Transfer of nitric oxide by blood from upstream to downstream resistance vessels causes microvascular dilation

The discovery that hemoglobin, albumin, and glutathione carry and release nitric oxide (NO) may have consequences for movement of NO by blood within microvessels. We hypothesize that NO in plasma or bound to proteins likely survives to downstream locations. To confirm this hypothesis, there must be a finite NO concentration ([NO]) in arteriolar blood, and upstream resistance vessels must be able to increase the vessel wall [NO] of downstream arterioles. Arteriolar blood NO was measured with NO-sensitive microelectrodes, and vessel wall [NO] was consistently 25-40% higher than blood [NO]. Localized suppression of NO production in large arterioles over 500-1,000 microm with L-nitroarginine reduced the [NO] approximately 40%, indicating as much as 60% of the wall NO was from blood transfer. Flow in mesenteric arteries was elevated by occlusion of adjacent arteries to induce a flow-mediated increase in arterial NO production. Both arterial wall and downstream arteriolar [NO] increased and the arterioles dilated as the blood [NO] was increased. To study receptor-mediated NO generation, bradykinin was locally applied to upstream large arterioles and NO measured there and in downstream arterioles. At both sites, [NO] increased and both sets of vessels dilated. When isoproterenol was applied to the upstream vessels, they dilated, but neither the [NO] or diameter downstream arterioles increased. These observations indicate that NO can move in blood from upstream to downstream resistance vessels. This mechanism allows larger vessels that generate large [NO] to influence vascular tone in downstream vessels in response to both flow and receptor stimuli.

Reduced perivascular PO2 increases nitric oxide release from endothelial cells

Many studies have suggested that endothelial cells can act as "oxygen sensors" to large reductions in oxygen availability by increasing nitric oxide (NO) production. This study determined whether small reductions in oxygen availability enhanced NO production from in vivo intestinal arterioles, venules, and parenchymal cells. In vivo measurements of perivascular NO concentration ([NO]) were made with NO-sensitive microelectrodes during normoxic and reduced oxygen availability. During normoxia, intestinal first-order arteriolar [NO] was 397 +/- 26 nM (n = 5), paired venular [NO] was 298 +/- 34 nM (n = 5), and parenchymal cell [NO] was 138 +/- 36 nM (n = 3). During reduced oxygen availability, arteriolar and venular [NO] significantly increased to 695 +/- 79 nM (n = 5) and 534 +/- 66 nM (n = 5), respectively, whereas parenchymal [NO] remained unchanged at 144 +/- 34 nM (n = 4). During reduced oxygenation, arteriolar and venular diameters increased by 15 +/- 3% and 14 +/- 5%, respectively: NG-nitro-L-arginine methyl ester strongly suppressed the dilation to lower periarteriolar Po2. Micropipette injection of a CO2 embolus into arterioles significantly attenuated arteriolar dilation and suppressed NO release in response to reduced oxygen availability. These results indicated that in rat intestine, reduced oxygen availability increased both arteriolar and venular NO and that the main site of NO release under these conditions was from endothelial cells.

Obesity lowers hyperglycemic threshold for impaired in vivo endothelial nitric oxide function

Obesity is a risk for type II diabetes mellitus and increased vascular resistance. Disturbances of nitric oxide (NO) physiology occur in both obese animals and humans. In obese Zucker rats, we determined whether a protein kinase C-beta II (PKC-beta II) mechanism may lower the resting NO concentration ([NO]) and predispose endothelial NO abnormalities at lower glucose concentrations than occur in lean rats. NO was measured with microelectrodes touching in vivo intestinal arterioles. At rest, the [NO] in obese Zucker rats was 60 nm less than normal or about a 15% decline. After local blockade of PKC-beta II with LY-333531, the [NO] increased approximately 90 nm in obese rats but did not change in lean rats. In lean rats, administration of 300 mg/dl D-glucose for 45 min depressed endothelium-dependent dilation; only 200 mg/dl was required in obese animals. These various observations indicate that resting [NO] is depressed in obese rats by a PKC-beta II mechanism and the hyperglycemic threshold for endothelial NO suppression is reduced to 200 mg/dl D-glucose.

Arteriolar nitric oxide concentration is decreased during hyperglycemia-induced betaII PKC activation

betaII protein kinase C (betaPKC) is activated during acute and chronic hyperglycemia and may alter endothelial cell function. We determined whether blockade of betaPKC protected in vivo endothelial formation of NO, as measured with NO-sensitive microelectrodes in the rat intestinal vasculature. NaCl hyperosmolarity, a specific endothelial stimulus to increase NO formation, caused approximately 20% arteriolar vasodilation and approximately 30% increase in NO concentration ([NO]). After topical 300 mg/dl hyperglycemia for 45 min, both responses were all but abolished. In comparison, pretreatment with LY-333531, a specific betaPKC inhibitor, maintained vasodilation and [NO] responses to NaCl hyperosmolarity after hyperglycemia. The betaPKC inhibitor alone had no significant effects on resting diameter or [NO] or their responses to NaCl hyperosmolarity. In separate rats, after topical hyperglycemia had suppressed dilation to ACh, LY-333531 restored approximately 70% of the dilatory response. These data demonstrated that activation of betaPKC during acute hyperglycemia depressed in vivo endothelial formation of NO at rest and during stimulation. This abnormality can be minimized by inhibition of betaPKC before hyperglycemia and can be substantially reversed by PKC inhibition after hyperglycemia-induced abnormalities have occurred.

Dependence of intestinal arteriolar regulation on flow-mediated nitric oxide formation

Our hypothesis was that a large fraction of resting nitric oxide (NO) formation is driven by flow-mediated mechanisms in the intestinal microvasculature of the rat. NO-sensitive microelectrodes measured the in vivo perivascular NO concentration ([NO]). Flow was increased by forcing the arterioles to perfuse additional nearby arterioles; flow was decreased by lowering the mucosal metabolic rate by reducing sodium absorption. Resting periarteriolar [NO] of large arterioles (first order; 1A) and intermediate-sized arterioles (second order; 2A) was 337 +/- 20 and 318 +/- 21 nM. The resting [NO] was higher than the dissociation constant for the NO-guanylate cyclase reaction of vascular smooth muscle; therefore, resting [NO] should be a potent dilatory signal at rest. Over flow velocity and shear rate ranges of approximately 40-180% of control, periarteriolar [NO] changed 5-8% for each 10% change in flow velocity and shear rate. The relationship of [NO] to flow velocity and shear rate demonstrated that 60-80% of resting [NO] depended on flow-mediated mechanisms. Therefore, moment-to-moment regulation of [NO] at rest is an ongoing process that is highly dependent on flow-dependent mechanisms.

