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Role of testosterone and its interaction with adrenoceptor in protection against ischaemic insult and contractile function of the heartTsang, Sharon. January 2008 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2008. / Includes bibliographical references (leaves 172-238) Also available in print.
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Investigation into the effects of Artemisinin in myocardial ischaemia reperfusion injuryBabba, M. A. January 2015 (has links)
Artemisinin is herbal drug with a wide range of biological and physiological function. It is currently administered in the treatment against uncomplicated F.Palcifarum infections. It has also been shown to be cytotoxic against a variety of cancer cells. Despite the promise of many anti cancer drugs, drug induced cardiotoxicity has constantly threatened drug applicability especially in patients with co-morbities. Artemisinin has been shown to be cardioprotective, although the intracellular pathways remain to be elucidated. In this study, isolated perfused rat hearts were subjected to 35 minutes of ischaemia and 120 minutes reperfusion or primary cardiac myocytes subjected to 120 minutes hypoxia and 120 minutes reoxygenation where artemisinin (4.3μM) was administered in presence and absence of the PI3K inhibitor (wortmannin) (0.1μM), p70S6K inhibitor (rapamycin) (0.1μM), non selective nitric oxide synthase inhibitor (L-NAME) (100μM) and inducible nitric oxide synthase inhibitor (aminoguanidine) (100μM). At the end of the experiment, hearts underwent infarct size to risk ratio assessment via tri-phenyltetrazolium chloride staining or western blot analysis for p-Akt and p70S6K. Cardiac myocytes were assessed for either MTT analysis, cleaved-caspase 3 or for eNOS/iNOS or p-BAD activity using flow cytometry. In isolated hearts, artemisinin (0.1μM-100μM) showed a significant dose dependent decrease in infarct size (P<0.01-0.001 vs. I/R control). It was also shown to significantly improve cellular viability (66.5±6.3% vs. 29.3±6.1% in H/R, P<0.01) and decrease the levels of cleaved caspase-3 compared to the H/R control group (17.1±2.0% vs. 26.8±2.0% in H/R, P<0.001). Artemisinin was shown to confer protection via the activation of the PI3K-Akt-p70S6k cell survival pathway and presented an upregulation in p-eNOS and iNOS expression. Furthermore, co-administering artemisinin with doxorubicin showed artemisinin reverses I/R or H/R injury as well as doxorubicin-induced injury via the nitric oxide signalling pathway. Additionally, in HL-60 cells, the co-administration doubled artemisinins cytotoxicity while also implicating the nitric oxide pathway. This is the first study to shows that artemisinin ameliorates doxorubicin mediated cardiac injury whilst enhancing its cytotoxicity in HL-60 in a nitric oxide dependent manner. This study concluded that artemisinin was both anti apoptotic and protective against myocardial I/R injury via the PI3K-Akt-BAD/P70S6K and via the nitric oxide cell survival pathway as well as pro-apoptotic against HL-60 in a nitric oxide dependent manner.
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The role of A3 adenosine receptors in protecting the myocardium from ischaemia/reperfusion injuryHussain, A. January 2009 (has links)
