Renal Arterial Circulation Research Articles

Thrombophilia: An Amalgam of Never Ending Clinical Manifestations

Abstract Thrombophilia is a blood coagulation disorder, in which blood has an increased tendency to clot, with both arterial and venous localization, being responsible for multiple manifestations: secondary arterial hypertension, stroke, acute pancreatitis or intracardiac masses. We are presenting the case of a 21-year-old male patient, hypertensive, known with thrombophilia, who was sent for the echocardiographic evaluation of an intracardiac mass attached to the posterior leaflet of the mitral valve. The echocardiography and transesophageal echocardiogram showed a hyperechogenic, homogeneous intracardiac mass, attached to the posterior leaflet of the mitral valve, the clinical context and the echocardiographic appearance being suggestive for a thrombus. Given the context of thrombophilia and the hypertension’s characteristics, we considered a secondary form of hypertension, the incriminated mechanism being represented by microthrombosis in the renal arterial circulation. There were two complications in the evolution of the patient: stroke and the recurrent acute pancreatitis, both being explained in the context of thrombophilia. The discharge echocardiography showed a favorable evolution, with a complete resolution of the thrombus under the anticoagulant treatment.

Descending thoracic aorta\u2013abdominal aortic bypass and bilateral renal arterial blood circulation reconstruction are effective in atypical coarctation of the aorta with heart failure: a case report

BackgroundThere are a lot of reports of the renal failure and heart failure due to coarctation of the aorta. However, there are no case reports in which revascularization dramatically improved left ventricular function in patients with progressive decline in left ventricular function. Herein, we present a rare case in which the left ventricular function was dramatically improved by surgical treatment for progressive left ventricular dysfunction due to atypical coarctation of the aorta.Case presentationA 58-year-old man underwent left axillary artery-bilateral femoral artery bypass at another hospital for atypical coarctation of the aorta due to Takayasu’s arteritis. Approximately 10 years later, he was re-hospitalized for heart failure, and the left ventricular ejection fraction gradually decreased to 28%. Computed tomography showed severe calcification and stenosis at the same site from the peripheral thoracic descending aorta to the lower abdominal aorta of the renal artery, and aortography showed delayed bilateral renal artery blood flow. An increase in plasma renin activity was also observed. Despite the administration of multiple antihypertensive drugs, blood pressure control was insufficient. We decided to perform surgical treatment to improve progressive cardiac dysfunction due to increased afterload and activated plasma renin activity. Descending thoracic aorta-abdominal aorta bypass and revascularization of the bilateral renal arteries via the great saphenous vein grafts were performed. Postoperative blood pressure control was improved, and the dose of antihypertensive drugs could be reduced. Plasma renin activity decreased, and transthoracic echocardiography 1.5 years later showed an improvement in contractility with a left ventricular ejection fraction of 58%.ConclusionIn atypical coarctation of the aorta in patients with decreased bilateral renal blood flow, heart failure due to renal hypertension, and progressive decrease in left ventricular contractility, descending thoracic aorta-abdominal aortic bypass and bilateral renal artery recirculation can be extremely effective.

Valvular and/or Non-valvular Aortic Pathology Can Bias the Ultrasonographic Diagnosis of Renal Artery Stenosis