Observation of the 11N ground state

The ground state of the proton-rich, unbound nucleus 11N was observed, together with six excited states using the multinucleon transfer reaction 10B(14N,13B)11N at 30A MeV incident energy at Grand Accelerateur National d'Ions Lourds. Levels of 11N are observed as well defined resonances in the spectrum of the 13B ejectiles. They are localized at 1.63(5), 2.16(5), 3.06(8), 3.61(5), 4.33(5), 5.98(10), and 6.54(10) MeV above the 10C+p threshold. The ground-state resonance has a mass excess of 24.618(50) MeV; the experimental width is smaller than theoretical predictions.

Acute hyperglycemia depresses arteriolar NO formation in skeletal muscle

In the rat intestinal and cerebral microvasculatures, acute D-glucose hyperglycemia suppresses endothelium-dependent dilation to ACh without affecting endothelium-independent dilation to nitroprusside. This study determined whether acute hyperglycemia suppressed arteriolar wall nitric oxide concentration ([NO]) at rest or during ACh stimulation and inhibited nitroprusside-, ACh- or contraction-induced dilation of rat spinotrapezius arterioles. Vascular responses were measured before and after 1 h of topical 300 mg/100 ml D-glucose; arteriolar [NO] was measured with NO-sensitive microelectrodes. Arteriolar dilation to ACh was not significantly altered after superfusion of 300 mg/100 ml D-glucose. However, after hyperglycemia, arteriolar [NO] was not increased by ACh, compared with a 300 nM increase attained during normoglycemia. Arteriolar dilation to submaximal nitroprusside and muscle contractions was enhanced by hyperglycemia. These results indicated that in the rat spinotrapezius muscle, acute hyperglycemia suppressed arteriolar NO production while simultaneously augmenting vascular smooth muscle responsiveness to nitroprusside, presumably through cGMP-mediated mechanisms. In effect, this may have allowed ACh- and muscle contraction-induced vasodilation to be maintained during hyperglycemia despite an impaired NO system.

Integration of intestinal structure, function, and microvascular regulation

Without an increase in blood flow to provide additional oxygen, intestinal absorption of nutrients cannot proceed. Studies of the intestinal microvascular structure and distribution of resistance indicated that most of the microvascular regulation must occur outside the mucosal tissues. This requires a communication system from the mucosa to resistance vessels unlike that of any other organ. The various mechanisms involved and their communication from mucosal to arteriolar cells has required an integrated study of intestinal structure, physiology, and microvascular regulation. The results of this analysis using diverse approaches have revealed some of the major physical and cellular mechanisms that couple intestinal absorption and microvascular function.

Mechanism of increased vessel wall nitric oxide concentrations during intestinal absorption

Vasoactive compounds, including nitric oxide (NO) and hypertonic sodium, may diffuse from venous endothelial cells and blood to the arterial wall during intestinal absorption. This hypothesis was tested by measuring the perivascular NO concentration ([NO]) for paired small arteries and veins with NO-sensitive microelectrodes. Resting arterial and venous wall concentrations for nine vessel pairs (5 rats) were 353 +/- 28 and 401 +/- 48 (SE) nM. During mucosal absorption of 100 and 300 mg/dl glucose, the artery dilated 12 +/- 1.5 and 17 +/- 2%, [NO] increased to 540 +/- 68 and 550 +/- 49 nM, and venous wall [NO] increased to 557 +/- 60 and 633 +/- 70 nM. During venous occlusion to block diffusion of materials from venous blood to the artery wall, the arterial and venous [NO] decreased by 70-80%, and one-half of the arterial dilation subsided. Superfusion with 320 and 360 mosmol/l hypertonic sodium medium to simulate the sodium hyperosmolarity during mucosal absorption of glucose increased the arterial [NO] by 20-30 and 40-50%; 360 mosmol/l saline made hypertonic with mannitol did not significantly increase the [NO]. Although venous to arterial diffusion of NO occurred, the increased arterial [NO] during mucosal glucose absorption was primarily generated by the arterial wall in response to materials that diffused from venous blood, such as hypertonic sodium.

Time- and order-dependent changes in functional and NO-mediated dilation during exercise training

Arterial vessel responses to sodium nitroprusside (SNP) and acetylcholine (ACh) were measured in the spinotrapezius muscle of sedentary (Sed) and treadmill-trained (Tr) rats to determine whether these endothelium-dependent (ACh) and -independent (SNP) mechanisms contribute to the training-induced increase in functional vasodilation previously observed. Control and maximal vessel diameters were similar between Sed and Tr. After 8 wk of training, functional dilation (2-, 4-, and 8-Hz contractions) was enhanced in all orders of vessels studied [terminal feed artery (FA), largest arterioles (1A), and intermediate-sized arterioles (2A)], but responses to SNP were increased only in FA. Responses to ACh were not significantly increased in any vessel order. After 16 wk of training, functional dilation had regressed in Tr such that only the FA response to 4 Hz was significantly elevated relative to Sed. However, the FA and 1A responses to SNP were significantly greater in Tr than in Sed, as were the 1A and 2A responses to ACh. These results show a dissociation of functional dilation and SNP- or ACh-mediated responses, as well as age-dependent interactions, a time-dependent progression, and vessel order specificity in the adaptations to training.

Non-insulin-dependent diabetes and hyperglycemia impair rat intestinal flow-mediated regulation

Release of nitric oxide from small arteries and larger arterioles of the intestine maintains their dilation and thereby supports mucosal blood flow. This flow-dependent mechanism can be studied by isosmotic replacement of sodium chloride with mannitol over the mucosa to lower mucosal metabolism and blood flow requirements. We tested the hypothesis that flow-mediated regulation is impaired in the non-insulin-dependent Zucker fatty diabetic (ZFD) male rats because of their marginally impaired endothelium-dependent dilation. Furthermore, we determined whether the depressed acetylcholine dilation associated with acute hyperglycemia in normoglycemic Zucker (NZ) rats also impairs flow-mediated regulation. When mannitol replaced sodium chloride over the villi, intestinal blood flow decreased significantly (P < 0.05) less in ZFD (80.9 +/- 6.8% of control) than NZ rats (40.9 +/- 6.4% of control). After 300 mg/dl hyperglycemia for 30 min, normal arterioles had impaired responses to acetylcholine and the resting blood flow and oxygen consumption were suppressed about 60%, which indicate the importance of basal nitric oxide release for intestinal vascular support of metabolism. The evidence of impaired flow-mediated dilation in ZFD and decreased resting blood flow after hyperglycemia in NZ rats demonstrated that both acute and chronic hyperglycemia disturb endothelial regulation of the intestinal vasculature.