Activation of A3 adenosine receptors has been shown to protect the myocardium from ischaemia reperfusion injury in a number of animal models. The PI3K - AKT and MEK1/2 - ERK1/2 cell survival pathways have been shown to play a critical role in regulating myocardial ischaemia reperfusion injury. In this study we investigated whether the A3 adenosine receptor agonist 2-CL-IB-MECA protects the myocardium from ischaemia reperfusion injury, when administered at reperfusion or post reperfusion and whether the protection involved the PI3K – AKT or MEK 1/2 – ERK1/2 cell survival pathways. In the Langendorff model of ischaemia reperfusion injury isolated perfused rat hearts underwent 35 minutes of ischaemia and 120 minutes of reperfusion. Administration of 2-CL-IB-MECA (1nM) at reperfusion significantly decreased infarct size to risk ratio compared to non-treated ischeamic reperfused control hearts. This protection was abolished in the presence of the PI3K inhibitor Wortmannin or MEK1/2 inhibitor UO126. Western blot analysis determined that administration of 2-CL-IB-MECA (1 nM) upregulated ERK1/2 phosphorylation. In the adult rat cardiac myocyte model of hypoxia/reoxygenation cells underwent 6 hours of hypoxia and 18 hours of reoxygenation. Administration of 2-CL-IB-MECA (1 nM) at the onset of reoxygenation significantly decreased cellular apoptosis and necrosis. Administration of 2-CL-IB-MECA (1nM) in the presence of the Wortmannin or UO126 significantly reversed this anti-apoptotic effect and anti-necrotic effect. Our data further showed that 2-CL-IB-MECA protects myocytes subjected to hypoxia/reoxygenation injury via decreasing cleaved-caspase 3 activity that was abolished in presence of the PI3K inhibitor but not in the presence of the MEK1/2 inhibitor UO126. Administration of 2-CL-IB-MECA (100nM) at the onset of reperfusion also significantly decreased infarct size to risk ratio in the ischaemic reperfused rat heart compared to controls that was reversed in the presence of Wortmannin or Rapamycin. This protection was associated with an increase in PI3K-AKT / p70S6K / BAD phosphorylation. 2-CL-IB-MECA (100nM) administered at reoxygenation also significantly protected adult rat cardiac myocytes from hypoxia/reoxygenation injury 28 in an anti-apoptotic and anti-necrotic manner. This anti-apoptotic/necrotic effect of 2-CL-IB-MECA was abolished in the presence Wortmannin. Furthermore, that this protection afforded by 2-CL-IB-MECA (100nM) when administered at reoxygenation was associated with a decrease in cleaved caspase 3 activity that was abolished in the presence of the Wortmannin Interestingly, postponing the administration of 2-CL-IB-MECA to 15 or 30 minutes after the onset of reperfusion significantly protected the isolated perfused rat heart from ischaemia reperfusion injury in a Wortmannin and UO126 sensitive manner. This protection was associated with an increase in AKT and ERK1/2 phosphorylation. Administration of the A3 agonist 2-CL-IB-MECA 15 or 30 minutes after the onset of reoxygenation significantly protected isolated adult rat cardiac myocytes subjected to 6 hours of hypoxia and 18 hours of reoxygenation from injury in an anti-apoptotic/necrotic manner. This anti-apoptotic was abolished upon PI3K inhibition with Wortmannin or MEK1/2 inhibition with UO126. The anti-necrotic effect of 2-CL-IB-MECA when administered 15 or 30 minutes post-reperfusion was not abolished in the presence of the inhibitors. Delaying the administration of 2-CL-IB-MECA to 15 or 30 minutes after reoxygenation was associated with a decrease in cleaved-caspase 3 activity that was abolished in the presence of Wortmannin but not in the presence of the MEK 1/2inhibitor UO126. Collectively, we have demonstrated for the first time that administration of 2-CL-IB-MECA at the onset of reperfusion protects the ischaemic reperfused rat myocardium from lethal ischaemia reperfusion injury in a PI3K and MEK1/2 sensitive manner. Delaying the administration of 2-CL-IB-MECA to 15 or 30 minutes after the onset of reperfusion of reoxygenation also significantly protects the isolated perfused rat heart from ischaemia reperfusion injury and the adult rat cardiac myocyte from hypoxia/reoxygenation injury in an anti apoptotic / necrotic manner. Furthermore, that this protection is associated with recruitment of the PI3K-AKT and MEK1/2 – ERK1/2 cell survival pathways.
