Effect of altered flow on the pattern of permeability around rabbit aortic branches

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Effect of altered flow on the pattern of permeability around rabbit aortic branches

Tracey J. Staughton¹, M. John Lever², and Peter D. Weinberg¹

¹ School of Animal and Microbial Sciences, University of Reading, Reading RG6 6AJ; and ² Physiological Flow Studies Group, Department of Biological and Medical Systems, Imperial College of Science, Technology and Medicine, London SW7 2BY, United Kingdom

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Uptake of circulating macromolecules by the aortic wall is greater downstream than upstream of branch sites in immature rabbits,but the opposite pattern is seen at later ages. The mature patternis nitric oxide dependent; we tested whether it is also flow dependent.Intercostal arteries of anesthetized rabbits were occluded, shamoperated, or left alone. Uptake of rhodamine-labeled albumin wasassessed by quantitative fluorescence microscopy of the sectionsthrough the aorta. In mature animals, uptake was higher upstreamthan downstream of the control and sham-operated branches, butthe pattern was reversed at occluded branches. In young animals,uptake was not significantly different between regions upstreamand downstream of control, sham-operated, or occluded branches.The absence of the normal immature pattern may reflect an influenceof anesthesia and will assist in the elucidation of mechanismsunderlying this pattern. The data for mature animals provide thefirst direct evidence that flow determines permeability near arterialbranches and may account for the inverse spatial correlation betweenshear stress and disease prevalence at branches of adult humanarteries.

blood flow; arterial permeability; rabbit aorta; age

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

ANITSCHKOW AND COLLEAGUES (1) showed early this century that aortic lesions in the cholesterol-fed rabbit occur particularlyfrequently downstream of branch sites. They suggested on the basisof experiments with intravital dyes that this resulted from anenhanced uptake of plasma constituents in such regions and furthersuggested that the enhanced uptake was caused by mechanical stresses.The patterns of lesions (15-17, 29, 37) and transport (5,27, 41, 49) have been confirmed many times and, followingthe suggestion of Fry (22), are widely thought to result fromeffects of elevated hemodynamic shear stresses. However, thereis a conspicuous lack of direct evidence that the variations intransport are flow dependent. The issue is further complicatedby the discrepancy with the lesion pattern subsequently observedin adult human arteries. In these vessels, lesions occur on theupstream lip of branches and the lateral walls of bifurcations(11, 14, 24, 46), which as several model and numericalstudies indicate are regions of low shear (2, 11, 21, 36,53). This pattern is difficult to reconcile with the roles oftransport and flow postulated for rabbitlesions.

It has recently been proposed that the occurrence of two different lesion distributions is related to age, not species, andthat this can resolve the uncertainty concerning the role of transport(6, 7, 39, 40). Human fetuses, neonates, and infantshave been known for some time to show the Anitschkow pattern oflipid deposition (43). These lesions must regress with increasingage, and new ones must then develop with the upstream distribution.It is now known that the spontaneous lesions occasionally seenin rabbits also switch from a downstream to a more upstream distributionwith age (6). Furthermore, although lesions occur downstreamof branches in young cholesterol-fed rabbits, the more upstreampattern can be induced in adult rabbits (7). Thus rabbit andhuman aortas seem to develop parallel but age-related distributionsof lipid deposition. Data obtained in the rabbit aorta show thatboth distributions can be explained by transport patterns. Theextensively investigated downstream pattern of transport is infact a property only of young rabbits. In adult animals, short-term(40) and quasi steady (39) transport are greater upstreamthan downstream ofbranches.

It is possible that effects of age are also the key to understanding the relation between flow and transport. In a study ofshort-term transport near branches by Sebkhi and Weinberg (40),mature rabbit aortas inadvertently exposed to tracer after death,and hence in the absence of blood pressure and flow, gave theyoung pattern of uptake, leading to the suggestion that it isthe adult, not the juvenile, pattern of transport that is flowdependent. The study described here (44) was designed to testthis hypothesis. Patterns of uptake by the aortic wall near intercostalbranch ostia were determined in young and old rabbits after flowaround some ostia had been modified by occluding the sidebranches.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Animals. All animal procedures complied with Home Office and local regulations. Five young (68-96 days, 1.84-3.4 kg) and seven old(613-738 days, 4.3-5.6 kg) male New Zealand White rabbits (MurexBiotech) were used to assess the effects of flow on aortic traceruptake. They were maintained on a standard diet (9603 TRB, HarlanTeklad).