Aldose reductase and IGF-I gene expression in aortic and arteriolar smooth muscle during hypo- and hyperinsulinemic diabetes

Two genes whose expression is likely to be altered during diabetes mellitus are aldose reductase (AD) and insulin-like growth factor-I (IGF-I). We proposed that gene expression of AD is increased in vascular smooth muscle during diabetes mellitus due to hyperglycemia, while IGF-I expression is decreased in insulin-deficient diabetes and elevated in insulin-resistant diabetes. The mRNA for both was measured in the renal glomerulus, in the vascular smooth muscle of large arterioles from the brain, kidney, and small intestine, and in the aorta of hypoinsulinemic streptozotocin (STZ)-treated rats and hyperinsulinemic Zucker diabetic fatty (ZDF) rats. Quantitative in situ hybridization was used to determine variations in expression. Expression of the AD gene was unchanged in STZ and ZDF rats, except for a decrease of about 50% in glomeruli and renal smooth muscle of STZ diabetic rats. Expression of IGF-I generally decreased in vascular smooth muscle of insulin-depleted STZ diabetic rats, but was normal in hyperinsulinemic ZDF rats. The data indicate that decreased expression of the AD gene is a specific problem in renal vascular smooth muscle and glomeruli in the insulin-depleted STZ model of diabetes. The expression of the IGF-I gene in vascular muscle was decreased in hypoinsulinemic diabetic animals, but did not increase in hyperinsulinemic diabetic rats.

Intestinal absorption of sodium and nitric oxide-dependent vasodilation interact to dominate resting vascular resistance

The villi of the small intestine maintain a hypertonic interstitium at all times, and the submucosal glands constantly secrete ions and accompanying water into the lumen. Generation of the 400- to 600-mOsm interstitial fluid in the villus and secretion by glands may require a large expenditure of energy and, consequently, have major effects on intestinal vascular regulation to supply oxygen and nutrients. Blood flow and oxygen consumption were measured in the ileum of anesthetized rats during natural resting conditions with physiological sodium chloride in the bathing fluid and during isosmotic replacement of sodium chloride with mannitol. Microvascular pressures and blood flow were used to determine the changes in resistance of the major arterioles and the terminal vasculature. When mannitol replaced sodium chloride in contact with the villi, intestinal blood flow decreased to 58.6 +/- 2.8% of control, and oxygen consumption was 54.2 +/- 3.4% of control. Resistance of the major arterioles increased 101.7 +/- 9.9%, and that of the terminal vasculature increased 40.4 +/- 6.2%. The increased resistance appeared to be caused by suppression of a nitric oxide mechanism. Local application of 10(-4) mol/L NG-nitro-L-arginine methyl ester caused about the same reduction in flow and increases in regional vascular resistance as during replacement of sodium but did not alter the oxygen consumption. These data indicate that about half of the intestinal metabolic rate during natural resting conditions is devoted to sodium secretion/absorption. Large resistance vessels are dilated to maintain a high blood flow through release of nitric oxide. We propose that dilation of the terminal vasculature in the metabolically active tissues increased flow velocity sufficiently in the major resistance vessels to cause a flow-mediated release of nitric oxide.

Resting oxygenation of rat and rabbit intestine: arteriolar and capillary contributions

Counter-current exchange of oxygen may occur between inflow and outflow microvessels of the small intestine and greatly influence the dominant sites of tissue oxygenation. To determine the location and magnitude of potential exchange, percent saturation of hemoglobin with oxygen (%SHb) was measured in microvessels throughout the intestine of rats and rabbits. Oxygen losses from systemic arterial blood through large and intermediate arterioles (second order, 2A) was 5-7%SHb in both species, and there was no evidence of an increase in percent saturation along intermediate and large venules. A larger loss of oxygen from arterioles and an increase in venous saturation would be evident if significant arteriolar to venular counter-current exchange of oxygen occurred in the submucosa. From 2A to the villus tip, arteriolar saturation decreased approximately 10%SHb in rabbits and approximately 15%SHb in rats; the villus tip percent saturation was 72.9 +/- 3.9%SHb in rabbits and 69.9 +/- 2.9%SHb in rats. An additional decrease of 5%SHb in rabbits and 15%SHb in rats occurred across the villus capillaries and smallest venules. Although the total reduction in percent saturation across the villi was different between the two species, 70-90% of the total arteriovenous oxygen losses occurred in the capillaries and small arterioles of the villi. We found no evidence of counter-current exchange of oxygen in villi or any other vascular region. Rather, as appears to occur in most organs, small arterioles in conjunction with capillaries dominate resting oxygen exchange to tissue.

Endothelial-dependent vasodilation is preserved in non-insulin-dependent Zucker fatty diabetic rats

Alterations in the structural properties of the microvasculature and in vasodilation mediated by endothelial- and, to some extent, nonendothelial-dependent mechanisms occurs in insulin-dependent diabetic humans and animals. Less severe problems of this type appear to occur during non-insulin-dependent diabetes mellitus (NIDDM) in humans, but data based on animal models of NIDDM are not available. The endothelial- and nonendothelial-mediated dilation of intestinal arterioles was studied in insulin-resistant male Zucker fatty diabetic (DB) rats and their lean normal male littermates (LM) at ages 22-25 and 35-40 wk. DB become hyperglycemic (450-550 mg/100 ml) at age 9-10 wk. Microiontophoretic release of acetylcholine, ADP, and nitroprusside onto arterioles caused equivalent dilation in LM and DB for both large and intermediate diameter arterioles. Administration of streptozotocin (STZ) to DB at age 18-19 wk lowered their insulin concentration approximately 25% but did not significantly effect the resting plasma glucose concentration. However, endothelial-dependent vasodilation was attenuated by 70-80% within 8-10 wk. The overall results indicate that prolonged hyperglycemia in insulin-resistant but hyperinsulinemic rats does not impair the endothelial- and nonendothelial-dependent dilation of the intestinal microvasculature. However, compromising beta-cell function with STZ, as indicated by lowering the insulin concentration by one-fourth, substantially compromises endothelial-dependent dilation similar to that found in insulin-dependent diabetic rats and humans.

