Department of Nephrology, University Hospital of Lund, Sweden
Correspondence and offprint requests to: Björn Öqvist, Department of Nephrology, University Hospital of Lund, S-221 85 Lund, Sweden.
![]() |
Abstract |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Methods. We used the PAN-(puromycin aminonucleoside) nephritis model in order to induce the nephrotic syndrome in female Wistar rats. Eight rats were given PAN, 15 mg/100 g body weight, intraperitoneally 10 days prior to the study, whereas 21 rats served as controls. Albumin clearance to tissues was measured using a dual isotope technique. Repeated blood samples as well as samples from various muscles, kidney, liver, lung, heart, abdominal wall and from ascites fluid were taken to determine radioactivity and tissue dry-to-wet weights. Clearance of albumin (Clalb) from plasma to interstitium was calculated from the (linear) increment in `plasma equivalent tissue albumin space' as a function of time, corrected for intravascular volume and oedema. The plasma and urine concentrations of albumin were determined in a parallel study by single radial diffusion using monospecific rabbit anti-rat antiserum in seven PAN animals and 13 controls.
Results. A marked fall in dry-to-wet weight ratios together with pronounced proteinuria, oedema and ascites were found in the PAN animals. Haematocrit decreased from 45% (3251) to 30% (2838) and serum albumin from 22.0 g/l (16.325.2) to 4.94 g/l (3.206.72) in control and PAN animals, respectively. However, Clalb apparently remained unchanged in the PAN animals in comparison to controls in most tissues examined. Thus, in these in vivo experiments there was no direct evidence of an increased extravasation of albumin in extrarenal tissues.
Conclusions. There was no strong support for the contention that a generalized disturbance of capillary integrity outside the renal vasculature would contribute to the oedema formation in the PAN nephrotic syndrome.
![]() |
Introduction |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
However, there is also the possibility that there may be a generalized increase of vascular permeability in extrarenal tissues in the nephrotic syndrome, as proposed by Lange and Meltzer [3,4] and recently by Lewis et al. [5], thus contributing to the oedema formation. In other words, the processes responsible for the reduced glomerular permselectivity may also cause changes in the permeability of peripheral vessels such as those in the skin and muscle, the latter comprising the largest vascular bed in the body.
In the present study the PAN-induced nephritis model was employed to investigate whether transvascular clearance of albumin (Clalb) is increased or not in extrarenal tissues in the nephrotic syndrome. The PAN-model was used, since it is assumed to mimic the minimal-change nephrosis in man. Albumin extravasation into tissues was assessed in vivo using a dual albumin tracer technique to monitor intra- and extravascular `plasma equivalent' albumin spaces [6,7]. In addition, whole-body plasma and blood volumes were assessed simultaneously.
![]() |
Methods |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
[125I]HSA (Human serum albumin, Institut for Energiteknikk, Kjeller, Norway), used as extravascular tracer (tracer I), was given intra-arterially (i.a.) at time 0 and [131I]HSA, used as an intravascular reference (tracer II), i.a. at 60 min (or in some cases at 30 min or 15 min). The animals were sacrificed after another 510 min by i.a. injection of saturated KCl. Free iodine was reduced to 0.30.5% using Microcon 30 filters, as measured after trichloracetic acid precipitation. Blood samples, each 25 µl, were taken at 5, 10, 20, 30, 35, 40, 50, 55 and 60 min. Tissue samples from abdominal skin, m. gastrocnemius, m. tibialis anterior and m. biceps femoris of both legs, large bowel, small bowel, stomach, kidney, liver, lung, heart, abdominal wall and from ascites fluid were taken directly upon sacrifice.
Samples were weighed and then measured to obtain at least 104 counts in a gamma counter (Wallac 1480 WizardTM 3, Turku, Finland) and then dried at 6570°C until constant weight (2448 h). Appropriate corrections for spill-over, background activity and radioactive decay were performed.
To calculate transcapillary clearance of tracer albumin (Clalb), the plasma equivalent spaces for albumin tracer I and tracer II were each assessed as the amount of tracer present per gram tissue (CPM/g) divided by the corresponding average plasma tracer concentration (CPM/L). Extravascular albumin tissue space was obtained by subtracting the intravascular albumin space (tracer II) from the total (extravascular+intravascular) albumin space (tracer I) at time T. Clalb was obtained by dividing the extravascular space by time and correlated to 100 g of tissue. This could be done since there is normally a linear increment in the plasma equivalent tissue albumin space as a function of time during the early extravasation of tracer albumin to tissues [7,10].