Surgical procedures. Each animal was anesthetized with fentanyl fluanisone (Hypnorm, Janssen) and midazolam (Hynovel, Roche). Initial doses were0.3 ml/kg im and 2 mg/kg iv, respectively; boosters of one-thirdthese amounts were administered as required. Lidocaine (Xylocaine,1-2 ml, Astra) was applied subcutaneously around the throat andventral midline. The trachea was intubated and the animal ventilatedwith air (50 breaths/min, Harvard Small AnimalVentilator).

The abdomen was opened along the midline, the diaphragm removed, and the sternum split to expose the thoracic aorta. Intercostalarteries were either occluded, sham operated, or left alone. Inearly experiments they were occluded by tying with surgical threadand in later experiments by clamping with microserrefines (FineScience Tools). A preliminary experiment showed that occludingthe intercostal arteries too close to their origin resulted ina substantially elevated tracer uptake, presumably reflectingdamage to the aortic wall. Therefore, the ties or clamps werepositioned ~5-10 mm from the aorta. Each lung was gently liftedto allow manipulation of the intercostal arteries under it. Theties (or clamps) and the lungs were protected from each otherby placing a sheet of expanded polystyrene foam between them.For sham operations, incisions were made on either side of theintercostal artery to mimic those used when tying or clampingvessels.

Mean arterial blood pressure was recorded in six animals by introducing a cannula attached to a pressure transducer (SE Laboratories)into the carotid artery. Heart rate was obtained in the same animalsby placing a photoplethysmograph probe (TSD 100B, Biopac) overthe central ear artery. The probe was connected via an analog-to-digitalconverter (Pico ADC-100, 12-bit sampling at 500 Hz) to a PC runningPicolog software (Pico Technology). The surgical procedures took~50 min tocomplete.

Tracer administration and fixation. Permeability was assessed using bovine serum albumin (fatty acid free, First Link) labeled with the fluorescent dye sulforhodamineB (Lissamine rhodamine B, CI 45100, Sigma). This tracer was preparedand purified of free dye by standard techniques, as previouslydescribed (20, 51). It was administered via the marginal earvein (700 mg/kg) ~20 min after the intercostal arteries were tiedoff; preliminary experiments showed such a delay was necessaryto observe the effects describedbelow.

Preliminary experiments also showed that the tracer circulation time of 10 min used in conscious animals (40) did not givean adequate ratio of dye fluorescence to arterial wall autofluorescence.This probably occurred because the lower blood pressure (see RESULTS)reduced uptake. Tracer was therefore allowed to circulate for15 min. Heparin (1,000 IU iv, Sigma) was administered 2 min beforethe end of this period. At 15 min, an overdose of pentobarbitonesodium (Euthatal, 300 mg iv, Rhône Mérieux) was given, and ablood sample was collected from the heart. A retrograde cannulawas tied into the aorta at the level of the diaphragm, and thethoracic aorta was flushed for 30 s with ~50 ml of saline froma reservoir 90-100 cm above the vessel. The aorta was then fixedin the same way for 30 min with 10% neutral buffered formalin,after which it was excised and placed in the same solution fora further 24 h. Model studies have shown this fixative and durationto be effective in immobilizing the tracer (45).

Measurement of tracer uptake. Tracer uptake was assessed by measuring fluorescence from longitudinal sections of aortic wall cut through the center of intercostalbranch ostia, using the histological procedures and carefullycalibrated techniques of digital imaging fluorescence microscopypreviously described (45, 51). Average values were calculatedfor regions of the aortic wall up to 345 µm (~1 side branch diameter)from the ostium, in the intima and media combined. Equivalentautofluorescence intensities, obtained in 18 branches from twoadditional rabbits not administered tracer, were subtracted fromthese values. Measurements of tracer and autofluorescence werenormally made on six sections from eachbranch.

So that tracer levels in the wall could be expressed as a percentage of circulating concentrations, plasma prepared from theterminal blood sample was diluted 1:100 with 12.5% wt/vol gelatin(type B, Sigma) in phosphate-buffered saline (0.15 mol/l, pH 7.4).Gels were set, fixed for 24 h in 10% neutral buffered formalin,and processed in the same way as the arterial tissue, as previouslydescribed (50, 51).