Vascular endothelium and smooth muscle remodeling accompanies hypertrophy of intestinal arterioles in streptozotocin diabetic rats

The purpose of this study was to document alterations in endothelial and smooth muscle cell morphology of first- and second-order intestinal arterioles after 6 months of streptozotocin-induced diabetes. Both light and scanning electron microscopic techniques were used to quantitate the changes in the microvasculature. After rendering the first- and second-order intestinal arterioles passive and processing the vessels, it was determined that these microvessels were significantly dilated in the diabetic animals. Further examination revealed that in the diabetic animals, the cross-sectional area of the endothelial layer was increased in both 1A and 2A vessels, and the smooth muscle layer cross-sectional area was significantly increased in 1A vessels. Individual smooth muscle cells were significantly increased in width in the diabetic animals, but not in length. These data suggest that in this model of diabetes in rats, intestinal arteriolar hypertrophy was accompanied by significant remodeling of the arteriolar wall.

Excess oxygen delivery during muscle contractions in spontaneously hypertensive rats

These experiments determined whether a deficit in oxygen supply relative to demand could account for the sustained decrease in tissue PO2 observed during contractions of the spinotrapezius muscle in spontaneously hypertensive rats (SHR). Relative changes in blood flow were determined from measurements of vessel diameter and red blood cell velocity. Venular hemoglobin oxygen saturation measurements were performed by using in vivo spectrophotometric techniques. The relative dilation [times control (xCT)] of arteriolar vessels during contractions was as large or greater in SHR than in normotensive rats (Wistar-Kyoto), as were the increases in blood flow (2 Hz, 3.50 +/- 0.69 vs. 3.00 +/- 1.05 xCT; 4 Hz, 10.20 +/- 3.06 vs. 9.00 +/- 1.48 xCT; 8 Hz, 16.40 +/- 3.95 vs. 10.70 +/- 2.48 xCT). Venular hemoglobin oxygen saturation was lower in the resting muscle of SHR than of Wistar-Kyoto rats (31.0 +/= 3.0 vs. 43.0 +/- 1.9%) but was higher in SHR after 4- and 8-Hz contractions (4 Hz, 52.0 +/- 4.8 vs. 43.0 +/- 3.6%; 8 Hz, 51.0 +/- 4.6 vs. 41.0 +/- 3.6%). Therefore, an excess in oxygen delivery occurs relative to oxygen use during muscle contractions in SHR. The previous and current results can be reconciled by considering the possibility that oxygen exchange is limited in SHR by a decrease in anatomic or perfused capillary density, arteriovenular shunting of blood, or decreased transit time of red blood cells through exchange vessels.

Role of a lymphatic system in glucose absorption and the accompanying microvascular hyperemia

In this study we evaluated the importance of a functional intestinal lymphatic system on changes in arteriolar and venular blood oxygen content, vasodilation, and elevation of venous blood osmolarity during glucose absorption. Glucose absorption was associated with a doubling of the arteriovenous oxygen difference [(A-V)O2], a 50 mosM increase in venous blood osmolarity, and 17% dilation of the intermediate-diameter arterioles. After the lymph vessels were mechanically blocked with mineral oil, glucose absorption again doubled the (A-V)O2, indicating that glucose was absorbed without a functional lymphatic system. Furthermore, venous blood osmolarity and arteriolar diameter increased similarly with and without a functional lymphatic system. This study indicates that even though the lymphatic system likely facilitates distribution of hypertonic material in the bowel wall during absorption, blockade of the lymphatics did not appreciably hinder vasodilation, glucose absorption, changes in intravascular oxygen content, or the elevation of tissue hyperosmolarity, as judged by the tonicity of the venular blood. Therefore, passage of materials absorbed or released in the mucosa to the submucosa through venular blood flow may be very important to the mechanism of absorptive hyperemia.

Active and passive arteriolar regulation in spontaneously hypertensive rats

This study determined to what extent active and passive wall tensions increase in in vivo intestinal arterioles of 13- to 15-week-old and 25- to 27-week-old spontaneously hypertensive rats (SHR) to maintain normal or smaller arteriolar diameters during microvascular hypertension. Acetylcholine and nitroprusside were used to determine whether vascular muscle relaxation to endothelium-derived relaxing factor or cyclic GMP is impaired. Large arterioles of hypertensive rats have passive tension-circumference relations that are steeper and shifted to the left compared with those of age-matched controls; passive resistance to distension limits vasodilation in hypertensive rats except at their naturally elevated arteriolar pressure. Passive tension contributes approximately 30% of the total resting tension in arterioles of hypertensive and normotensive rats because a greater passive tension occurs at the 20% to 25% constricted resting diameter in hypertensive rats. Absolute and relative changes in the diameter of SHR arterioles during acetylcholine and nitroprusside application were equal to or greater than those in Wistar-Kyoto rats. However, reduction in active tension was suppressed in older SHR and remained approximately 50% higher than that found in older Wistar-Kyoto rats during drug application. Vasoconstriction and increased passive resistance to distension of the arteriolar wall diminish the active tension required to maintain normal or smaller resting diameters against microvascular hypertension. However, the elevated microvascular pressure in hypertensive rats is required to allow near-normal dilation to compensate for their increased passive resistance to stretch and decreased ability to relax active tension through cyclic GMP mechanisms.

Adrenergic and pressure-dependent vascular regulation in sedentary and trained rats

In this study, we determined if aerobic exercise training alters adrenergic or pressure-dependent vascular regulation in the rat hindlimb or intestine. Pressor responses to bilateral carotid artery occlusion and systemic phenylephrine (PE) infusion were not altered by training. During occlusion, peak and steady-state changes in hindlimb vascular resistance (HLR) were significantly greater in trained (24 and 13%) than in sedentary (8 and -3%) rats; a similar trend existed for intestinal vascular resistance (IR). The pressure-dependent contribution was consistent between groups (HLR: peak 55-85%, steady state 25-45%; IR: peak and steady state 40-65%). During PE infusion, increases in IR and HLR were similar between groups. The increase in HLR was substantially pressure dependent in both groups (approximately 50% at highest dose) as was the change in IR in trained rats. However, the IR response to PE was not pressure dependent in sedentary rats. The direct effects of PE were similar between sedentary and trained rats in the hindlimb but were suppressed in the intestine of trained rats compared with sedentary rats. Therefore, aerobic exercise training altered adrenergic and pressure-dependent vasoregulatory mechanisms in both skeletal muscle and intestinal tissues.

