Global ETD Search

1	Modelling nephron dynamics and tubuloglomerular feedback Graybill, Scott Jason January 2010 (has links) The kidneys are amazingly versatile organs that perform a wide range of vital bodily functions. This thesis provides an analysis into a range of mathematical models of the tubuloglomerular feedback (TGF) mechanism. The TGF mechanism is an autoregulatory mechanism unique to the kidney that maintains approximately constant blood flow to the organ despite wide fluctuations in pressure. Oscillations in pressure, flow, and sodium chloride concentration have been attributed to the action of the TGF mechanism through a number of experimental studies. These oscillations appear spontaneously or in response to a natural or artificial pressure step or microperfusion. The reason for sustained oscillatory behaviour in nephrons is not immediately clear. Significant research has gone into experimentally determining the signal to the TGF mechanism, but the physiological significance is not mentioned in the literature. Considerable modelling of the oscillations attributed to the TGF mechanism has also been undertaken. However, this modelling uses models that are inherently oscillatory, such as a second-order differential equation or delay differential equations. While these models can be fitted to closely approximate the experimental results they do not address the physiological factors that contribute to sustained oscillations. This thesis aims to determine the contributing factors to the sustained oscillations. By understanding these factors a better hypothesis of the physiological role of the oscillations should be possible. Chapter 3 presents a mathematical model by Holstein-Rathlou and Marsh [28] that uses a partial differential equation (PDE) model for the tubule and a second-order differential equation for the TGF feedback. The remainder of this chapter shows that oscillations occur without an inherently oscillatory second-order differential equation due to the delays in the system. Tubular compliance was also shown to be necessary for sustained oscillations. Sustained oscillations were not exhibited in the TGF model with a noncompliant tubule. Although damped oscillations were exhibited for a wide range of parameter space. Adding compliance to the tubule increased the delay around the loop of Henle. This additional delay elicited sustained oscillations. The computationally expensive PDE model of 3 was simplified to an ordinary differential equation (ODE) model in Chapter 4 by assuming a spatial profile. This model exhibits much of the same qualitative behaviour as the PDE model including sustained oscillations for similar ranges of parameter space. Compliance was also found to be important in the generation of sustained oscillations in agreement with the PDE tubule model. This model is less computationally expensive than the PDE model and allows analysis that was unfeasible with the PDE model. Significant natural and artificial blood pressure fluctuation occur in experimental rat models. Chapter 5 examines the effect of inlet pressure forcing on a nonoscillatory and an oscillatory model. The inherently nonoscillatory noncompliant model becomes oscillatory with a physiologically realistic pressure forcing. The oscillatory compliant model remains oscillatory with the addition of a inlet pressure forcing. Pressure fluctuations were hypothesised to contribute to sustained oscillations and could be validated experimentally. Two extensions to the single nephron TGF models are presented in Chapter 6. A realistic juxtaglomerular delay is added to the single nephron models with both the ODE and PDE tubular models. Physiologically realistic juxtaglomerular delays induce sustained oscillations in the otherwise nonoscillatory noncompliant models. The remainder of this chapter presents a different model for a variable interstitial sodium chloride concentration profile. This model demonstrates experimentally observed function of the countercurrent mechanism by which a concentration gradient is set up and maintained in the interstitium. Two single nephron models with ODE tubular models are coupled in Chapter 7. The coupling is modelled through the effect on the resistance of their neighbouring nephron's afferent arteriole resistance. The coupled nephron model exhibits entrainment as observed experimentally. Inhibiting the oscillation in one nephron reduces the amplitude of the oscillation in its neighbour. This result compares well with experiments where the TGF mechanism in one nephron is blocked by the administration of furosemide. Kidneys nephrons tubuloglomerular feedback oscillations mathematical modelling bioengineering.