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The role of the beta3-adrenergic receptor (β3-AR) in cardioprotectionAlsalhin, Aisha Khlani Hassan 12 1900 (has links)
Thesis (MScMedSc)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: It is well-established that transient activation of the β-adrenergic signalling pathway with ligands such as isoproterenol, formoterol and dobutamine, elicits cardioprotection against subsequent long periods of ischaemia. Initially the focus was on the β1- and β2-adrenergic receptors (β1-AR, β2-AR), but recently the β3-AR also emerged as a potential target in the treatment of heart disease. In heart failure, β1- and β2-AR are typically known to be down-regulated while β3-ARs, on the other hand, are up-regulated (Moniotte et al., 2001). Thus, it has become important to examine the significance of the β3-AR and its downstream signalling under similar states of stress. It has been shown that β3-AR stimulation is resistant to short term agonist-promoted desensitization in vitro and in vivo (Liggett et al., 1993) and after being activated, this receptor is able to convey continual intracellular signals (Lafontan et al., 1994). Thus, it could be an ideal target for therapeutic intervention, also in ischaemic heart disease. We hypothesized that selective β3-AR stimulation during ischaemia / reperfusion may be cardioprotective, whereas selective inhibition of this receptor may prove useful in the end stages of sustained ischaemia and early reperfusion. Methods: The isolated working rat heart, subjected to 35 min of regional ischaemia (RI) and 60 min reperfusion was used as model. The β3-AR agonist (BRL37344) (1 μM) or antagonist (SR59230A) (0.1 μM) were applied as follows: (i) before 35 min RI (PT), (ii) during the last 10 min of RI (PerT) and /or (iii) at the onset of reperfusion (PostT) and (iv) administration of BRL37344 during the last 10 min of RI BRL37344 (PerT) was followed by SR59230A during first 10 min of reperfusion SR59230A (Post). The contribution of nitric oxide synthase (NOS) in β3-AR was assessed, using the non-specific NOS inhibitor, L-NAME (50 μM). Endpoints were functional recovery and infarct size. In another set of experiments BRL37344 and SR59230A were applied according to the same protocols, but the left ventricle was dissected from the heart and freeze clamped at 10 min reperfusion for Western blot analysis of extracellular signal-regulated kinase (ERK p44/p42), protein kinase B (PKB/Akt), glycogen synthase kinase-3β (GSK-3β), and endothelial nitric oxide synthase (eNOS). Data were analyzed with one or two-way analysis of variance (ANOVA). Results: Administration of the selective β3-AR agonist (BRL37344) (1μM) before 35 min RI (BRL37344 (PT), significantly reduced infarct size when compared to the non-pretreatment group (NPT) (21.43±2.52 vs 43.17±1.20, p < 0.001). BRL37344 had similar effects on infarct size when applied during the last 10 min of regional ischaemia BRL37344 (PerT) (14.94±2.34, vs NPT, p < 0.001) or at the onset of reperfusion BRL37344 (PostT) (19.06±1.81, vs NPT, p < 0.001). When BRL37344 was applied as a (PerT+PostT) strategy, infarct size was once again significantly reduced (20.55±2.01 vs 43.17±1.20, p <0.001). In contrast, administration of the β3-antagonist SR59230A according to the same protocol did not reduce infarct size and values similar to those of untreated hearts (NPT) were obtained. Surprisingly, when BRL37344 was applied during the last 10 min of regional ischaemia followed by the administration of the β3-AR antagonist (SR59230A) at the onset of reperfusion, [BRL37344 (PerT) & SR59230A (PostT)], infarct size was significantly reduced to 20.78±3.02 (p <0.001 vs NPT and SR59230A (PerT + PostT). Involvement of nitric oxide (NO) was shown since the reduction in infarct size elicited by BRL37344 was totally abolished by, L-NAME, when administered in combination with BRL37344 for 10 minutes prior to RI or at the onset of reperfusion for 10 minutes (% infarct size: 41.48±3.18 and 35.75±3.54, p <0.001 vs BRL37344 (PT) and BRL37344 (PostT), respectively. Western blot results show that PKB/Akt is activated by BRL37344 regardless of the time of administration. The intervention BRL37344 (PerT+PostT), exhibited the most significant phosphorylation of PKB/Akt (fold increase: 14.2±3.71, p<0.01 vs NPT and p<0.05 vs BRL37344 (PostT). In addition, BRL37344 (PT), (PerT), (PostT) and [BRL37344 (PerT) +SR59230A (PostT)] showed significant activation of this kinase (2.92±0.22, 5.54±0.43, 4.73±0.47, and 6.60±0.78, respectively). ERKp44/p42 however, was not significantly activated by any of the treatments. Phosphorylation