The degree of oedema was calculated from dry-to-wet weight ratio of PAN-rat tissues (DW/WW)P and those of control rats (DW/WW)0 from the formula:
![]() |
The `oedema factor', fE=1+E/100, was used to always standardize the extravascular albumin space to tissue dry weight (actually to the wet tissue weight before any oedema formation had occurred), by multiplication of all extravascular spaces by fE.
Plasma volume (PV) was calculated by dividing the total mass of radioactivity administered (at time zero) by the c.p.m. per millilitre plasma as extrapolated to time zero using a monoexponential plot. Blood volume was calculated from central haematocrit and PV after correction (using factor 0.91) for total body haematocrit when assessed from central haematocrit [11].
The plasma and urine concentrations of albumin were determined by single radial diffusion [12] using monospecific rabbit anti-rat antiserum (Kemila, Sollentuna, Sweden). Eight microlitres of undiluted plasma or urine was used and the plates were incubated in a humid chamber at 8°C for 3 days. Purified albumin (Sigma Chemical Co., St Louis, MO, USA) was used as standard.
Results are given as medians and ranges. StatView ANOVA with post-hoc testing was used for statistical calculations.
![]() |
Results |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
|
|
Increased albuminuria, from 0.41 g/l (0.161.21) in controls to 18.75 g/l (8.9021.47) in nephrotic animals, was followed by a marked decrease in serum albumin, from 22.0 g/l (16.325.2) in controls to 4.94 g/l (3.206.72) in PAN animals.
![]() |
Discussion |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Albumin is the main colloid responsible for plasma colloid osmotic pressure and the first line of defence against oedema formation. Marked hypoalbuminaemia and a drop in COPp per se may thus cause marked oedema formation according to the classical Starling hypothesis. In a study of analbuminaemic rats, however, no oedema was seen, possibly explained by a compensatory increase in other plasma proteins, such as orosomucoid [18]. Renkin and co-workers [19] in a study of analbuminaemic rats found only slight differences in Clalb versus normal controls, though there were significant differences in a few individual tissues examined. The Clalb values in that study and in an earlier study [7] are very similar to ours, except for skin, where Renkin et al. [19] found an increased Clalb in analbuminaemic rats. Furthermore, in moderate hypoalbuminaemia there are compensatory reductions in COPi [1], and increases in interstitial hydrostatic pressure (Pi), acting as `safety factors' against oedema formation.
One must bear in mind that the individual clearance values not only reflect capillary permeability (P) but also the capillary surface area (S) and the microvascular pressure (Pc) [10,20]. Concerning the microvascular surface area, PAN-nephrosis would hardly imply any changes in S, at least not any reductions in this parameter. If anything, S would be increased due to the plasma volume expansion (see below) and due to the low haematocrit in nephrosis, in analogy with the situation in uraemic patients, who have a low haematocrit [21]. Furthermore, there is no evidence for an altered capillary hydrostatic pressure in the nephrotic syndrome in general, at least not in man [5]. However, we cannot exclude that there is an increased capillary surface area and an increased capillary filtration coefficient [5] in our nephrotic animals, which is partly offset by a reduced driving force, i.e. a reduced transcapillary hydraulic pressure gradient for albumin, caused by the nephrotic oedema (see below).
The reason for the observed increase in plasma and blood volumes is not obvious, but is consistent with several other studies in humans [2226]. One possible explanation is that renal sodium retention during nephrosis leads to such increases. In acute experiments a reduction of plasma proteins has been shown to cause a fall in blood volume only when the hypoproteinaemia is severe [27], but on the contrary, in the chronic nephrotic syndrome an increase in blood volume is often found [22,28]. Actually, Koomans et al. in their study of nephrotic patients [25] found a small elevation of blood volume in overhydrated nephrotic patients, despite large variations in extracellular fluid volume. It thus seems that the regulation of plasma volume has priority over the regulation of interstitial fluid volume in this situation [25,29]. The renal sodium retention in the PAN-nephrotic syndrome has been studied by Ichikawa et al. [30]. PAN-nephrosis was induced by selective infusion of PAN into one kidney in rat experiments, while the other kidney was left intact. This caused Na-retention only in the affected kidney, whereas Na excretion was normal in the control kidney.