2	The Influence of the Adenosine A<sub>1</sub>-receptor on Tubuloglomerular Feedback and Renin Release Brown, Russell January 2004 (has links) <p>The kidneys play a vital role in the maintenance of extracellular fluid and electrolyte balance and blood pressure. Adenosine, acting through the adenosine A<sub>1</sub>-receptor (A<sub>1</sub>R), and nitric oxide have been implicated in several of the regulatory mechanisms in the kidney. The A<sub>1</sub>R has been found to be present in the renal vasculature, primarily in the afferent arterioles, and in the proximal tubules. The tubuloglomerular feedback mechanism (TGF) is an important regulator of renal vascular tone and glomerular filtration rate. The aim of these investigations was to further elucidate the role of adenosine, acting through the A<sub>1</sub>R. Investigations on adenosine’s renal effects were performed on transgenic mice lacking the A<sub>1</sub>R.</p><p>TGF response, elicited by increased distal salt load, was completely abolished in the A1R knockout (A<sub>1</sub>R -/- ) mice. Basal plasma-renin levels were found to be ~2-fold higher in the A<sub>1</sub>R -/- compared to the A<sub>1</sub>R wild-type (A<sub>1</sub>R+/+) mice. However, salt intake induced inverse changes in plasma-renin levels, indicating that adenosine tonically inhibits macula densa stimulated renin release. Anesthetized and conscious A<sub>1</sub>R -/- mice, measured telemetrically, had an increased blood pressure, which could be due to the increased plasma-renin levels. Despite the high plasma-renin levels, increased urinary sodium excretion was also observed in the A<sub>1</sub>R -/- animals. Ischemia caused a decrease in renal function in both A<sub>1</sub>R+/+ and A<sub>1</sub>R -/- mice. Ischemic preconditioning protected the A<sub>1</sub>R+/+ mice from subsequent ischemic episode but had no protective effect on the A<sub>1</sub>R -/- mice.</p><p>Acute extracellular volume expansion greatly attenuates TGF sensitivity, thus facilitating the elimination of excess fluid. Acute inhibition of nNOS in volume-expanded rats was found to re-establish the attenuated TGF response caused by acute extracellular volume expansion.</p><p>The results show that adenosine, acting through the A<sub>1</sub>R, plays an important role in mediating TGF response and consequently, regulating renin release, blood pressure, electrolyte balance and other vital renal mechanisms.</p> Physiology adenosine tubuloglomerular feedback renin release blood pressure micropuncture Fysiologi Physiology Fysiologi
3	Interaction between Adenosine and Angiotensin II in Renal Afferent Arterioles of Mice Lai, Enyin January 2007 (has links) <p>Renal arterioles represent the most important effecter site in the control of renal perfusion and filtration. Adenosine (Ado), angiotensin II (Ang II) and nitric oxide (NO) interact in modulating arteriolar tone. The present work investigates the mechanism of this interaction. We tested the hypothesis that AT<sub>1</sub> receptor (AT<sub>1</sub>AR) mediated NO release in isolated perfused afferent arterioles. Further, special attention was given to mechanisms of Ado-Ang II -interactions.</p><p>We found (I) that Ang II specifically induces NO release via AT<sub>1</sub>AR in arterioles. The effect is important in view of high renin and Ang II concentrations in these vessels. (II) Ado modulates the Ang II response by acting on vasoconstrictor A<sub>1</sub>AR and vasodilator A<sub>2</sub>AR. Vice versa, Ang II critically enhances the constriction to Ado, which supports the assumption of its modulating action in the tubuloglomerular feedback (TGF). (III) The synergistic effect of Ang II and Ado on arteriolar contraction is concurrent with an increase in the cytosolic calcium. Further, (IV) Ado increases the calcium sensitivity of the contractile machinery in arteriolar smooth muscle cells most probably by enhancement of the phosphorylation of the myosin light chain regulatory unit. RhoA kinase, protein kinase C and p38 MAP are involved in the Ado effect, which is not receptor mediated and depends on the Ado uptake into vascular cells. Remarkably, the enhancing action of Ado is most likely limited to Ang II; since Ado does not influence endothelin-1 and norepinephrine induced contractions.</p><p>These novel results extend our knowledge about the synergistic action of Ang II and Ado in the control of renal filtration. Ado, the key factor in mediation of the TGF, develops a significant vasoconstrictor action only in the presence of Ang II. On the other hand, the Ang II induced vasoconstriction is modulated by Ado via receptor and non-receptor mediated intracellular signaling pathways.</p> Physiology adenosine angiotensin II afferent arteriole calcium nitric oxide microperfusion tubuloglomerular feedback Fysiologi