of eNOS and GSK-3β was significant only in the BRL37344 (PerT+PostT) and [BRL37344 (PerT) + SR59230A (PostT)] groups. The activation of eNOS-S-1177 in the BRL37344 (PerT+PostT) group was (2.82±0.46, p<0.01 and 0.05 vs NPT and BRL37344 (PostT), respectively) and in the [BRL37344 (PerT) + SR59230A (PostT)] group was (2.26±0.48, p<0.05 vs NPT). A very significant increased phosphorylation of GSK-3β was seen in the same two groups (68.8±7.73, p<0.001 vs NPT and 25.5±5.42 vs NPT, p<0.05, respectively). Conclusion: β3-AR has potent cardioprotective effects when administered either before, during and after ischaemia during early reperfusion as indicated by the reduction in infarct size as well as activation of PKB, GSK-3β and eNOS. These beneficial effects can be linked to NO production through activation of eNOS. / AFRIKAANSE OPSOMMING: Dit is bekend dat verbygaande aktivering van die β-adrenerge seinpad, met ligande soos isoproterenol, formoterol en dobutamien, die hart teen daaropvolgende lang periodes van iskemie beskerm. Aanvanklik was die fokus op die β1- en β2-adrenerge reseptore (β1-AR, β2-AR); maar onlangs is ook die β3-AR as 'n potensiële teiken in die behandeling van hartsiektes ge-eien. In hartversaking, is dit bekend dat β1- en β2-AR afreguleer word, terwyl β3-ARs, aan die ander kant, opreguleer word (Moniotte et al., 2001). Dit het dus belangrik geword om die belang van die β3-AR en sy stroomaf seinpad onder soortgelyke strestoestande te ondersoek. Dit is bewys dat β3-AR stimulasie teen korttermyn agonis geïnduseerde desensitisering in vitro en in vivo bestand is (Liggett et al., 1993) en wanneer geaktiveer, is hierdie reseptor in staat om intrasellulêre seine voortdurend oor te dra (Granneman, 1995). Dit kan dus ‘n ideale teiken vir terapeutiese intervensie wees, ook in iskemiese hartsiekte. Ons hipotetiseer dat selektiewe β3-AR stimulasie tydens iskemie / reperfusie kardiobeskermende mag wees, terwyl selektiewe inhibisie van hierdie reseptor effektief kan wees in die eindstadia van volgehoue iskemie en vroeë herperfusie. Metodes: Die geïsoleerde werkende rothart, onderwerp aan 35 min van streeksiskemie (SI) en 60 min herperfusie, is as model gebruik. Die β3-AR agonis (BRL37344) (1μM) of antagonis (SR59230A) (0.1 μM), is as volg toegedien: (i) voor 35 min SI (PT), (ii) gedurende die laaste 10 min van SI (PerT) en / of (iii) tydens die aanvang van herperfusie (PostT) en (iv) gedurende die laaste 10 min van SI is BRL toediening BRL37344 (PerT) gevolg deur SR59230A tydens die eerste 10 min van herperfusie SR59230A (Post). Die rol van stikstofoksiedsintase (NOS) in β3-AR is met behulp van die nie-spesifieke NOS inhibitor, L-NAME (50 μM) ondersoek. Eindpunte was funksionele herstel tydens herperfusie en infarktgrootte. In 'n ander reeks eksperimente is BRL37344 en SR59230A volgens dieselfde protokolle toegedien, maar die linker ventrikel is uit die hart gedissekteer na 10 min herperfusie en gevriesklamp vir Western klad analise van ekstrasellulêre-sein gereguleerde kinase (ERK p44/p42), proteïen kinase B (PKB/Akt), glikogeen sintase kinase-3β (GSK-3β), en endoteel stikstofoksied- sintase (eNOS). Data is met een of twee-rigting variansie analise (ANOVA) ontleed. Resultate: Administrasie van die selektiewe β3-AR agonis (BRL37344) (1μM) voor 35 min SI BRL37344 (PT), het die infarktgrootte beduidend verminder vergeleke met die nie-behandelde groep (NPT) (21.43±2.52 vs 43.17±1.20, p<0.001). BRL37344 het ‘n soortgelyke effek op infarktgrootte wanneer dit gedurende die laaste 10 min van streeksiskemie BRL37344 (PerT) (14.94±2.34, vs NPT, p<0.001) of by die aanvang van herperfusie (BRL37344 (PostT) (19.06±1.81, vs NPT, p<0.001) toegedien word. Wanneer BRL37344 as 'n (PerT+PostT) strategie toegedien is, was infarktgrootte weereens beduidend verlaag (20.55±2.01 vs 43.17±1.20, p<0.001). In teenstelling hiermee, het administrasie van die β3-antagonis SR59230A volgens dieselfde protokol, nie infarktgrootte verminder nie en waardes soortgelyk aan dié van onbehandelde harte (NPT) is verkry. Interessant, wanneer BRL37344 gedurende die laaste 10 min van streeksiskemie toegedien is, gevolg deur die administrasie van die β3-AR antagonis (SR59230A) by die aanvang van herperfusie, [BRL37344(PerT) & SR59230A(PostT)], was infarktgrootte aansienlik verminder tot 20.78±3.02 (p<0.001 vs NPT en SR59230A (PerT+PostT). Die betrokkenheid van stikstofoksied (NO) is waargeneem deurdat die vermindering in infarktgrootte ontlok deur BRL37344, heeltemal deur L-NAME opgehef is, wanneer dit in kombinasie met BRL37344 vir 10 minute voor SI of by die aanvang van herperfusie vir 10 minute toegedien is (% infarktgrootte: 41.48±3.18 en 35.75±3.54, p<0.001 vs BRL37344 (PT) en BRL37344 (PostT) onderskeidelik). Western kladresultate toon dat PKB/Akt deur BRL37344 geaktiveer word ongeag die tyd van die administrasie. Die intervensie BRL37344 (PerT+PostT), toon die mees beduidende fosforilering van PKB/Akt (voudige toename: 14.2±3.71, p<0.01 vs NPT en p<0.05 vs BRL37344 (PostT). Daarbenewens het BRL37344 (PT), (PerT), (PostT) en [BRL37344 (PerT) + SR59230A (PostT)] ook beduidende aktivering van hierdie kinase tot gevolg gehad (2.92±0.22, 5.54±0.43, 4.73±0.47 en 6.60±0.78, onderskeidelik). ERKp44/p42 is egter nie deur enige van die behandelings geaktiveer nie. Fosforilering van eNOS en GSK-3β was net beduidend in die BRL37344 (PerT+PostT) en [BRL37344 (PerT) + SR59230A (PostT)] groepe. Die aktivering van eNOS-S-1177 was beduidend in die BRL37344 (PerT+PostT) en [BRL37344 (PerT) + SR59230A (PostT)] groepe. 'n Baie beduidende toename in fosforilering van GSK-3β is in dieselfde twee groepe (68.8±7.73, p<0.001 en 25.5±5.42, p<0.05 vs NPT onderskeidelik) waargeneem. Gevolgtrekking: β3-AR het kragtige kardiobeskermende effekte wanneer dit, hetsy voor, tydens en na iskemie gedurende vroeë herperfusie toegedien word, soos deur die vermindering in infarktgrootte sowel as die aktivering van PKB, GSK-3β en eNOS aangedui is. Hierdie voordelige effekte kan aan NO produksie deur aktivering van eNOS gekoppel word.
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Novel therapies in acute kidney injuryMemon, Shoab Ahmed January 2015 (has links)
Renal ischaemia-reperfusion injury (IRI) is a major cause of acute kidney injury (AKI) which is in turn the leading cause of morbidity and mortality in hospitalized patients. The principle aim of this thesis was to evaluate potential new therapies that might afford protection against IRI in both in vitro and in vivo settings. Recent evidence suggests that nitrite (NO2-) may play an important role in protecting the myocardium from IRI. Our initial work into the role of NO2- in an in vitro model of renal IRI in proximal tubular epithelial cells provided evidence that NO2- can prevent apoptosis and preserve cell viability. This lead to an in vivo study where high NO2- concentrations (50 mg/L) were given orally to rats for 7 days prior to inducing renal IRI but no beneficial effects of this treatment were observed. Another potential treatment identified was thiamine (vitamin B1) and this, like NO2-was investigated to see if it had the potential to protect rats from AKI injury. It has been previously recognized that in renal IRI the high energy phosphate ATP is found to be severely depleted whilst is is known that thiamine can play a pivotal role in generating ATP. Furthermore, thiamine has previously been demonstrated to protect against myocardial ischaemic injury and has the ability to reduce myocardial infarct size. In vitro, thiamine was found to reduce the degree of apoptosis in cultured HK-2 cells caused by ischaemia whilst in vivo it afforded protection against AKI caused by renal IRI by anti-apoptotic, anti-inflammatory and anti-oxidant mechanisms. Finally, a study into the possible therapeutic role of gene therapy with bone morphogenic protein 7 (BMP-7) in renal IRI was undertaken. Previous work has established that i.v. BMP-7 is able to protect against renal IRI but it has also been associated with ectopic bone formation at the site of injection. Therefore another method to increase circulating BMP-7 was sought. We initially found that BMP-7 gene therapy could attenuate apoptosis and preserves cell viability in an in vitro model of renal IRI. However, whilst in vivo gene therapy with electroporation of BMP-7 plasmid DNA increased BMP-7 expression in mice serum 2 days post electroporation, it was unable to protect the animals against IRI induced AKI. In rats the direct injection of naked DNA BMP-7 plasmid systematic 2 days prior to renal IRI was able to upregulate BMP-7 expression 4 days later in kidney tissue. Despite this it was unable to afford protection against renal IRI. Apoptosis and necrosis play a crucial role in the pathogenesis of renal IRI induced AKI. In this thesis we investigated the role of three putative therapeutic agents and their role in apoptosis and necrosis in vitro in PTECs and in vivo against renal IRI induced AKI. All three therapeutic drugs were able to attenuate apoptosis in PTECs but were unable to protect against necrosis, whilst against renal IRI induced AKI only thiamine was found to be protective. Thiamine appears to hold the most promise and more work needs to be undertaken so that its potential benefit in AKI can be realised.