Renal artery stenosis (RAS) has been shown to cause a reduction in the index of maximal systolic acceleration (AImax: the maximal acceleration of flow waveform in early systole divided by the peak systolic velocity) of blood in the renal interlobar arteries, caused by local dampening of the pulse wave. In previous studies, AImax demonstrated diagnostic accuracy in terms of negative predictive value, which is useful for screening, but had a relatively low specificity. We hypothesized that an upstream focal resistance, such as an aortic stenosis or aneurysm, could act in the same way as RAS, thus generating false positives in non-stenotic kidneys. We studied 226 patients who underwent a complete protocol for RAS screening. AImax was 6.2 ± 2.9 s–1 and 13.4 ± 3.5 s–1 (mean ± standard deviation) in stenotic and non-stenotic kidneys, respectively. Diagnostic accuracy of ultrasonography with respect to the benchmark of renal computed tomography or magnetic resonance angiography (significant RAS cutoff ≥50%) resulted in 97% sensitivity, 94% specificity and a negative and positive predictive value of 99% and 55%, respectively. Using logistic regression for unexpectedly low AImax in non-stenotic kidneys (AImax cutoff ≤ 9.0 s–1), aortic pathology, such as aortic valve stenosis or aortic arch dilation (as assessed by echocardiography), was found to be the only significant predictor (Χ2 = 33.8, p < 0.0001) of false positive cases compared with clinical and hemodynamic variables. We concluded that the aortic valvular and non-valvular pathology can act as a proximal resistance that can attenuate the Doppler flowmetric parameters, which explore the flow waveform in the renal parenchymal arterial circulation, thus mimicking the presence of a focal resistance in the peripheral vascular region explored.

AMP-activated protein kinase activation ameliorates eicosanoid dysregulation in high-fat-induced kidney disease in mice

High-fat diet (HFD) causes renal lipotoxicity that is ameliorated with AMP-activated protein kinase (AMPK) activation. Although bioactive eicosanoids increase with HFD and are essential in regulation of renal disease, their role in the inflammatory response to HFD-induced kidney disease and their modulation by AMPK activation remain unexplored. In a mouse model, we explored the effects of HFD on eicosanoid synthesis and the role of AMPK activation in ameliorating these changes. We used targeted lipidomic profiling with quantitative MS to determine PUFA and eicosanoid content in kidneys, urine, and renal arterial and venous circulation. HFD increased phospholipase expression as well as the total and free pro-inflammatory arachidonic acid (AA) and anti-inflammatory DHA in kidneys. Consistent with the parent PUFA levels, the AA- and DHA-derived lipoxygenase (LOX), cytochrome P450, and nonenzymatic degradation (NE) metabolites increased in kidneys with HFD, while EPA-derived LOX and NE metabolites decreased. Conversely, treatment with 5-aminoimidazole-4-carboxamide-1-β-D-furanosyl 5'-monophosphate (AICAR), an AMPK activator, reduced the free AA and DHA content and the DHA-derived metabolites in kidney. Interestingly, kidney and circulating AA, AA metabolites, EPA-derived LOX, and NE metabolites are increased with HFD; whereas, DHA metabolites are increased in kidney in contrast to their decreased circulating levels with HFD. Together, these changes showcase HFD-induced pro- and anti-inflammatory eicosanoid dysregulation and highlight the role of AMPK in correcting HFD-induced dysregulated eicosanoid pathways.