4	The Influence of the Adenosine A1-receptor on Tubuloglomerular Feedback and Renin Release Brown, Russell January 2004 (has links) The kidneys play a vital role in the maintenance of extracellular fluid and electrolyte balance and blood pressure. Adenosine, acting through the adenosine A1-receptor (A1R), and nitric oxide have been implicated in several of the regulatory mechanisms in the kidney. The A1R has been found to be present in the renal vasculature, primarily in the afferent arterioles, and in the proximal tubules. The tubuloglomerular feedback mechanism (TGF) is an important regulator of renal vascular tone and glomerular filtration rate. The aim of these investigations was to further elucidate the role of adenosine, acting through the A1R. Investigations on adenosine’s renal effects were performed on transgenic mice lacking the A1R. TGF response, elicited by increased distal salt load, was completely abolished in the A1R knockout (A1R -/- ) mice. Basal plasma-renin levels were found to be ~2-fold higher in the A1R -/- compared to the A1R wild-type (A1R+/+) mice. However, salt intake induced inverse changes in plasma-renin levels, indicating that adenosine tonically inhibits macula densa stimulated renin release. Anesthetized and conscious A1R -/- mice, measured telemetrically, had an increased blood pressure, which could be due to the increased plasma-renin levels. Despite the high plasma-renin levels, increased urinary sodium excretion was also observed in the A1R -/- animals. Ischemia caused a decrease in renal function in both A1R+/+ and A1R -/- mice. Ischemic preconditioning protected the A1R+/+ mice from subsequent ischemic episode but had no protective effect on the A1R -/- mice. Acute extracellular volume expansion greatly attenuates TGF sensitivity, thus facilitating the elimination of excess fluid. Acute inhibition of nNOS in volume-expanded rats was found to re-establish the attenuated TGF response caused by acute extracellular volume expansion. The results show that adenosine, acting through the A1R, plays an important role in mediating TGF response and consequently, regulating renin release, blood pressure, electrolyte balance and other vital renal mechanisms. Physiology adenosine tubuloglomerular feedback renin release blood pressure micropuncture Fysiologi Physiology Fysiologi
5	Interaction between Adenosine and Angiotensin II in Renal Afferent Arterioles of Mice Lai, Enyin January 2007 (has links) Renal arterioles represent the most important effecter site in the control of renal perfusion and filtration. Adenosine (Ado), angiotensin II (Ang II) and nitric oxide (NO) interact in modulating arteriolar tone. The present work investigates the mechanism of this interaction. We tested the hypothesis that AT1 receptor (AT1AR) mediated NO release in isolated perfused afferent arterioles. Further, special attention was given to mechanisms of Ado-Ang II -interactions. We found (I) that Ang II specifically induces NO release via AT1AR in arterioles. The effect is important in view of high renin and Ang II concentrations in these vessels. (II) Ado modulates the Ang II response by acting on vasoconstrictor A1AR and vasodilator A2AR. Vice versa, Ang II critically enhances the constriction to Ado, which supports the assumption of its modulating action in the tubuloglomerular feedback (TGF). (III) The synergistic effect of Ang II and Ado on arteriolar contraction is concurrent with an increase in the cytosolic calcium. Further, (IV) Ado increases the calcium sensitivity of the contractile machinery in arteriolar smooth muscle cells most probably by enhancement of the phosphorylation of the myosin light chain regulatory unit. RhoA kinase, protein kinase C and p38 MAP are involved in the Ado effect, which is not receptor mediated and depends on the Ado uptake into vascular cells. Remarkably, the enhancing action of Ado is most likely limited to Ang II; since Ado does not influence endothelin-1 and norepinephrine induced contractions. These novel results extend our knowledge about the synergistic action of Ang II and Ado in the control of renal filtration. Ado, the key factor in mediation of the TGF, develops a significant vasoconstrictor action only in the presence of Ang II. On the other hand, the Ang II induced vasoconstriction is modulated by Ado via receptor and non-receptor mediated intracellular signaling pathways. Physiology adenosine angiotensin II afferent arteriole calcium nitric oxide microperfusion tubuloglomerular feedback Fysiologi