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Evaluation of a novel mitochondria-targeted anti-oxidant therapy for ischaemia-reperfusion injury in renal transplantationHamed, Mazin Osman January 2017 (has links)
Ischaemia-reperfusion (IR) injury makes a major contribution to graft damage during kidney transplantation and increases the risks of primary non-function, delayed graft function and rejection. Oxidative damage to mitochondria is a key early event in IR injury. The aim of this project was to examine the safety and efficacy of the mitochondria-targeted antioxidant MitoQ in reducing pig and human kidney IR injury using an ex vivo normothermic perfusion (EVNP) system. Over a range of 500 nM to 250 µM using a 150 pig kidneys and 80 declined deceased human kidneys, MitoQ was successfully taken up by pig and human kidneys in a concentration-dependent manner, resulting in stable tissue concentrations over 24 hours of cold storage followed by 6 hours of EVNP. The uptake of MitoQ was increased approximately 2-fold when MitoQ was administered to warm (rather than cold) kidneys and when kidneys were preserved using hypothermic machine perfusion (rather than cold static storage). 50 µM MitoQ, administered to pig kidneys at the end of warm ischaemia, significantly increased renal blood and urine output flow at the end of 6 h EVNP compared to the control group. Creatinine clearance was numerically higher in the 50 µM MitoQ group compared to the control group but the difference did not reach statistical significance. To test the safety and efficacy of MitoQ in human kidney IRI, pairs of declined deceased human kidneys were used, with one kidney in each pair used as control. The total urine output, creatinine clearance and percentage fall of serum creatinine were numerically higher in the 50 µM MitoQ group compared to the control group, although the differences did not reach statistical significance during 3 h of EVNP. There was a significant difference in the renal blood flow between the 50 µM MitoQ group and the control group at the end of the first hour of EVNP. The renal blood flow remained relatively stable during the first hour of EVNP in the 50 µM MitoQ group compared to a significant decrease in renal blood flow in the control group. There was no effect on fractional excretion of sodium or oxidative injury markers (protein carbonyl formation, lipid peroxidation) in pig or human kidneys, which is consistent with previous studies that demonstrated the requirement of >24 hour after reperfusion for manifestation of changes in these parameters. In this thesis, I was able to successfully demonstrate the safety and potential efficacy of MitoQ in ameliorating renal IRI using pig kidneys. While more declined deceased human kidneys need to be analysed to fully explore the potential efficacy of MitoQ in ameliorating renal IRI, this study provides important data that will help inform future studies and ultimately a clinical trial for assessing the efficacy of the mitochondria-targeted antioxidant MitoQ in human kidney transplantation. My findings suggest that MitoQ has the potential to increase the use of marginal kidneys and to improve graft and patient outcomes.