Medical therapy for atherosclerotic renal artery stenosis

Atherosclerotic renal artery stenosis (ARAS) is a common manifestation of generalized atherosclerosis (ATS) and is the most common disorder of the renal arterial circulation [1–3]. Furthermore, ARAS typically occurs in patients at high risk of cardiovascular disease with coexistent vascular disease at nonrenal sites. Indeed, the prevalence of ARAS in a population-based study of people aged 65 years or over is 7%. Prevalence rates for ARAS is 18% in patients with hypertension, 20% in patients with diabetes mellitus and hypertension, 25% in patients with peripheral vascular disease and 33% in those with abdominal aortic aneurysm [4]. Patients affected by ARAS are likely to have more complications and more extensive target-organ damage than patients without ARAS. Indeed, hemodynamically significant ARAS (stenosis >70%) leads to a fall in poststenosis pressure, and if perfusion pressure falls below the limit of renal autoregulation, the glomerular filtration rate decreases. The renin–angiotensin–aldosterone system (RAAS) is activated by the decrease in renal perfusion with increased production of angiotensin II, whose action led to an increase in hemodynamic resistance and systemic blood pressure. Its other nonhemodynamic effects play an important role in structural changes in the ischemic kidney [5]. Recent experimental evidence suggests that ARAS is associated with the activation of intrarenal fibrogenic and inflammatory pathways, oxidative stress and microvascular remodeling, and blocking these mechanisms can improve renal hemodynamics and function. As recent evidence indicates, the relationship between renal artery stenosis and ATS is complex, and mediators implicated in the pathophysiology of atherosclerotic renovascular disease may also contribute to the progression of cardiovascular damage. The therapeutic options to date include revascularization usually by percutaneous transluminal renal angioplasty (PTRA) with or without stenting and/or medical treatment. However, although the angiographic results after PTRA are often remarkable, clinical results are rarely satisfactory regarding hypertension, renal function and survival [6–11]. It is of note that these studies usually concern patients with stable clinical conditions and, in many cases, only moderate ARAS lesions. Recognizing these limitations, the conclusions drawn from these trials are that, compared with best medical management, PTRA with stenting has a very small role in the management of ARAS. Most importantly, there was no difference in the change in renal function and overall cardiovascular mortality. However, these results do not affect patients with ARAS associated to acute kidney injury, flash pulmonary edema or with malignant or treatment-resistant hypertension. Other patients are in great risk for acute kidney injury namely those with critical ARAS and rapid deterioration of renal function on RAAS inhibitors.

“The Seagull Cry”

Duplex ultrasound is widely used to detect vascular dysfunction after kidney transplantation. We describe musical murmurs found in renal allografts. A 29-year-old man with an increase in serum creatinine 1 month after cadaveric kidney transplantation was referred for duplex ultrasound to exclude perfusion dysfunction. Renal arterial and venous circulation was normal. However, during Doppler spectral recording, a loud “seagull cry” was audible (audio file in the online-only Data Supplement). Spectral analysis displayed mirror-image parallel strings and bands of low to moderate frequency (Figure 1A and B). A small arteriovenous fistula, presumably after previous biopsy, was detected as cause of the turbulent flow. Inasmuch as no bleeding complication or pseudoaneurysm formation occurred, a conservative strategy was chosen, and follow-up with duplex ultrasound was recommended. Figure 1. A and B, Renal transplant with …

Contrast angiography of the rat renal microcirculation in vivo using synchrotron radiation

We have developed a new method for contrast microangiography of the rat renal circulation using synchrotron radiation. The method was applied to determine responses of the renal arterial vasculature to angiotensin II and electrical stimulation of the renal nerves (RNS). Iodinated contrast agent was administered directly into the renal artery of pentobarbital-anesthetized rats before and during 1) intravenous infusion of angiotensin II (1.6 microg x kg(-1) x min(-1)) or 2) its vehicle, or 3) RNS at 2 Hz. Images were obtained at 30 Hz, before and during these treatments, and vascular caliber was determined by use of a newly developed algorithm described herein. Up to four levels of branching could be observed simultaneously along the arterial tree, comprising vessels with resting diameter of 28-400 microm. Vessel diameter was not significantly altered by vehicle infusion (+3.1 +/- 3.5% change) but was significantly reduced by angiotensin II (-24.3 +/- 3.4%) and RNS (-17.1 +/- 3.8%). Angiotensin II-induced vasoconstriction was independent of vessel size, but RNS-induced vasoconstriction was greatest in vessels with a resting caliber of 100-200 microm and least in vessels with a resting caliber 40-100 microm. In conclusion, the method we describe herein provides a new approach for assessing responses of the renal arterial circulation to vasoactive factors along several orders of branching.

Theodore Caldwell Janeway, clinician and pathophysiologist.