Wraight [31] explained the preservation and even increase in plasma volume in hypoalbuminaemia as a consequence of a decreased protein capillary `permeability' in combination with a decreased interstitial fluid protein concentration and (COPi), implying an essentially maintained transcapillary osmotic gradient in hypoproteinaemia. This is in line with the present data, but the findings should rather be understood in the light of a heteroporous capillary membrane theory [20,32]. In such a model the Starling fluid equilibrium is maintained across the microvascular walls due to the presence of a large number of protein selective small pores (of radius 45 nm) in the endothelium. Macromolecules, however, reach the interstitium through a very small number of large pores (radius 25 nm). Across large pores there is no Starling equilibrium, because of the low effective colloid osmotic pressure gradient prevailing across these pores normally. Thus, there is always fluid filtration occurring through large pores, which is solely governed by the hydrostatic pressure gradient between plasma and interstitium. In line with this theory, Rippe et al. [32] showed a clear-cut proportionality between COPp and Clalb at zero (or low) transcapillary net filtration rates. Thus, if plasma COPp is lowered while the Pc is not markedly altered, then there will be an initially increased fluid filtration across the microvascular walls. This will lead to an increase in Pi and a reduction in COPi. These changes may, at least partly, buffer the initial increases in transcapillary fluid filtration. Most importantly, the pressure gradient across large pores is now reduced following the reduction in the transcapillary hydrostatic pressure gradient. Thus, the increases in tissue pressure following hypoproteinaemia should result in a (slightly) reduced macromolecular transport from blood to tissue.
One possible source of error in this study is that the role of the `lymphatic safety factor', i.e. the increase in lymph flow in order to maintain the transcapillary oncotic pressure gradient, and thereby prevent oedema, is unknown. Hollander [33], in a study of different patients with oedema of various aetiology, concluded that albumin in accordance with the two-pore theory [20] is removed from the tissues mainly by lymphatics. Furthermore, lymphatic flow is generally increased in various types of oedema, including those in liver cirrhosis and in the nephrotic syndrome. Conhaim calculated a several-fold increase in lymph flow in a study on sheep with severe hypoproteinaemia [34]. In a more recent study by Paulson et al. [35] a significant increase in intestinal lymph flow was demonstrated in nephrotic rats. One could then argue that any increase in transcapillary albumin transport in nephrosis would be offset by an increased lymphatic drainage of tracer. However, since the interstitial equilibrium distribution volume for albumin is quite large, at least in muscle (45 ml/100 g) [11], and the transcapillary albumin clearance is low (0.005 ml/min), the initial drainage of tracer from tissue to lymph should be negligible during the present conditions. This is because the rate constant of solute removal from the interstitium will be determined by Clalb divided by the interstitial albumin distribution volume, i.e. here 0.005/5=1x10-3/min. This holds if the interstitium functions as a well-mixed compartment. However, the situation may be different in tissues with a relatively small interstitial volume, and a high Clalb such as in the lung [36] or intestine [37]. Furthermore, there may be preferential channels existing between the capillary barrier and the lymphatics, with which tracer albumin may rather rapidly equilibrate. In that case, there may have been removal of tracer from the tissues during the conditions of the present experiments. In a number of recent studies by Renkin and co-workers, this component was, however, considered to be small [38,39].
One previous study [5] has indicated the presence of a moderately elevated filtration coefficient (LpS, hydraulic conductivity) in the calf in patients with different types of the nephrotic syndrome. Since LpS is dependent of both permeability and surface area, it could not be determined whether either or both of these parameters had been affected. Possibly, as mentioned above, the capillary surface area in e.g. muscle would be slightly increased in the nephrotic syndrome. One cannot, however, rule out that at least part of the increment in LpS in nephrotic oedema may be a spurious one due to methodological errors inherent in the LpS determination. LpS is determined from the reasonably straight weight gain slope occurring some time after venous pressure elevation. This linear phase will occur earlier and with a greater slope in oedematous conditions than in non-oedematous conditions. This is because in oedematous conditions increases in filtration rate are not markedly buffered by Starling force adjustments, i.e. increases in Pi and reductions in COPi occurring during e.g. LpS determinations, which however occurs during non-oedematous conditions [40]. Another possibility is that the pre-to-post-capillary resistance ratio may have been reduced during oedema formation in the nephrotic syndrome, leading to a higher degree of capillary pressure elevation in the nephrotic subjects compared to normals for any level of venous pressure elevation performed during a LpS measurement. This would lead to an overestimation of LpS in oedematous conditions.
In summary, the present study of transvascular albumin clearance during in vivo conditions could not confirm the notion of a generalised increase in transvascular albumin permeation in PAN-induced nephrotic syndrome in rats.
![]() |
Acknowledgments |
---|
![]() |
References |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|