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HOT study : the development, management and results from phase IIB, randomised controlled trial of heme arginate in recipients of deceased donor renal transplantsThomas, Rachel Alexandra Barclay January 2016 (has links)
Aims There are few proven therapies that can protect against the inevitable ischaemia reperfusion injury (IRI) that occurs during renal transplantation. IRI increases the likelihood of delayed graft function (DGF), which negatively impacts on the long-term survival of a transplanted kidney. One enzyme of interest, heme oxygenase-1 (HO-1), degrades heme and protects against the oxidative stress that occurs secondary to IRI. Clinical renal recipients with higher HO-1 levels have improved graft function post transplant. Heme arginate (HA), a form of hemin, which has been used to treat porphyria for over 30 years, has repeatedly been shown to induce HO-1 in in vivo and in vitro macrophages. It is one of the few HO-1 inducers approved for clinical use and healthy volunteer studies confirmed that HA could also safely induce HO-1 in humans. Prior to the formal start of the MD, the University of Edinburgh successfully applied to NHS Blood and Transplant for funding to investigate whether giving HA to recipients of deceased donor renal grafts prior to transplant could upregulate HO-1 and whether this had any effect on the function and health of the grafts. This MD aims to explain the background behind the proposed study, the process of study approval, planning and trial logistics and protocol. This thesis then describes the methods of sample analysis, the results and future directions for the HOT (Heme Oxygenase-1 in renal Transplantation) study. Methods The HOT study planning and approval process took eight months and the first participant was randomised in January 2012. The study was sponsored by ACCORD, a joint company from University of Edinburgh and NHS Lothian, and recruited patients from the Edinburgh Royal Infirmary Transplant Unit. The protocol was followed to ensure that 40 recipients were randomised blind to either active (two doses 3mg kg-1 HA: pre-operatively, day 2) or placebo (NaCl: same schedule). To ensure that the primary outcome was fulfilled, recipient blood was taken daily for peripheral blood mononuclear cells (PBMC) extraction. After further blinding steps, the PBMCs were analysed for HO-1 protein and mRNA. The secondary outcome measures involved collecting urine for analysis of urinary biomarkers (KIM-1 and NGAL), taking renal graft biopsies pre-op and day 5 for renal HO-1 analysis and collecting renal function data. DGF was calculated daily. To ensure that all adverse event data was captured, the recipients were closely reviewed for 7 days and their renal function was monitored for 90 days. Results The final participant was recruited in May 2013 within the predicted timescale and to budget. This participant completed follow-up in August 2013. Of the 40 participants, three received the infusion but did not receive a transplant and therefore could not give primary outcome data. The remaining 37 did and this was analysed. Adverse events were equivalent between groups and there were no adverse reactions to HA. HA upregulated PBMC HO-1 protein at 24 hours compared to placebo: HA 11.1ng/ml (1.0- 37.0) vs. placebo 0.14ng/ml (-0.7- 0.3)(p= < 0.0001). PBMC HO-1 mRNA was also increased: HA 2.73 fold (1.8- 3.2) vs. placebo 1.41 fold (1.2- 2.2) (p=0.02). HA increased HO-1 protein immunopositivity in day 5 renal tissue compared with placebo: HA 0.21 (-24- 0.7) vs. placebo -0.03 (-76- 0.15) (p=0.02) and the percentage of HO-1 positive renal macrophages also increased: HA 50.8 cells per HPF (40.0- 59.8) vs. placebo 22.3 (0- 34.8) (p=0.012). Renal HO-1 mRNA was also increased in HA group: 2.02 (0.20- 4.03) fold increase compared to 1.68 (0.75- 10.39) fold in the placebo group but it was not significant (p= 0.451). Urinary biomarkers were reduced after HA but not significantly so. Histological injury and DGF rates were similar between the groups. Conclusion HA is safe and effective in renal transplant recipients as reported in this phase II, randomised, placebo controlled, blinded, single-centre study. The primary outcome was achieved and demonstrated for the first time that HA induces HO-1 in peripheral and renal macrophages in kidney transplant recipients. There was also evidence that HA increased HO-1 expression in renal tissue. There was no evidence that HA improved renal function or reduced injury as seen in animal models but it is recognised that the sample size was small and the study was not powered to these endpoints. Larger studies are planned to determine the impact of HO-1 upregulation on clinical outcomes and evaluate the benefit to patients at risk of IRI. The plans for HOT2 are expanded in this thesis.