Clinical CardiologyVolume 30, Issue 3 p. 146-148 Profiles in CardiologyFree Access Theodore Caldwell Janeway, clinician and pathophysiologist Jordan M. Prutkin M.D., M.H.S., Corresponding Author Jordan M. Prutkin M.D., M.H.S. [email protected] Department of Medicine, Division of Cardiology, The University of Washington, Seattle, Washington, USAUniversity of Washington Division of Cardiology Box 356422 Seattle, WA 98195, USASearch for more papers by this author Jordan M. Prutkin M.D., M.H.S., Corresponding Author Jordan M. Prutkin M.D., M.H.S. [email protected] Department of Medicine, Division of Cardiology, The University of Washington, Seattle, Washington, USAUniversity of Washington Division of Cardiology Box 356422 Seattle, WA 98195, USASearch for more papers by this author First published: 26 March 2007 https://doi.org/10.1002/clc.5Citations: 1AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL No abstract is available for this article. REFERENCES 1 Memorial meeting to Dr. Theodore Caldwell Janeway. Bull Johns Hopkins Hosp 1918; 29: 142– 148. 2 Kelly HA: Theodore Caldwell Janeway. American Medical Biographies (Eds. HA Kelly, WL Burrage) pp. 614– 615. Baltimore: The Normal Remington Company, 1920. 3 Dr. Edward Gamaliel Janeway. The Elizabethtown Post, February 16, 1911; Vol. 58, Number 31. 4 Longcope WT: Theodore Caldwell Janeway. In History of the Interurban Clinical Club, 1905–1937 (Ed. D Riesman). Chicago: John C. Winston Company, 1937. 5 Crenner CW: Introduction of the blood pressure cuff into U.S. medical practice: Technology and skilled practice. Ann Intern Med 1998; 128: 488– 493. 6 Janeway TC: The Clinical Study of Blood-Pressure: A Guide to the Use of the Sphygmomanometer in Medical, Surgical, and Obstetrical Practice, with a Summary of the Experimental and Clinical Facts Relating to the Blood-Pressure in Health and in Disease. New York: D. Appleton and Company, 1904; (a) p. 173; (b) p. 91– 92. 7 Janeway TC: The diagnostic significance of persistent high arterial pressure. Am J Med Sci 1906; 131: 772– 778. 8 Janeway TC: Some observations on the estimation of blood pressure in man. NY Univ Bull Med Sci 1901; 1: 105– 110. 9 Korotkoff NC: On methods of studying blood pressure. Izvestiia oennomedistinskite Akademiia 1905; 11: 365. 10 Obituary. Theodore C. Janeway. Lancet. 1918; 191(4924): 80. 11 Janeway TC: A study of the causes of death in one hundred patients with high blood-pressure. J Am Med Assoc 1912; 59: 2106. 12 Janeway TC: The pathological physiology of chronic arterial hypertension and its treatment. Am J Med Sci 1907; 83: 50– 59. 13 Janeway TC: Note on the blood-pressure changes following reduction of the renal arterial circulation. Proc Soc Exp Biol Med 1909; 6: 109– 111. 14 Goldblatt H, Lynch J, Hanzal RF, Summerville WW: Studies on experimental hypertension: I. The production of persistent elevation of systolic blood pressure by means of renal ischemia. J Exp Med 1934; 59: 347– 379. 15 Lamb AR: The Presbyterian Hospital and the Columbia-Presbyterian Medical Center, 1868–1943, p. 139. New York: Columbia University Press, 1955. 16 Janeway TC: Important contributions to clinical medicine during the past thirty years from the study of human blood pressures. Bull Johns Hopkins Hosp 1915; 26: 341– 350. 17 Fye WB: The origin of the full-time system: Implications for clinical research. J Am Med Assoc 1991; 265: 1555– 1562. Citing Literature Volume30, Issue3March 2007Pages 146-148 ReferencesRelatedInformation

Platelet-activating factor is a renal vasodilator in the anesthetized rat

In view of the potent vasoactive properties of platelet-activating factor (PAF), we investigated the renal hemodynamic effects of this lipid. C16-PAF (0.5-10 ng/kg) given as a bolus into the renal arterial circulation of pentobarbital sodium-anesthetized male Wistar rats produced a dose-dependent increase in renal blood flow (6-15%), before causing systemic hypotension. The PAF-induced renal vasodilation and systemic hypotension was independent of renal innervation, unaltered by eicosanoid synthesis inhibition with indomethacin or dexamethasone, unchanged by the nonselective dopamine-receptor antagonist haloperidol, but was abolished by the PAF-receptor antagonist, L-659,989. Non-hypotensive intrarenal PAF infusion at 0.5 ng.min-1.kg-1 caused an increase in renal blood flow. Thus PAF can cause renal vasodilation in the rat kidney that is PAF-receptor mediated and does not involve the sympathetic nervous system or the release of vasodilatory arachidonic acid metabolites or dopamine.