Topical hyperglycemia rapidly suppresses EDRF-mediated vasodilation of normal rat arterioles

Arteriolar dilation to endothelium-derived relaxing factor (EDRF) is suppressed early in diabetes mellitus. The purpose of this study was to determine whether acute exposure to a hyperglycemic media can suppress EDRF function of normal arterioles. Dilation of intestinal arterioles to iontophoretically applied acetylcholine (ACh) and nitroprusside was measured in normoglycemic rats before and after 1 h of topical exposure to isotonic solutions containing D-glucose concentrations of 200, 300, and 500 mg/100 ml. Exposure to a D-glucose concentration of 200 mg/100 ml had no effect on vasodilation to ACh. D-Glucose concentrations of both 300 and 500 mg/100 ml caused significant suppression of the responses: for example, at the approximate 50% effective dosage (100 nA), the dilatory response was decreased by 60% at a D-glucose concentration of 300 mg/100 ml and 55% at a D-glucose concentration of 500 mg/100 ml. Responses to nitroprusside were not significantly (P < 0.05) impaired after exposure to D-glucose concentrations of 200, 300, or 500 mg/100 ml. Exposure to an isotonic L-glucose concentration of 500 mg/100 ml for 1 h had no significant (P > 0.05) effect on responses to ACh. Pretreatment with superoxide dismutase, catalase, indomethacin, or meclofenamic acid preserved EDRF-mediated vasodilation during exposure to a D-glucose concentration of 500 mg/100 ml at almost all the ACh dosages tested. These results indicate that oxygen radicals formed in part by increased eicosanoid synthesis during exposure to D-glucose hyperglycemia interfere with the EDRF mechanism before its action on the microvascular smooth muscle.

Sodium hyperosmolarity of intestinal lymph causes arteriolar vasodilation in part mediated by EDRF

This study evaluated 1) the effect of increased submucosal lymph osmolarity on the regulation of first-order (1A) and second-order (2A) intestinal arterioles and 2) the role of endothelium-derived relaxing factor (EDRF) in hypertonic-induced vasodilation. Increasing the submucosal lymph osmolarity from 280 to 400 mosM, in increments of 30 mosM, resulted in a dose-dependent dilation of 1A and 2A. A submucosal lymph tonicity of 340 mosM, as occurs during glucose and oleic acid absorption, caused dilation of 1A (118%) and 2A (124%) equivalent to that during absorptive hyperemia. The dilation caused by 400 mosM mannitol (137%) was similar to that with 340 mosM NaCl (131%) and approximately 70% of that with 400 mosM NaCl (152%). After EDRF blockade, the responses to sodium hypertonicity decreased by about one-half; blockade reduced mannitol-induced dilation by 22%. These results indicate that sodium hypertonicity, as occurs during absorption, can play a major role in absorptive hyperemia, and about one-half of the dilation is related to a sodium-coupled release of EDRF.

Evaluation of carbocyanine-labeled erythrocytes for microvascular measurements

Red blood cells labeled with the carbocyanine dyes, 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) and 3,3'-dioctadecyloxacarbocyanine perchlorate (DiO), were evaluated for use in making microvascular measurements in rat small intestine and spinotrapezius muscle. We determined the minimum concentration of each dye which produced near maximal fluorescent intensity and labeled cell fraction. These dyes, which have excitation and emission spectra similar to fluorescein and rhodamine derivatives, have a number of advantages over the isothiocyanates: (1) the labeling procedure is quicker, easier, and less expensive; (2) the labeled cell fraction and the fluorescent intensity of DiI and DiO cells are stable for long periods of time in the rat circulation; and (3) DiI-labeled cells are brighter and transmit light through overlying erythrocytes better than rhodamine X isothiocyanate. However, in vitro and in vivo evaluations illustrate the potential limiting effects of vessel diameter and cell velocity on the accuracy of microvascular measurements made using this technique. In the small intestine and spinotrapezius muscle preparations, measurements of labeled cell flux were readily reproducible and could be partly automated with image analysis only in capillaries and small venules. Counting labeled cells in larger vessels by human observation or with automation was not reproducible, presumably due to absorption and dispersion of the fluorescent signal by overlying erythrocytes and smearing of the cell image at high cell velocities.

Functional adaptations of rat skeletal muscle arterioles to aerobic exercise training

This study tested the hypothesis that both structural and functional adaptations of arterioles occur within the skeletal muscle of rats aerobically trained for 8-10 wk with treadmill exercise. The training regimen used has been shown to elicit a 37% increase in plantaris citrate synthase activity but did not result in an elevation in citrate synthase activity in the spinotrapezius or gracilis muscles of rats used in this study. In the in vivo resting spinotrapezius muscle, arteriole diameters were similar in sedentary (SED) and trained (TR) rats. However, large- (1A) and intermediate- (2A) sized arterioles dilated proportionately more in TR than in SED rats during 1- to 8-Hz muscle contractions, even though the passive mechanical properties (circumference-passive wall tension relationships) were similar between groups. Vascular casts demonstrated a trend for an increase in the number of small (3A) arterioles and an approximately 20% increase in the passive diameter of 1A and 2A arterioles in the spinotrapezius muscle of TR rats. In contrast, in the gracilis muscle, arteriole diameters and density were identical in SED and TR rats, but the capillary-to-muscle fiber ratio was approximately 15% higher in TR rats. The results suggest that aerobic exercise training can greatly increase functional vasodilation and induce a slight increase in vascular density in skeletal muscle tissues, even if the oxidative capacity of these tissues is not increased by the training regimen.