Statistics. Data are expressed as means ± SE, and n indicates the number of rabbits unless otherwise stated. Statistical comparisons weremade between pairs of means by unpaired Student's t-test and between>2 means byANOVA.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Mean arterial blood pressure, measured while tracer was circulating, averaged 71 ± 5 mmHg (range 49-81 mmHg), which is ~80%of the normal in vivo value. Blood pressure was depressed in bothyoung and old rabbits. Heart rate was approximately equal to thenormal value in both young and old rabbits, averaging 242 ± 7beats/min (range 221-270 beats/min) while tracercirculated.

Patterns of transport are shown in Fig. 1. To express the pattern quantitatively, uptake in the upstream region was subtractedfrom that in the downstream region, and the difference was thenexpressed as a percentage of the mean in both regions. Numbersgreater than zero therefore signify greater uptake in the downstreamregion, whereas numbers less than zero signify greater uptakein the upstream region. In the immature animals (Fig. 1A), therewas no significant difference between the patterns of transportaround control, sham-operated, or occluded branches (F = 0.008,P > 0.05). On average, a downstream pattern was observed in allthree treatment groups, but the differences between regions weresmall and not significant (t = 0.04, P > 0.1; t = 0.02, P > 0.1;t = 0.04, P > 0.1 for control, sham-operated, and occluded branches,respectively).

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Fig. 1. Patterns of tracer uptake by the aortic wall upstream and downstream of the origins of intercostal arteries that had been occluded, sham operated, or left alone. Differences in uptake between upstream and downstream regions are shown as a percentage of the mean uptake; values >0 signify greater uptake downstream of the branch, values <0 signify greater uptake upstream. A: in immature rabbits (n = 5), tracer uptake was not significantly different between regions upstream and downstream of all three types of branch. B: in mature rabbits (n = 6), tracer uptake was greater upstream of control branches and this pattern was unaffected by sham operation; however, data for occluded branches were significantly different. Bars show means ± SE.

This pattern was markedly different from those previously observed in immature conscious rabbits (39, 40) or in immatureperfused aortas (18), where uptake has been substantially greaterin the downstream region. To ensure that this discrepancy wasnot caused by a change in rabbit arterial properties over timeor by some problem with the measuring equipment, but was insteaddue to the surgical protocol, the pattern of transport was determinedin one conscious, untreated rabbit of the same age. This animalgave a value of 86 ± 20% (n = 8 branches), exactly as expectedfrom the earlierstudies.

In mature animals (Fig. 1B), control branches gave the upstream pattern of transport seen in all previous studies (18, 39,40). The finding was consistent, each rabbit showing this patternon average, and significant (t = 3.84, P < 0.02). There was nosignificant difference between the patterns of transport in controland sham-operated branches (t = 0.37, P > 0.7). However, valuesfor the occluded branches were significantly different from boththe control (t = 3.81, P < 0.01) and sham-operated (t = 2.38,P < 0.05) branches; on average, these branches showed the reversepattern of transport, uptake being greatest in the downstreamregion.

The data from one mature rabbit were omitted from these analyses, because the results for its sham-operated branches (130± 7.2%, n = 3 branches) were much higher than those obtained inthe other six animals; the occluded branches also gave an unusuallyhigh value. We speculate that the vessels in this animal werehyperreactive and went into spasm during the sham operation (orocclusion). However, even if data from this animal are included,the difference in values between occluded and control branchesremains significant (t = 3.64, P < 0.01), and the lack of differencebetween control and sham-operated branches remains insignificant(t = 1.13, P > 0.2).

Figure 2 shows typical images of the fluorescence emitted by sections through occluded and control branches from a maturerabbit. Tracer concentrations are indicated by the brightnessat each location. In the control branch, concentrations in theaortic intima media are visibly greater upstream of the branchostium than downstream. In the occluded branch, the opposite trendis apparent. Tracer in the adventitia, where concentrations arehigher than in the intima media, was not included in the measurements.