Epidermal growth factor accelerates functional recovery from ischaemic acute tubular necrosis in the rat: Role of the epidermal growth factor receptor

1. Severe, ischaemic, acute tubular necrosis was induced in rats by bilateral occlusion of the renal arteries. The experimental group received exogenous epidermal growth factor infused directly into the renal arterial circulation. Serum creatinine concentration was measured daily for 1 week. Epidermal growth factor receptor binding was measured by autoradiography of whole kidney sections. Renal cell proliferation was measured by incorporation of [3H]thymidine into DNA. 2. Serum creatinine concentration increased after acute tubular necrosis with a peak at 48 h and remained elevated above control levels after 7 days. Binding of radiolabelled epidermal growth factor occurred in all regions of the kidney 48 h after ischaemia. Treatment with exogenous epidermal growth factor attenuated the rise in serum creatinine by 4 days after acute tubular necrosis and after 7 days serum creatinine was lower than in animals that did not receive epidermal growth factor. Infusion of epidermal growth factor also increased renal DNA synthesis. 3. The increase in epidermal growth factor binding in the kidney after acute tubular necrosis and the attenuation of the increase in serum creatinine concentration by administration of exogenous epidermal growth factor, suggest a role for epidermal growth factor in recovery from ischaemic damage. The increase in DNA synthesis in response to epidermal growth factor indicates that its effect may be due, at least in part, to accelerated tubular cell proliferation.

An experimental model of chronic renal disease in dogs by infusion of microspheres into the renal arterial circulation

SUMMARY The feasibility of renal arterial infusion of nonbiodegradable microspheres as a model of chronic renal disease in dogs was evaluated. Resin-coated, styrene-divinyl benzene copolymer microspheres were infused into the kidneys of healthy adult Beagles by direct injections of both renal arteries in a single surgical procedure. Injections of 25-μm diameter microspheres had minimal effect on either the clinical status or serum values of the dogs. Histologic examination revealed the majority of the microspheres lodged within the capillary beds of the glomeruli, and little change to the kidneys. However, injections of 50-μm diameter microspheres caused significant increases in serum concentrations of urea nitrogen and creatinine. Histologically, the larger microspheres obstructed afferent arterioles and small arteries, which caused diffuse glomerular necrosis and nephron damage. With doses ranging from 1 to 3 million microspheres/dog, a correlation between the quantity of microspheres injected and severity of renal damage was observed. The optimal dose for producing a model of moderate renal disease was determined to be 1.8 million microspheres/dog (0.9 million microspheres/kidney). During long-term studies, microsphere-injected dogs fed a moderately restricted protein ration remained relatively azotemic, compared with control dogs on the identical ration. During the 5-month postsurgical period, the serum urea nitrogen concentration averaged 18.41 ± 1.59 mg/dl (mean ± SE) for the microsphere-injected dogs vs 9.31 ± 0.38 for the control dogs (P &lt; 0.001). Similarly, the mean serum creatinine value was significantly higher (P = 0.020) for the microsphere-injected dogs, compared with the controls (1.28 ± 0.12 mg/dl vs 0.94 ± 0.03). In addition, the difference in mean endogenous creatinine clearance rates was statistically significant (microsphere-injected 1.02 ± 0.05 ml/min/kg, vs control 1.53 ± 0.06, P &lt; 0.001).