Intestinal lymphatic vessels release endothelial-dependent vasodilators

This study evaluated the possibility that the endothelial cells of microscopic lymphatic vessels can release vasoactive agents which affect the lymphatic vessels and nearby arterioles. Microinotophoresis of acetylcholine (ACh) or bradykinin (BK) onto the wall of quiescent submucosal lymphatic vessels in the rat small intestine had no discernible effects on their diameters but caused spontaneously active mesenteric lymphatic vessels to constrict. Application of ACh or BK to the arteriolar wall caused significant vasodilation. Release of either drug onto the wall of a nearby lymphatic produced arteriolar dilation that was approximately 80% of that observed with direct application to the arteriolar wall; drug application into parenchymal tissue produced a dilation less than 25% of that observed during application to the lymphatic. NG-monomethyl-L-arginine application to the lymphatic blocked all ACh-induced lymphatic-mediated responses but had no effect on the response to direct ACh application to the arteriolar wall or any of the responses to BK application. These results are consistent with the hypothesis that lymphatic endothelial cells are capable of releasing agents that dilate nearby arterioles and cause spontaneously active lymphatic vessels to constrict.

Structural and functional origins of suppressed acetylcholine vasodilation in diabetic rat intestinal arterioles

This study evaluated the possible impairments to endothelium-mediated vasodilation by structural and functional properties of the intestinal arterioles in adult (20-21-week-old) rats after 8-11 days or 7-8 weeks of streptozotocin-induced diabetes. Arteriolar intravascular pressures and luminal diameters were simultaneously measured during iontophoretic application of acetylcholine, bradykinin, and nitroprusside to the outer vessel wall, and passive diameter-pressure relations were obtained during maximal vasodilation. Microvascular pressures and circumference-passive wall tension relations were similar between all diabetic and normal rats and did not appear to significantly influence vasodilation. Both acute and chronic hyperglycemia were associated with near complete suppression of acetylcholine-induced vasodilation in large arterioles, and the threshold dose for vasodilation of intermediate arterioles was approximately 10-fold higher in diabetic rats. In both diabetic groups, dilatory responses to nitroprusside were normal, and in chronically diabetic rats, the relative vasodilation in response to various doses of bradykinin was equivalent to that found in normal rats. These observations indicate that a very specific deficit of acetylcholine-induced endothelium-derived relaxing factor action rapidly develops in intestinal arterioles of diabetic rats, but the arteriolar wall mechanical properties, cGMP-mediated muscle relaxation, and endothelial release of the bradykinin-stimulated relaxing factor are not compromised after 7-8 weeks of chronic hyperglycemia.

Hepatic venular pressures of rats, dogs, and rabbits

We tested the hypotheses that the hepatic venule pressures (Phv), just downstream from the hepatic sinusoids, are closely similar (less than 2 mmHg) either to the portal venous pressure (Ppv), indicating a high hepatic venous resistance, or to the inferior vena cava (Pivc) pressure, indicating a high portal-sinusoidal venous resistance, as reported by previous investigators. A micropipette servo-null pressure measurement technique was used with rats, dogs, and rabbits. Phv, referred to the anatomic level of the vena cava, averaged 5.1 +/- 1.0, 6.4 +/- 1.1, and 5.4 +/- 1.0 (SD) mmHg in the rats, puppies, and rabbits, respectively. Ppv averaged 8.0 +/- 1.4, 10.8 +/- 2.2, and 7.4 +/- 1.5 mmHg, respectively. Norepinephrine infusion into the portal vein (1-5 micrograms.min-1.kg-1) caused Ppv to increase and the portal venous flow to decrease but did not significantly affect Phv. The hepatic venous circuit contributed 44 +/- 17% (rats) and 31 +/- 26% (dogs) of the total liver venous vascular resistance under control conditions. We conclude that the portal and sinusoidal vasculatures are the dominant, but not exclusive, resistance sites of the liver venous vasculature both at rest and during norepinephrine-induced vasoconstriction.

Vascular smooth muscle structure and juvenile growth in rat intestinal venules

The morphological structure of individual vascular smooth muscle cells from intestinal venules was evaluated with a combination of quantitative scanning (SEM) and transmission (TEM) electron microscopy techniques. In addition, growth of individual venular smooth muscle cells and of the overall vessel wall was compared from measurements of these variables during the rapid juvenile growth spurt from ages 4 to 6 and 10 to 12 weeks in Wistar-Kyoto rats. SEM revealed that smooth muscle cells of intestinal venules in weanling rats are very long (379 +/- 91 [SD] microns) and wide (6.0 +/- 1.3 microns) and very little further cell enlargement occurs during rapid juvenile growth. TEM studies indicated that passive inner vessel diameter and total muscle layer cross-sectional area of both the largest and intermediate diameter venules of young rats, as well as the percentage of the total wall area as muscle tissue in each venule type, did not significantly increase during body growth. These observations indicate that both the intestinal venules and their smooth muscle cells reach mature dimensions at a very early stage of life. Comparison of intestinal vascular smooth muscle cell dimensions indicates that venular smooth muscle cells are much larger in both cell length and volume than comparable arteriolar smooth muscle cells.

Mechanical characteristics and active tension generation in rat intestinal arterioles

The contributions of active and passive wall tension to regulation of arteriolar diameters were determined for large (1A), intermediate (2A), and small (3A) arterioles in the small intestine of the anesthetized rat. Active tension (Ta) contributed greater than 85% of total wall force at rest in 2A and 3A and 75-80% of total force in 1A. Ta was approximately 90% of peak active tension (Ta,peak) for large through small arterioles, even though absolute Ta varied by fourfold. A linear relationship between microvascular pressure and Ta was observed for decreases in pressure in all arterioles. Ta remained nearly constant for pressure increases of 40% in 2A and 3A but was increased in 1A. Because of the plateau of the circumference-Ta relationship near Ta,peak, superfusion of progressively increasing concentrations of norepinephrine or adenosine resulted in maintenance of the close Ta-Ta,peak relationship unless the vessel diameter changed greater than 25%. These results indicate that, while arteriolar diameters vary substantially, near-peak Ta is generated for a variety of physiological conditions.