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Fig. 2. Digital images of the fluorescence emitted by sections through a control branch (A, upstream of ostium; B, downstream) and an occluded branch (C, upstream; D, downstream) from a mature animal. Aortic endothelium is at the top and the adventitia (with high levels of fluorescence) is at the bottom of all images. The lumen of the intercostal artery lies between each pair of images. Fluorescence intensity, indicating tracer concentration, is visibly greater in the intima-media upstream of the control branch but downstream of the tied branch. Bar = 100 µm.

The mean of uptake in the upstream and downstream regions combined was significantly greater in control branches from immatureanimals than in those from mature animals (Fig. 3A) (t = 4.10,P < 0.01). Again, this contrasts with previous studies in consciousanimals, where mean uptake in immature rabbits (other than weanlings)was similar to that in mature rabbits (39, 40). There wasno significant difference in mean uptake between treatment groupsfor either the immature (Fig. 3B) or mature (Fig. 3C) rabbits(F = 0.64, P > 0.2 and F = 0.77, P > 0.2, respectively).

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Fig. 3. Mean tracer concentration in regions of aortic wall upstream and downstream of intercostal branches combined, expressed as a percentage of the tracer concentration in plasma. A: tracer concentration was significantly higher near control branches from immature rabbits (n = 5) than near those from mature rabbits (n = 6). In immature (B) and mature (C) rabbits, there was no significant effect of occlusion or sham operation on mean uptake. Bars show means + SE.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The present study is part of continuing attempts to elucidate the mechanisms underlying the two transport patterns seen nearrabbit aortic branches; these patterns may be relevant to thedistribution of human as well as rabbit lesions. Short-term uptakestudies (40) suggest that both transport patterns are determinedby variations in the permeability of the wall to the diffusiveor convective entry of macromolecules. Because both patterns areseen in vessels perfused with a constant flow of physiologicalbuffer (18), neither can depend on interactions between bloodcells and the wall, on the precise composition of plasma, or onthe pulsatility of flow, at least in the short term. Effects ofadding nitric oxide synthase inhibitors to perfused vessels indicatethat the upstream transport pattern, seen in mature rabbits, isnitric oxide dependent but the downstream one, seen in immaturerabbits, is not (18). Here we tested the proposition that theupstream but not the downstream pattern is flowdependent.

Aortic hemodynamics were modified by occluding intercostal arteries. This procedure does not completely stop flow into theside branch because blood is still able to pass out of it intothe vasa vasorum and any other small vessels originating proximalto the occlusion site. We did not attempt to prevent such flowbecause blocking the adventitial blood supply can injure the aorticwall (48) and increase uptake (13). Preliminary experimentsshowed that transport was not increased if the intercostal arterywas occluded at least a few millimeters from the aorta. Flow intothe branch will still have been very substantially reduced bysuch occlusion, and any changes in transport can be attributedto this change in flow provided that there are no effects of shamoperation.

Control branches in the mature rabbits showed the expected upstream pattern of transport. Sham-operated branches gave thesame result, showing that the pattern was not modified by surgicalmanipulation alone. As predicted, the pattern was modified atoccluded branches; in fact, the downstream pattern was seen. Theobserved dependence of the mature transport pattern on flow fitswell with its dependence on nitric oxide because nitric oxidesynthesis is influenced by blood flow, increases in steady flowrate or the introduction of pulsatile flow both increasing itsrelease (35, 38). In the short term, such increases are mediatedby an enhanced activity of nitric oxide synthase (23), whereasin the longer term increased expression of this enzyme may alsobe important (47). The dependence of the mature pattern on flowprobably also accounts for the inverse spatial correlation betweenshear rate and transport seen at the rabbit aortic bifurcationby Berceli et al. (9); we have speculated elsewhere (40)that the distribution of tracer they saw is equivalent to thematurepattern.

The average uptake in upstream and downstream regions combined did not differ between control, sham-operated, and occludedbranches in mature rabbits. Hence, the change in pattern observedaround occluded branches must have resulted from a decrease inuptake upstream of the branch and an increase downstream. Sucha change is hard to explain but is consistent with previous data:reversals in pattern without changes in mean level also occurwith age (39, 40) and, in mature rabbits, with cholesterolfeeding (Sebkhi and Weinberg, unpublished observations) and administrationof the nitric oxide synthase inhibitor N-monomethyl-L-arginine (L-NMMA) (18). We speculate that flow,age, and hypercholesterolemia all have the same striking effectas L-NMMA because they all act via influences on nitric oxidesynthesis or activity. In studies by other groups (3, 32,33, 52), nitric oxide has increased or decreased transportacross blood vessel walls. Although the reasons for this discrepancyare a matter of controversy (26, 31), the occurrence of bothtrends is consistent with the concept that in the mature aortanitric oxide increases transport upstream of branches but decreasesitdownstream.