Use of hydrogen gas clearance for measurement of renal circulation: An experimental study

Inhalation of hydrogen gas and its immediate diffusion into the blood permits an accurate and reproducible determination of its clearance through a fine platinum electrode inserted in the renal cortex. The oxidation of molecular hydrogen at the surface of the electrode generates a current which is then easily recorded. Such recordings accurately reflect regional arterial circulation. Experiments have been done in rats to determine regional renal cortical arterial circulation in (1) normal conditions, (2) immediately following unilateral, complete ureteral obstruction, and (3) following a twenty-four-hour ureteral obstruction. Hundreds of simple and reproducible recordings were obtained. Although acute obstruction does not immediately affect cortical blood supply, a twenty-four-hour obstruction was accompanied by a 31.3 per cent reduction in circulation.

The effects of aortic infusion of ethylene oxide on renal function in the rat

The effect of ethylene oxide on kidney function was investigated in the intact rat. A method was developed for introducing aqueous solutions of ethylene oxide into the abdominal aorta above the renal arteries without opening the abdominal cavity; 40 ± 6% (SE) of an infusion introduced into the aorta above the renal arteries was estimated to enter directly into the renal arterial circulation. It was found that 0.1 and 1% ethylene oxide solutions infused above the renal arteries caused significant decreases in glomerular filtration rate (33 ± 3% and 29 ± 4%, respectively) and similar decreases in effective renal blood flow with no change in mean arterial pressure. Infusion of a higher concentration of ethylene oxide (10%) resulted in death of the animal. The calculated concentrations of ethylene oxide in renal arterial blood which caused significant decreases in glomerular filtration rate were between 0.45 and 4.5 μg/ml. Ethylene oxide had no effect on renal Na + or K + reabsorption. The effects of ethylene oxide are therefore principally on the renal vasculature and not on tubular function.

Influence of adrenergic drugs on prostaglandin E release from the dog kidney,.

SummaryPGE levels in renal venous blood of in situ perfused dog kidneys were measured by radioimmunoassay. A basal efflux of PGE was found and a significant increase in the levels was elicited by injection of norepinephrine or epinephrine into the renal arterial circulation. Isoproterenol had a small but possibly unimportant effect, α-adrenergic blockade with phen-oxybenzamine did not inhibit the PGE increase but did block the pressor response to norepinephrine and epinephrine. Thus, PGE release in these experiments was apparently not dependent on total renal blood flow or perfusion pressure. Acetylsalicylic acid and indomethacin blocked the PGE response to norepinephrine and epinephrine but did not affect the pressor response suggesting that PGE synthesis rather than the release of stored PGE occurs when α-adrenergic drugs are administered. Our findings lend support to the suggestion that PGE may play a physiologic role in the intrarenal vascular adjustments.

Distribution of Renal Arterial Circulation in the Dog

Distribution of Renal Arterial Circulation in the Dog

The cause of essential hypertension.