Rat venular pressure-diameter relationships are regulated by sympathetic activity

The hypothesis that the pressure-diameter relationship of intestinal venules in rats is primarily determined by sympathetic nervous system activity was tested. The pressure-diameter relationship of the smallest to largest diameter (20-100 microns) intestinal venules of the rat was measured at rest, during hemorrhage to increase sympathetic neural activity, and during saline volume expansion to decrease sympathetic activity. During hemorrhage, the diameter of all venules decreased approximately 10% at 10 mmHg venous pressure, and the slope of the pressure-diameter relationship increased approximately 50% above control. Blood volume expansion led to an approximately 10% increase in venule diameter at 10 mmHg and a 25% decrease in slope. Denervation of the vessels causes concomitant vasodilation, which was greater than the vasodilation caused by blood volume expansion. Hemorrhage after denervation caused no significant changes in the relationship when compared with denervated control. Nitroprusside caused an even greater vasodilation when compared with the pressure-diameter relationship after denervation. The results suggest that the slope and 10-mmHg intercept of the pressure-diameter relationship for the largest through smallest intestinal venules and, therefore, their vascular compliance and capacitance characteristics are primarily determined by sympathetic activity.

Maturation of the rat intestinal microvasculature from juvenile to early adult life

The same region of intestinal ileum was compared in the same rats at 10 and 20 wk of age to determine if reported differences in vessel density between these ages were the result of changes in vessel numbers. The number and branching pattern of arterioles observed remained remarkably constant during the 10 wk between observations, and minimal enlargement of bowel mass occurred. No significant change in average maximum diameter of arterioles was observed. Although the total number of small arterioles did not change, vessels were gained and lost at an equal rate (7%) between 10 and 20 wk. There was no significant changes in means or frequency distributions of intercapillary distances in the radial or longitudinal bowel muscle layers. The results indicate that the intestinal microvascular branching pattern changes very little from juvenile to adult life. However, a slow turnover of small arterioles does occur, indicating an ongoing remodeling of the terminal vasculature during juvenile life.

EDRF from rat intestine and skeletal muscle venules causes dilation of arterioles

Communication from venules to arterioles through the release of endothelial-derived relaxing factor (EDRF) was evaluated. To demonstrate that the rat intestinal and the spinotrapezius muscle arterioles can respond to EDRF, the vessels were dilated by iontophoretically applied acetylcholine (ACh), and this dilation was greatly attenuated by the inhibitors of EDRF actions, methylene blue (100 microM) and dithiothreitol (50 microM). The EDRF inhibitors did not suppress arteriolar dilation to typically applied adenosine (10(-4) M), an endothelium-independent dilator. Although ACh release onto the venular wall had minimal effects on the diameter of the venule, the paired arteriole would dilate 20-30% in the intestine and 50-60% in the spinotrapezius muscle. After EDRF inhibition, venular ACh exposure did not cause arteriolar dilation. ACh diffusion from venules to arterioles was not the cause of arteriolar dilation, because release of ACh into the tissue at the same distance as from the arteriole to the venular ACh release site caused minimal arteriolar dilation. Neither blockade of neural reflexes with tetrodotoxin (3 X 10(-6) M) nor suppression of prostaglandin formation with indomethacin (10(-5) M) prevented the arteriolar dilation during release of ACh onto the venular wall. The overall study indicated that communication from venules to arterioles through the release of EDRF from the venule did occur and caused substantial arteriolar vasodilation. Therefore circumstances within and around venules may influence regulation of nearby arterioles through an EDRF-mediated mechanism.

The microcirculation in hypertension

Studies of the peripheral microcirculation in major organ systems during hypertension indicate that in anaesthetized spontaneously hypertensive rats (SHR) a combination of both vasoconstriction and temporary and permanent vessel closure occurs. The vasoconstriction is often limited to the largest and smallest arterioles and rarefaction is best expressed for arterioles with inner diameters less than 25 microns in the lower body musculature. Direct measurements of microvascular pressures in hypertensive rats indicate that while all arterioles in major organ systems are exposed to a pressure much higher than normal, the smallest arterioles dissipate a much higher than normal fraction of the mean arterial pressure. However, the transition vessels between the smallest arteries and the larger arterioles account for the largest fraction of total resistance (50-60%) and dominate the precapillary vascular resistance in the cerebral, intestinal and skeletal muscle vasculatures. In the established stages of hypertension, the relative influence of the transition resistance vessels is somewhat less than during the developmental phase of hypertension and also less than in adult normal animals. This latter observation has been made in a number of vasculatures and may indicate that resistance changes in the true microvessels and in the transition vessels do not occur simultaneously during the development of hypertension.

Rat intestinal lymph osmolarity during glucose and oleic acid absorption

The two major purposes of this study were to determine 1) how glucose and oleic acid absorption by the intestinal villi influenced the osmotic composition of lymph as it exited the villus base and 2) what if any changes in lymph osmolarity occurred as the lymph traversed through the bowel wall. The rat jejunum was used in all studies and lymph was collected from individual lymphatics at 0.5-1 nl/min during control states and luminal exposure to 35-550 mg% glucose solutions (isotonic in saline) and 5 and 20 mM oleic acidtaurocholate solutions. Lymph collected from the base of villi during vigorous motility had an osmolarity of 403 +/- 15 mosM at rest and was only increased 30-50 mosM more except during exposure to 550 mg% glucose, where osmolarity increased over 100 mosM. Under comparable conditions, the submucosal lymph osmolarity at rest was 302 +/- 3.5 mosM and increased to 330-350 mosM during exposure to all of the solutions tested. When intestinal motility was virtually stopped, the submucosal lymph osmolarity was isotonic for all solutions tested. These observations indicate that absorption of glucose and oleic acid increased the osmolarity of lymph, leaving the villus only 30-50 mosM unless a glucose concentration of 550 mg% was present. Furthermore, the increased flow of villus lymph during absorption raised the osmolarity of the submucosal lymph when bowel motility assisted the lymph propulsion. This movement of materials from the villus to the submucosa by venular blood and lymph flow provides an opportunity for the villus tissue to influence the composition of the submucosal interstitial environment.

Arteriolar diameter and tissue oxygen tension during muscle contraction in hypertensive rats

This study evaluated the possibility that in hypertension, mechanisms that maintain near normal arteriolar diameters at elevated arteriolar pressures limit the ability of skeletal muscle arterioles to dilate in response to an increase in tissue metabolism. The spinotrapezius muscles of 16- to 20-week-old spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY) were contracted at frequencies of 1, 2, 4, and 8 Hz. The inner diameters of first-order through third-order arterioles were measured at rest and following 3 minutes of contractions. Tissue oxygen tension (PO2) at the venous end of capillaries was monitored during 8-Hz contractions. At rest, following contractions, and after maximum dilation with adenosine, the inner diameters of arterioles of equivalent branch order were not significantly different in SHR and WKY. Opening of closed arterioles during muscle contraction and adenosine application occurred in less than 5% of the observations in both groups. The resting tissue PO2 was 25.5 +/- 1.3 mm Hg in normal rats and 26.1 +/- 2.1 mm Hg in SHR. At nearly maximum vasodilation during 8-Hz stimulation, tissue PO2 recovered to 81.9 +/- 12.7% of control in WKY but only to 41.2 +/- 13.0% of control in SHR. These observations indicate that the expression of local regulatory mechanisms related to tissue metabolism is virtually normal in the spinotrapezius muscle vasculature of SHR in the context of arteriolar dilation. However, at near maximum performance, factors other than absolute arteriolar diameter preclude the normal preservation of tissue PO2 in the spinotrapezius muscle of SHR.