The fact that occlusion had the same effect as L-NMMA further suggests that it reduced shear, and hence nitric oxide synthesis,in both upstream and downstream regions. That would also explainwhy it had the same effect as the inadvertent exposure to zeroaortic flow (and consequent absence of shear in both regions)in the experiments of Sebkhi and Weinberg (40). This inferenceis supported by two recent numerical studies of flow at the rabbitaortocoeliac branch, which show that shear stresses are elevatedboth upstream and downstream of the branch (10, 12). As flowinto the side branch is reduced, so are the elevations in shearstress (12).

The downstream pattern of transport normally seen in immature rabbits was abolished by some aspect of the protocol used inthe present study. Thus we could not determine the effect of flowon this pattern. However, recent experiments by Lever and Murphy(34) have answered this point: a downstream pattern of uptakewas observed around the aortorenal branch of young rabbits, andthe pattern was not changed 1.5 h after the renal artery was occluded.The only studies appearing to show a causal relation between flowand the downstream pattern of transport of which we are awareare those in which aortas lost the downstream pattern of Evansblue dye (EBD) uptake when exposed to the dye in vitro (8).However, these studies predated the discoveries that depressurizationof arteries causes endothelial damage (4) and that EBD inhibitsthe release or action of nitric oxide (19). Furthermore, therewas an absence of pressure as well as flow invitro.

It is not currently possible to say what does cause the downstream pattern in immature rabbits, but its disappearance duringour experiments suggests that it cannot depend on structural orother long-term influences alone, contrary to previous speculation(40). Differences in conditions between the present experimentand those in which the downstream pattern was detected seem quitesubtle. In particular, the downstream pattern was seen by Leverand Murphy (34), who employed the same tracer and similar techniquesof in situ fixation, tracer detection, and side branch occlusion,although they studied a branch of the abdominal rather than thethoracic aorta. The small difference in protocols between thetwo studies reduces the number of factors that could be of importance.An effect of blood pressure is one possibility because pressuresare lower when the thorax and abdomen are opened, as in the presentstudy, than when the abdomen alone is opened, as in the studyby Lever and Murphy. The reduction could affect the release ofautocoids and the compaction or strain of the wall. It would alsodiminish convective transport. Such transport is likely to dominateat foci of enhanced endothelial permeability, and these occurparticularly frequently downstream of intercostal branch ostiain young rabbits (5, 27). Another possibility is an influenceof anesthetics on the immature but not the mature pattern of transport;although the two studies used the same anesthetics, the presentone employed higher doses. These anesthetics are known to havediverse direct effects on arteries. For example, they are eithervasoactive or can alter the response of endothelial and smoothmuscle cells to vasoactive agents (e.g., 25, 28, 30, 42). Effectsof anesthetics on transport in young but not mature rabbits mightalso explain why mean uptake was greater in the former in thepresent study but not in studies using consciousanimals.

In conclusion, we have demonstrated for the first time a flow dependence of transport around arterial branches. It was theupstream pattern, seen in mature animals, that was found to beflow dependent. The results provide a novel explanation for thespatial correlation between the pattern of flow and the distributionof disease in adult human arteries. The downstream pattern oftransport, seen in immature arteries, appears not to be flow dependent(34); preliminary evidence was obtained that it is abolishedby low blood pressure or by pharmacological effects of anesthetics.Systematic investigation of the conditions where the downstreampattern is and is not detectable will allow the mechanisms underlyingit to be more preciselyestablished.

	ACKNOWLEDGEMENTS

This study was funded by the British HeartFoundation.

	FOOTNOTES

Address for reprint requests and other correspondence: P. D. Weinberg, School of Animal and Microbial Sciences, Univ. of Reading,Whiteknights PO Box 228, Reading RG6 6AJ, UK (E-mail: p.d.weinberg{at}reading.ac.uk).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 30 November 2000; accepted in final form 23 February 2001.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

1. Anitschkow, N. Experimental atherosclerosis in animals. In: Arteriosclerosis, edited by Cowdry EV.. New York: Macmillan, 1933, p. 271-322.

