Fig. 1. Elimination rate of fibrin. 
- Isotonic sodiumchloride + AMCA + Thrombin 
--- N-acetylcysteine + AMCA + Thrombin 
Level of significance * * *  p<O.OOl 

DISCUSSION 

In a previous study, Wegener et a1 (13) found that NAC partly 
inhibited ARDS caused by intravascular coagulation, possibly by its 

scavenging effect and/or, (in this particular ARDS model), by influencing 
the fibrin deposition in the lung. A reduction in the deposition of 
fibrin could have been due to decreased fibrinogen consumption, to 
increased fibrin elimination or could be secondary to the scavenging 
effect. 

Our results indicate that NAC counteracts fibrin deposition in the 
lung directly, since the fibrinogen level in the blood in NAC-treated 

animals is higher than in animals not given this treatment and the amount 
of fibrin in the lungs shortly after thrombin infusion was much less in 

NAC-treated rats. It may therefore be justified to suggest that NAC 
inhibits fibrin formation in the blood. 

50 



The very rapid effect on fibrin formation in the lungs after the 
administration of thrombin indicates that the effect of NAC on fibrin 
formation is not secondary to its scravenging effect but more probably 

due to a direct anticoagulant effect. As the elimination curves for lung 
fibrin did not differ between rats treated and not-treated with NAC (Fig. 
l ) ,  this substance probably does not influence the removal of fibrin from 

the lungs. The findings of Sim et a1 ( 1 1 )  that a relatively high 
concentration of NAC showed no fibrinolytic activity when added to fresh 
human fibrin plates supports our opinion that NAC does not excert its 
effect by increasing fibrin elimination. Sim et a1 (11) also found NAC 
to be an active inhibitor of thrombus formation in the microcirculation 

of the hamster cheek pouch. 

ACKNOWLEDGEMENTS 

This work was supported by the Swedish National Association against 
Heart and Lung Diseases, the Swedish Medical Research Council, and 
Ciba-Geigy, Sweden. 

REFERENCES 

1. Arfors, K.E., Busch, C., Jakobsson, S., Lindquist, O., Malmberg, P., 
Rammer, L. & Saldeen, T.: Pulmonary insufficiency following intravenous 
infusion of thrombin and AMCA (Tranexamic acid) in the dog. Acta Chir. 
Scand. 138:445-452, 1972. 

2. Bagge, L., Busch, C., Rammer, L. & Saldeen, T.: Delayed fibrin 
elimination from the lungs of burned rats with endogenous inhibition of 
the fibrinolytic system. Thrombosis Research 2:365-376, 1973. 

3. Bernard, G.R., Lucht, W.D., Niedermeyer, M.E., Snapper, J . R . ,  Ogletree, 
M.L. 6 Brigham, K.L.: Effect of N-acetylcysteine on the pulmonary 
response to endotoxin in the awake sheep and upon in vitro granulocyte 
function. J. Clin. Invest. 73:1772-1784, 1984. 

4. Busch, C., Rammer, L. & Saldeen, T.: Quantitation of fibrin deposition 
and elimination in organs of rats injected with labelled fibrinogen and 
albumin. Thromb. Diat. Haemorrh. 29:94-107, 1973. 

5. Busch, C. & Rammer, L.: Quantitation of fibrin deposition and elimination 
in organs of rats injected with labelled fibrinogen by isolation of the 
labelled fibrin from water soluble tracer. Thromb Diat Haemorrh 29, 108- 
1 1 4 ,  1973. 

6. Diffang, C. & Saldeen, T.: Effect of brinase (protease I from 
Aspergillus oryzae) on the elimination of fibrin from the lungs and 
pulmonary damage in rats with induced intravascular coagulation and 
inhibited fibrinolysis. Thrombosis Research 9: 611-622, 1976. 

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7. Gerdin, B., Diffang, C. & Saldeen, T.: Pulmonary insufficiency in the 
rat after intravascular coagulation and inhibition of fibrinolysis. Eur. 
Surg. Res. 13:402-413, 1981. 

8. Helmkamp, R.W., Contreras, M.A. & Bale, U.F. :1311-labelling of proteins 
9. Nilsson, I.-M. & Olow, B.: Determination of fibrinogen and fibrinolytic 

activity. Thromb. Diat. Haemorrh. (Stuttg.) 8:297, 1962. 

10. Saldeen, T.: Quantitative determination of intravascular coagulation in 
the lungs of experimental animals. Scand J Haemat 6: 205-215, 1969. 

11. Sim, A.K., McCraw, A.P. & Davies, M . E . :  An evaluation of the anti- 
thrombotic potential of three synthetic compounds. (Personal communication 
of data file by Zambon S.p.A., Bresso-Milan, Italy, 1976. 

12. Snedecor, W.: "Statistical methods". The Iowa State University Press, 
1965. 

13. Wegener, T., Sandhagen, B. & Saldeen, T.: Effect of N-acetylcysteine 
on pulmonary damage due to microembolism in the rat. Eur J Resp Dis. 
Submitted. 

Address for reprints: 

Thomas Wegener 
Department of Lung Medicine 
Uppsala University 
Akademiska sjukhuset 
S-751 85 Uppsala, Sweden 

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