6	Development of Salt-Sensitive Hypertension in Hydronephrosis Carlström, Mattias January 2008 (has links) <p>Hydronephrosis, due to ureteropelvic junction obstruction, is a common condition in infants with an incidence of approximately 0.5-1%. During the last decade, the surgical management of non-symptomatic hydronephrosis has become more conservative, and the long-term physiological consequences of this new policy are unclear. The overall aim of this thesis was to determine whether there is a link between hydronephrosis and the development of hypertension. Hydronephrosis was induced by partial ureteral obstruction in 3-week old rats or mice. In the adult animals, blood pressure was measured telemetrically during different sodium conditions and the renal function was evaluated. Both species developed salt-sensitive hypertension and histopathological changes (i.e. fibrosis, inflammation, glomerular and tubular changes) that correlated with the degree of hydronephrosis. An abnormal renal excretion pattern with increased diuresis and impaired urine concentrating ability was observed in hydronephrosis. The mechanisms were primarily located to the diseased kidney, as relief of the obstruction attenuated blood pressure and salt-sensitivity. Increased renin angiotensin system activity, due to ureteral obstruction, might be involved in the development but not necessary the maintenance of hypertension. Hydronephrotic animals displayed reduced nitric oxide availability, which might be due to increased oxidative stress in the diseased kidney. Renal nitric oxide deficiency and subsequent resetting of the tubuloglomerular feedback mechanism, appeared to have an important role in the development of hypertension. In conclusion, experimental hydronephrosis, induced by partial ureteral obstruction, provides a new model for studies of salt-sensitive hypertension. Furthermore, the new findings imply that the current conservative treatment strategy in hydronephrosis should be reconsidered in favour of treatment that is more active, in order to prevent the development of renal injury and hypertension in later life.</p> Physiology blood pressure nephrectomy nitric oxide oxidative stress renal function renin angiotensin system salt-sensitivity telemetry tubuloglomerular feedback ureteral obstruction Fysiologi
7	Macula Densa Derived Nitric Oxide and Kidney Function Ollerstam, Anna January 2002 (has links) <p>The kidney is the major organ regulating the extracellular fluid volume and thereby the arterial blood pressure. The neuronal isoform of nitric oxide synthase (nNOS) in the kidney is predominantly located in the macula densa cells. These cells are sensors for both renin release and the tubuloglomerular feedback mechanism (TGF), which is an important regulator of the glomerular filtration rate and afferent arteriole tone. The aim of this investigation was to elucidate the function of nNOS in the macula densa cells.</p><p>Acute nNOS inhibition in rats resulted in an increased TGF responsiveness and unchanged blood pressure while, after chronic inhibition, the TGF was normalised and the blood pressure was elevated. The plasma renin concentration was elevated in rats on long-term low salt diet, but was not significantly affected by chronic nNOS inhibition. On the other hand, nNOS inhibition for four days increased plasma renin concentration in rats treated with a low salt diet. The renal vasculature of rats exhibits a diminished renal blood flow and intracellular Ca2+ response to angiotensin II after one week blockade of nNOS while angiotensin II’s effect on the renal blood flow was abolished after four weeks treatment. Acute extracellular volume expansion diminish the TGF sensitivity thus assisting the elimination of excess fluid but after acute addition of nNOS inhibitor to volume expanded rats the TGF sensitivity restored.</p><p>In conclusion, the results from the present study suggest an important role for nNOS in the macula densa cells in the regulation of the arterial blood pressure and the modulation of the TGF response.</p> Cell biology Nitric oxide rats kidney macula densa cells tubuloglomerular feedback renin angiotensin II blood pressure hypertension renal blood flow neuronal nirtic oxide synthase Cellbiologi Cell biology Cellbiologi
8	Macula Densa Derived Nitric Oxide and Kidney Function Ollerstam, Anna January 2002 (has links) The kidney is the major organ regulating the extracellular fluid volume and thereby the arterial blood pressure. The neuronal isoform of nitric oxide synthase (nNOS) in the kidney is predominantly located in the macula densa cells. These cells are sensors for both renin release and the tubuloglomerular feedback mechanism (TGF), which is an important regulator of the glomerular filtration rate and afferent arteriole tone. The aim of this investigation was to elucidate the function of nNOS in the macula densa cells. Acute nNOS inhibition in rats resulted in an increased TGF responsiveness and unchanged blood pressure while, after chronic inhibition, the TGF was normalised and the blood pressure was elevated. The plasma renin concentration was elevated in rats on long-term low salt diet, but was not significantly affected by chronic nNOS inhibition. On the other hand, nNOS inhibition for four days increased plasma renin concentration in rats treated with a low salt diet. The renal vasculature of rats exhibits a diminished renal blood flow and intracellular Ca2+ response to angiotensin II after one week blockade of nNOS while angiotensin II’s effect on the renal blood flow was abolished after four weeks treatment. Acute extracellular volume expansion diminish the TGF sensitivity thus assisting the elimination of excess fluid but after acute addition of nNOS inhibitor to volume expanded rats the TGF sensitivity restored. In conclusion, the results from the present study suggest an important role for nNOS in the macula densa cells in the regulation of the arterial blood pressure and the modulation of the TGF response. Cell biology Nitric oxide rats kidney macula densa cells tubuloglomerular feedback renin angiotensin II blood pressure hypertension renal blood flow neuronal nirtic oxide synthase Cellbiologi Cell biology Cellbiologi