2. Asakura, T, and Karino T. Flow patterns and spatial distribution of atherosclerotic lesions in human coronary arteries. Circ Res 66: 1045-1066, 1990[Abstract/Free Full Text].

3. Baldwin, AL, and Wilson LM. Endothelium increases medial hydraulic conductance of aorta, possibly by release of EDRF. Am J Physiol Heart Circ Physiol 264: H26-H32, 1993[Abstract/Free Full Text].

4. Baldwin, AL, Winlove CP, and Caro CG. Structural response of the rabbit aorta and vena cava to in situ collapse. Artery 10: 420-439, 1982[ISI][Medline].

5. Barakat, AI, Uhthoff PAF, and Colton CK. Topographical mapping of sites of enhanced HRP permeability in the normal rabbit aorta. J Biomech Eng 114: 283-292, 1992[ISI][Medline].

6. Barnes, SE, and Weinberg PD. Contrasting patterns of spontaneous aortic disease in young and old rabbits. Arterioscler Thromb Vasc Biol 18: 300-308, 1998[Abstract/Free Full Text].

7. Barnes, SE, and Weinberg PD. Two patterns of lipid deposition in the cholesterol-fed rabbit. Arterioscler Thromb Vasc Biol 19: 2376-2386, 1999[Abstract/Free Full Text].

8. Bell, FP, Somer JB, and Schwartz CJ. Patterns of aortic Evans blue uptake in vivo and in vitro. Atherosclerosis 16: 369-375, 1972[ISI][Medline].

9. Berceli, SA, Warty VS, Sheppeck RA, Mandarino WA, Tanksale SK, and Borovetz HS. Hemodynamics and low-density lipoprotein metabolism: rates of low-density incorporation and degradation along medial and lateral walls of the rabbit aorto-iliac bifurcation. Arteriosclerosis 10: 688-694, 1990.

10. Buchanan, JR, Kleinstreuer C, Truskey GA, and Lei M. Relation between non-uniform hemodynamics and sites of altered permeability and lesion growth at the rabbit aorto-celiac junction. Atherosclerosis 143: 27-40, 1999[ISI][Medline].

11. Caro, CG, Fitz-Gerald JM, and Schroter RM. Atheroma and arterial wall shear: observation, correlation and proposal of a shear dependent mass transfer mechanism for atherogenesis. Proc R Soc Lond B Biol Sci 177: 109-159, 1971[Medline].

12. Cheer, AY, Dwyer HA, Barakat AI, Sy E, and Bice M. Computational study of the effect of geometric and flow parameters on the steady flow field at the rabbit aorto-celiac bifurcation. Biorheology 35: 415-435, 1998[ISI][Medline].

13. Coleman, PJ, Lever MJ, and Martin JF. Fibrinogen retention in rabbit carotid arteries in vivo following application of a silastic collar (Abstract). J Physiol 475P: P115-P116, 1994.

14. Cornhill, JF, Herderick EE, and Stary HC. Topography of human aortic Sudanophilic lesions. In: Blood Flow in Large Arteries: Application to Atherogenesis and Clinical Medicine (monographs on atherosclerosis, vol 15), edited by Leipsch DW. Basel: Karger, 1990, p. 13-19.

15. Cornhill, JF, and Roach MR. A quantitative study of the localization of atherosclerotic lesions in the rabbit aorta. Atherosclerosis 23: 489-501, 1976[ISI][Medline].

16. Daley, SJ, Herderick EE, Cornhill JF, and Rogers KA. Cholesterol-fed and casein-fed rabbit models of atherosclerosis. Part 1: differing lesion area and volume despite equal plasma cholesterol levels. Arterioscler Thromb 14: 95-104, 1994[Abstract/Free Full Text].

17. Forster, BA, Javed Q, Leake DS, and Weinberg PD. High-resolution mapping of the frequency of lipid deposits in thoracic aortae from cholesterol-fed and heritable hyperlipidaemic rabbits. Atherosclerosis 120: 249-253, 1996[ISI][Medline].

18. Forster, BA, and Weinberg PD. Changes with age in the influence of endogenous nitric oxide on transport properties of the rabbit aortic wall near branches. Arterioscler Thromb Vasc Biol 17: 1361-1368, 1997[Abstract/Free Full Text].