Intestinal microvascular growth during maturation in diabetic juvenile rats

To determine if intestinal microvascular growth is impaired in diabetic juvenile animals, a segment of the terminal ileum was marked and the microvasculature of this segment observed at the age of 5 weeks and again at the age of 10-11 weeks in normal and diabetic Sprague Dawley rats. Diabetes was induced by streptozotocin after the first observation period and the plasma glucose concentration exceeded 500 mg% by the age of 10-11 weeks. Microvascular growth was quantitated by measurements of the number, length, and maximally dilated inner diameters of specific arterioles and by intercapillary distances in the marked intestinal region at both ages. Although intestinal enlargement was much greater in diabetics, there was no change in the number of arterioles during maturation and intercapillary distances were equivalent in diabetic and normal rats. In normal and diabetic animals, the arteriolar length increased to match bowel elongation, however, increases in bowel and arteriolar lengths in diabetic animals were about twice that of normal rats. During juvenile maturation, the maximally dilated inner diameters of the small arterioles in diabetic animals were increased compared with their normal counterparts. Thus, arteriolar growth during maturation is characterized by changes in the length but not in the number of vessels in intestine of both normal and diabetic rats. The perfusion of about 90% more tissue by mass for each arteriole in diabetic rats is facilitated by arteriolar dilation.(ABSTRACT TRUNCATED AT 250 WORDS)

Lymphatic pathways and role of valves in lymph propulsion from small intestine

The pathways through which lymph is propelled from the mucosal, submucosal, and muscle layer lymphatics of the small intestine, the interconnections between these layers, and the location of lymphatic valves within these layers were studied. Injections of fluid into a single lacteal or submucosal lymphatic of rats, rabbits, dogs, and cats spread in all directions through the submucosal lymphatics and into laceteals but did not enter the lymphatics of the muscle layer. Injections into muscle layer lymphatics also spread in all directions but in no case entered the submucosal lymphatics. The submucosal and muscle layer lymphatics join within the bowel wall near the mesenteric border to form collecting lymphatics characterized by valves and spontaneous contractions. These data indicate that lymphatics of the mucosa and submucosa form a syncytium independent of the muscle layer lymphatics and that few if any valves exist within these lymphatic networks. Cycling lacteal pressures were measured when intestinal motility was present but not when motility was abolished, suggesting that intestinal motility might have a role in lymph propulsion.

Determinants of resting and passive intestinal vascular pressures in rat and rabbit

Microvascular pressures in the intestinal arteries, submucosal arterioles, and mucosal venules were measured in rats and rabbits at rest and during maximum dilation. From these data and Doppler velocimetry measurements of relative changes in whole organ blood flow on maximum dilation, it was possible to determine to what extent microvascular pressures at rest depend on the active control and passive hemodynamic characteristics of specific vascular segments. New Zealand White rabbits (2-3 kg body wt) had a mean arterial pressure of 70-75 mmHg. However, pressures in arterioles of both species became equivalent at the second order of arteriolar branching within the bowel wall, and pressures in the smallest mucosal venules were 13.7 +/- 0.6 (SE) mmHg in rabbits and 14.9 +/- 0.3 mmHg in rats. Maximum vasodilation to approximately 300% of the control blood flow increased mucosal venule pressures approximately 10 mmHg in rats compared with approximately 4 mmHg in rabbits. The increased mucosal venule pressure during vasodilation was primarily due to increased pressures within the submucosal small arterioles, which immediately precede the villus vasculature in both species. The increased blood flow during vasodilation was due primarily to a decreased resistance of the small arteries and large arterioles, even though pressures in these larger vessels changed only approximately 10%. This situation allows a major decrease in intestinal vascular resistance to substantially increase blood flow with a minimal increase in mucosal microvascular pressures.

Quantification of intestinal microvascular growth during maturation: techniques and observations

This study was undertaken to determine what changes occur in the intestinal microvasculature during the rapid growth associated with juvenile maturation. A technique was developed that permitted the comparison of the same microvessels in exactly the same intestinal region at two time periods of an animal's life. A region of the terminal ileum of 5-week-old rats was exposed and marked, and photographs and video recordings were made of the microvessels. Four weeks later, the marked intestinal region was located, and photography and videography of the microvessels were repeated. Comparison of indexes for body, intestinal, and microvascular growth for the treated rats and age- and colony-matched controls revealed no significant differences. The number and branching pattern of arterioles observed in the marked region remained remarkably constant during the 4 weeks between observation periods, even though body and bowel mass of the treated animals increased approximately 2.5 times. The lengths of the arterioles were increased (18%) by almost the same proportion as the axis of bowel (22%) in which they were oriented. The average distance between capillaries in the radial intestinal muscle layer was also increased by about the same percentage (24%) as that of tissue elongation (22%). The overall data are consistent with the hypothesis that during the growth spurt of juvenile life, the arterioles present at the weanling stage are elongated and new branches do not develop. The net effect of tissue growth with a minimal change in numbers of arterioles is a decreased ratio of number of arterioles to tissue mass as a normal consequence of maturation.

Exposure of vascular smooth muscle cells for analysis with the scanning electron microscope

There has been interest in using the scanning electron microscope (SEM) to study the structure of tissues obscured by other cellular or non-cellular elements almost since the SEM was first used to examine biological tissues. Such interest includes the vessel wall and, in particular, the vascular smooth muscle cells. This paper presents a review of the three basic methodologies that have been employed to allow examination of the vascular smooth muscle, 1) blunt dissection, 2) digestion and 3) microdissection. Discussion of other perivascular elements was not a focus of this review. Also presented is the application of these different methodologies to different pathophysiologic conditions.