9	Development of Salt-Sensitive Hypertension in Hydronephrosis Carlström, Mattias January 2008 (has links) Hydronephrosis, due to ureteropelvic junction obstruction, is a common condition in infants with an incidence of approximately 0.5-1%. During the last decade, the surgical management of non-symptomatic hydronephrosis has become more conservative, and the long-term physiological consequences of this new policy are unclear. The overall aim of this thesis was to determine whether there is a link between hydronephrosis and the development of hypertension. Hydronephrosis was induced by partial ureteral obstruction in 3-week old rats or mice. In the adult animals, blood pressure was measured telemetrically during different sodium conditions and the renal function was evaluated. Both species developed salt-sensitive hypertension and histopathological changes (i.e. fibrosis, inflammation, glomerular and tubular changes) that correlated with the degree of hydronephrosis. An abnormal renal excretion pattern with increased diuresis and impaired urine concentrating ability was observed in hydronephrosis. The mechanisms were primarily located to the diseased kidney, as relief of the obstruction attenuated blood pressure and salt-sensitivity. Increased renin angiotensin system activity, due to ureteral obstruction, might be involved in the development but not necessary the maintenance of hypertension. Hydronephrotic animals displayed reduced nitric oxide availability, which might be due to increased oxidative stress in the diseased kidney. Renal nitric oxide deficiency and subsequent resetting of the tubuloglomerular feedback mechanism, appeared to have an important role in the development of hypertension. In conclusion, experimental hydronephrosis, induced by partial ureteral obstruction, provides a new model for studies of salt-sensitive hypertension. Furthermore, the new findings imply that the current conservative treatment strategy in hydronephrosis should be reconsidered in favour of treatment that is more active, in order to prevent the development of renal injury and hypertension in later life. Physiology blood pressure nephrectomy nitric oxide oxidative stress renal function renin angiotensin system salt-sensitivity telemetry tubuloglomerular feedback ureteral obstruction Fysiologi
10	Local Purinergic Control of Arteriolar Reactivity in Pancreatic Islets and Renal Glomeruli Gao, Xiang January 2014 (has links) Local control of regional blood flow is exerted mainly through the arterioles. An adequate minute-to-minute regulation of blood perfusion of the kidney and the pancreas is obtained by the modulation of arteriolar reactivity, which will influence the organ function. The importance of purinergic signaling in this concept has been addressed, with special emphasis on the role of the adenosine A1 receptor. The effects of adenosine on two specialized vascular beds, namely the renal glomerulus and the pancreatic islets, have been examined. Characteristic for these regional circulations is their very high basal blood flow, but with somewhat different responses to vasoconstrictor and vasodilator stimuli. By adapting a unique microperfusion technique it was possible to separately perfuse isolated single mouse arterioles with attached glomeruli or pancreatic islets ex vivo. Microvascular responses were investigated following different additions to the perfusion fluid to directly examine the degree of dilation or constriction of the arterioles. This has been performed on transgenic animals in this thesis, e.g. A1 receptor knockout mice. Also effects of P2Y receptors on islet arterioles were examined in both normoglycemic and type 2 diabetic rats. Furthermore, interference with adenosine transport in glomerular arterioles were examined.. Our studies demonstrate important, yet complex, effects of adenosine and nucleotide signaling on renal and islet microvascular function, which in turn may influence both cardiovascular and metabolic regulations. They highlight the need for further studies of other purinergic receptors in this context, studies that are at currently being investigated. afferent arteriole islet arteriole adenosine A1 receptor ATP P2Y receptor microperfusion angiotensin II type 2 diabetes hypertension oxidative stress nitric oxide tubuloglomerular feedback

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