19. Forster, BA, and Weinberg PD. Evans' blue dye abolishes endothelium-dependent relaxation of rabbit aortic rings. Atherosclerosis 129: 129-131, 1997[ISI][Medline].

20. Fothergill, JE. Fluorochromes and their conjugation with proteins. In: Fluorescent Protein Tracing (2nd ed.), edited by Nairn RC.. Edinburgh, UK: Livingstone, 1964, p. 4-33.

21. Friedman, MH, Hutchins GM, Bargeron CB, Deters OJ, and Mark FF. Correlation between intimal thickness and fluid shear in human arteries. Atherosclerosis 39: 425-436, 1981[ISI][Medline].

22. Fry, DL. Certain chemorheologic considerations regarding the blood vascular wall interface with particular reference to coronary artery disease. Circulation 40, Suppl IV: 38-59, 1969.

23. Fulton, D, Gratton JP, McCabe TJ, Fontana J, Fujio Y, Walsh K, Franke TF, Papapetropoulos A, and Sessa WC. Regulation of endothelium-derived nitric oxide production by the protein kinase Akt. Nature 399: 597-601, 1999[Medline].

24. Grottum, P, Svindland A, and Walloe L. Localization of atherosclerotic lesions in the bifurcation of the main left coronary artery. Atherosclerosis 47: 55-62, 1983[ISI][Medline].

25. Hayashi, Y, Minamino N, Isumi Y, Kangawa K, Kuro M, and Matsuo H. Effects of thiopental, ketamine, etomidate, propofol and midazolam on the production of adrenomedullin and endothelin-1 in vascular smooth muscle cells. Res Commun Mol Pathol Pharmacol 103: 325-331, 1999[ISI][Medline].

26. He, P, Liu B, and Curry FE. Effect of nitric oxide synthase inhibitors on basal microvessel permeability and endothelial cell [Ca²⁺]_i. Am J Physiol Heart Circ Physiol 273: H747-H755, 1997[Abstract/Free Full Text].

27. Herrmann, RA, Malinauskas RA, and Truskey GA. Characterization of sites with elevated LDL permeability at intercostal, celiac, and iliac branches of the normal rabbit aorta. Arterioscler Thromb 14: 313-323, 1994[Abstract/Free Full Text].

28. Introna, RPS, Bridges MT, Yodlowski EH, Grover TE, and Pruett JK. Direct effects of fentanyl on canine coronary artery rings. Life Sci 56: 1265-1273, 1995[ISI][Medline].

29. Ivey, J, Roach MR, and Kratky RG. A new probability mapping method to describe the development of atherosclerotic lesions in cholesterol-fed rabbits. Atherosclerosis 115: 73-84, 1995[ISI][Medline].

30. Klockgehter-Radke, AP, Gravemann J, Kettler D, and Hellige G. Influence of opioids on the vascular tone of isolated porcine coronary artery segments. Acta Anaesthesiol Scand 44: 1134-1137, 2000[ISI][Medline].

31. Kubes, P. Nitric oxide affects microvascular permeability in the intact and inflamed vasculature. Microcirculation 2: 235-244, 1995[Medline].

32. Kubes, P, and Granger DN. Nitric oxide modulates microvascular permeability. Am J Physiol Heart Circ Physiol 262: H611-H615, 1992[Abstract/Free Full Text].

33. Kurose, I, Kubes P, Wolf R, Anderson DC, Paulson J, Miyasaka M, and Granger DN. Inhibition of nitric oxide production: mechanisms of vascular albumin leakage. Circ Res 73: 164-171, 1993[Abstract].

34. Murphy, CL. Arterial Mass Transport in Relation to Flow (PhD thesis) Imperial College, 1998.

35. Pohl, U, Herlan K, Huang A, and Bassenge E. EDRF-mediated shear induced dilation opposes myogenic constriction in small rabbit arteries. Am J Physiol Heart Circ Physiol 261: H2016-H2023, 1991[Abstract/Free Full Text].

36. Ravensbergen, J, Ravensbergen JW, Krijger JKB, Hillen B, and Hoogstraten HW. Localizing role of hemodynamics in atherosclerosis in several human vertebrobasilar junction geometries. Arterioscler Thromb Vasc Biol 18: 708-716, 1998[Abstract/Free Full Text].