THE CAUSE OF ESSENTIAL HYPERTENSION MILTON MENDLOWITZ, M.D., STANLEY GITLOW, M.D., and NOSRAT NAFTCHI, M.S.* When the blood-pressure cuffwas discovered about sixty years ago, it became apparent to many workers in Europe and in this country (1-4) thathigh blood pressure was a common affliction ofthe adulthuman being which not infrequently caused his death, either directly or indirectly. It could cause a blood vessel to burst in the brain, produce progressive deterioration ofthe kidneys, cause the heart to fail, or accelerate the process of arteriosclerosis. Arteriosclerosis, in turn, could lead to vascular occlusions , especially in the heart, brain, or extremities, and so hasten the end. Through the years many causes have been propounded for this disease, including psychic disturbance (5), endocrine imbalance (6), hereditary predisposition (7), neurovascular dysfunction (8) (initiated, for example, by the carotid sinus), renal malfunction (9), etc. When the smoke ofcontroversy had cleared a little, some hypertensive diseases, such as those associated with adrenal medullary tumors (10) and adrenal cortical tumors or hyperplasia (11) and those associated with such renal diseases as acute and chronic glomerulonephritis, chronic pyelonephritis, and polycystic kidneys, were distinguished from primary hypertension itself, although even today this distinction cannot always be made clinically in the individual patient. When neurogenic hypertension was produced in the laboratory by section of the aortic depressor and carotid sinus nerves of dogs (12) and when renal hypertension was produced by interfering with the canine renal arterial circulation (13), opposite schools ofthought developed. One identified primary hypertension as essentially renal, the other believed it to be essentially nervous in origin. However, tissue examined directly by biopsy or at autopsy revealed no renal abnormality early in the course of * Department ofMedicine, Mount Sinai Hospital, New York. This work has been aided by grants from the American Heart Association and the National Heart Institute (H-Ï164). 354 M. Mendlowitz, S. Gitlow, and N. Naftchi · Essential Hypertension Perspectives in Biology and Medicine · Spring 1959 human primary or essential hypertension (14). Even if the hypertension were attributed to such renal ischemia, some mechanism would have to be invoked to account for the initiation of the localized ischemia. Moreover , the nature of the hypertension produced by renal ischemia was elusive to the investigator. Pressor substances isolated fromthekidneywere presumed responsible for this renal hypertension (15, 16). Then it was difficult to explain the occurrence ofhypertension when both kidneys were ablated (17), so electrolyte retention or a substance elaborated by normal kidneys which prevented hypertension was postulated. It was also suggested that retention of water and electrolytes was not generalized but was confined to small blood vessels, especially arterioles (18, 19), and that the subsequent development ofarteriolar sclerosis provided the final impetus toward increased peripheral resistance. Thus, it was customary about ten or fifteen years ago to say that the cause ofessential hypertension was unknown. Now some workers in the field believe that primary hypertension has many causes—sometimes renal, sometimes endocrine, sometimes hypothalamic, sometimes a combination, etc. Ifthat state ofmind is reassuring, several observations are not. For example, it has become quite clear that primary hypertension is hereditary (7, 20), although how the predisposition is implemented is unclear. Is it via the kidneys in some cases, the blood vessels in some, the nervous system in some, and the endocrine glands in still others? This seems unlikely from what is known ofhereditary disease. Also, sympathectomy and therapy with drugs directed at neurogenic vasoconstriction have been so dramatically effective in many cases that it seems as though increased neurogenic vasoconstriction must be involved in primary hypertension. The fact that equivalent drug dosage has a greater depressor effect in hypertensive than in normotensive subjects (21) supports this feeling. On the other hand, salt depletion by the low-sodium diet (19) and presumably by such diuretics as chlorothiazide (22, 23) seems to act either by increasing the caliber ofblood vessels or by decreasing blood flow, as measured in both instances after inhibition ofsympathetic neural vasoconstriction. Also, some recent evidence suggests that chlorothiazide decreases vascular sensitivity to norepinephrine (24). It is disturbing, however, that ganglion-blocking drugs, particularly, decrease blood pressure not only by inhibiting neurogenic arteriolar vasoconstriction but also by decreasing cardiac output, possibly because...

Note on the blood-pressure changes following reduction of the renal arterial circulation

Of the various workers who have studied the effects of reduction of kidney substance, only Passler and Heineke record systematic blood-pressure observations. They were able to make direct measurements in the femoral on five dogs before and after operation, and reported a rise in pressure in all, the smallest increase being 15 mm., the greatest 29 mm., and the average 21.5 mm. These figures are based on the comparison of single readings before operation with one or more after operation, and are open to the objections I have previously urged. Because of the small number of reported observations in this field, I hope to be pardoned for presenting my still very incomplete studies at this time, in order that I may demonstrate one of the animals now living with reduced kidney substance and hypertension.I have made blood-pressure readings, by the rough method previously described, on twenty-three dogs, over a period of fifteen months. As a guide to normal readings in the dog I have figures from twelve dogs that ...