37. Roach, MR, Cornhill JF, and Fletcher J. A quantitative study of the development of sudanophilic lesions in the aorta of rabbits fed a low-cholesterol diet for up to six months. Atherosclerosis 29: 259-264, 1978[ISI][Medline].

38. Rubanyi, GM, Romero JC, and Vanhoutte PM. Flow-induced release of endothelium-derived relaxing factor. Am J Physiol Heart Circ Physiol 250: H1145-H1149, 1986[Abstract/Free Full Text].

39. Sebkhi, A, and Weinberg PD. Age-related variations in transport properties of the rabbit arterial wall near branches. Atherosclerosis 106: 1-8, 1994[ISI][Medline].

40. Sebkhi, A, and Weinberg PD. Effect of age on the pattern of short-term albumin uptake by the rabbit aortic wall near intercostal branch ostia. Arterioscler Thromb Vasc Biol 16: 317-327, 1996[Abstract/Free Full Text].

41. Schwenke, DC, and Carew TE. Quantification in vivo of increased LDL content and rate of LDL degradation in normal rabbit aorta occurring at sites susceptible to early atherosclerotic lesions. Circ Res 62: 699-710, 1988[Abstract/Free Full Text].

42. Shiraishi, Y, Ohashi M, Kanmura Y, Yamaguchi S, Yoshimura N, and Itoh T. Possible mechanisms underlying the midazolam-induced relaxation of the noradrenaline contraction in rabbit mesenteric resistance artery. Br J Pharmacol 121: 1155-1163, 1997[ISI][Medline].

43. Sinzinger, H, Silberbauer K, and Auerswald W. Quantitative investigation of sudanophilic lesions around the aortic ostia of human fetuses, newborn and children. Blood Vessels 17: 44-52, 1980[ISI][Medline].

44. Staughton, TJ. Transport Properties of the Rabbit Aortic Wall Near Branches: Possible Influences of Nitric Oxide Synthesis and Blood Flow (PhD thesis) University of Reading, 2000.

45. Staughton, TJ, McGillicuddy CJ, and Weinberg PD. Techniques for reducing the interfering effects of autofluorescence in fluorescence microscopy: improved detection of sulphorhodamine B-labelled albumin in arterial tissue. J Microsc 201: 70-76, 2001[ISI][Medline].

46. Svindland, A, and Walloe L. Distribution pattern for sudanophilic plaques in the descending thoracic and proximal abdominal aorta. Atherosclerosis 57: 219-224, 1985[ISI][Medline].

47. Uematsu, M, Ohara Y, Navas JP, Nishida K, Murphy TJ, Alexander RW, Nerem RM, and Harrison DG. Regulation of endothelial cell nitric oxide synthase mRNA expression by shear stress. Am J Physiol Cell Physiol 269: C1371-C1378, 1995[Abstract/Free Full Text].

48. VanderLoo, B, and Martin JF. The adventitia, endothelium and atherosclerosis (Review). Int J Microcirc Clin Exp 17: 280-288, 1997[ISI][Medline].

49. Weinberg, PD. Application of fluorescence densitometry to the study of albumin uptake by the rabbit aortic wall up- and downstream of branches. Atherosclerosis 74: 139-148, 1988[ISI][Medline].

50. Weinberg, PD. Densitometry of photomicrographic negatives for the determination of fluorophores in sections of tissue. Anal Chim Acta 227: 235-241, 1989.

51. Weinberg, PD, Winlove CP, and Parker KH. Measurement of absolute tracer concentrations in tissue sections by using digital imaging fluorescence microscopy: application to the study of plasma protein uptake by the arterial wall. J Microsc 173: 127-141, 1994[ISI][Medline].

52. Yuan, Y, Granger HJ, Zaweija DC, and Chilian WM. Flow modulates coronary venular permeability by a nitric-oxide related mechanism. Am J Physiol Heart Circ Physiol 263: H641-H646, 1992[Abstract/Free Full Text].

53. Zarins, CK, Giddens DP, Bharadvaj BK, Sottiurai VS, Mabon RF, and Glagov S. Carotid bifurcation atherosclerosis; quantitative correlation of plaque localization with flow velocity profiles and wall shear stress. Circ Res 53: 502-514, 1983[Abstract/Free Full Text].

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