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Adenosine and Ischaemia in Young To Aged HeartsWillems, Laura E, n/a January 2006 (has links)
Ischaemic heart disease is a major contributor to premature death and heart failure in the Westernised world. Ischaemic injury within the heart may be beneficially modulated by the nucleoside adenosine. Derived from catabolism of ATP, adenosine was initially known as a potent bradycardic and hypotensive agent. However, more recently the protective function of adenosine has been investigated. The protective effects of adenosine are mediated via activation of adenosine receptors: A1, A2A, A2B, and A3 receptors. Activation of these potentially protective (or retaliatory) adenosine receptors hinges upon accumulation of adenosine during ischaemia-reperfusion. This Thesis examines the role and mechanisms of adenosine mediated cardioprotection in young and aged hearts, exploring endogenous and exogenous adenosine receptor activation, genetic manipulation of A1 receptors and adenosine deaminase and pharmacological manipulation of adenosine metabolism. The effects of age on ischaemic responses and adenosine handling and protection are also assessed. The core approach to assess each of the above issues involved the Langendorff isolated mouse heart preparation. Experiments within Chapter 3 focuses on the contractile effects of adenosine receptors in normoxic hearts. This study indicates A2A receptors have no direct effect on contractility, while adenosine exerts positive inotropy independently of coronary flow and perfusion pressure (i.e. Independent of the Gregg phenomenon). In addition, investigations in genetically modified hearts hint at positive inotropy in response to A1 receptors. Since the latter is only evidenced in modified lines, it is possible A1-mediated inotropy may be abnormal or supraphysiological. In Chapter 4 the impact of genetic 'deletion' of A1ARs and/or adenosine deaminase (ADA) on intrinsic tolerance to ischaemia were studied. Data demonstrate that genetic deletion of A1 receptors significantly limits the ability of the mouse myocardium to withstand injury during ischaemic insult. Thus, providing strong support for a role of A1ARs in determining intrinsic tolerance to ischaemia-reperfusion. ADA KO mice confirm protection afforded by endogenous adenosine and the notion of adenosine metabolism modification as a protective strategy. Interestingly, effects of A1AR KO differ from A1AR overexpression or A1AR agonism in that the latter decrease contractile diastolic dysfunction while A1AR KO selectively increase systolic dysfunction and increase oncosis without altering diastolic injury. This challenges current dogma regarding the action of A1 adenosine receptors on ischaemic injury. In Chapter 5 the effects of adenosine metabolism inhibition (via adenosine deaminase (ADA) and adenosine kinase (AK) inhibitors) were studied. Inhibition of adenosine deaminase with the drug EHNA, and adenosine phosphorylation with iodotubercidin significantly protected mouse hearts from ischaemia-reperfusion, reducing contractile dysfunction and cardiac enzyme efflux. However, inhibitors failed to improve the outcome of the aged myocardium. 8-SPT and 5-HD reduced the protective effects of EHNA and iodotubercidin demonstrating thus; cardioprotection via ADA and AK appears to rely on adenosine receptor activation and involves a mitoK ATP dependent mechanism. Since aging is of considerable importance with regard to outcomes of ischaemic heart disease, experiments in Chapter 6 focused on effects of aging (and gender) on cardiovascular function and injury during ischaemia-reperfusion. In assessing post ischaemic outcomes in hearts from young adult (2-4 months), mature adult (8 months), middle aged (12 months), aged (18 months) and senescent (24-28 months) C57/BL/6J mice, data reveal a substantial age-related decline in ischaemic tolerance (which appears selective for myocardial vs. vascular injury). The decline in ischaemic tolerance is expressed primarily within the initial 12 months in both males and females with relatively little further decline with continued aging. There is evidence of a modest improvement in tolerance in senescence vs. aged hearts possibly reflecting selection of a protected phenotype in senescent populations. In addition, mature and middle-aged female hearts showed improved tolerance to ischaemia-reperfusion compared to males, supporting a role for hormonal changes. Effects of aging and purine metabolism were studied in Chapter 7. Data suggest impaired tolerance to ischaemia-reperfusion in older hearts may stem in part from shifts in myocardial purine catabolism. Data reveal reduced accumulation of salvageable and cardioprotective adenosine and enhanced accumulation of poorly salvaged (and potentially injurious) hypoxanthine and xanthine. These changes may potentially predispose the aged myocardium to ischaemic injury and radical generation via the xanthine oxidase reaction. The final data Chapter of this Thesis describes preliminary data regarding aging, signalling and adenosine mediated protection. It was found that protein kinase C (PKC) and A1 receptors mediate protection in young hearts and also that A1 receptors appear to mediate protection via a PKC LindependentLi signalling cascade. In addition, experiments in aged hearts (attempting to elucidate mechanisms behind impaired adenosinergic protection with age) suggest a PKC-independent A1-mediated protection path may be preserved with aging, since A1 receptors continue to offer some protection while PKC activation does not. It is possible the failure of exogenous adenosine to offer protection in aged hearts may result from a lesion at or downstream of PKC.
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Optimising the quality of donor organs for transplantation: studies of hormone resuscitation of the brain-dead multi-organ donor and the development of a long-term preservation strategy to optimise function of the transplanted heart in a porcine modelHing, Alfred , Victor Chang Cardiac Research Institute, Faculty of Medicine, UNSW January 2009 (has links)
Brain death has adverse effects on the organ donor, increasing organ dysfunction and affecting transplantation outcomes. It can also render organs unsuitable for transplantation. Another determinant of organ quality is ischaemia-reperfusion injury, which limits ischaemic storage time for hearts to six hours. The aim of this thesis was to investigate the effectiveness of hormone resuscitation (HR) of the donor to ameliorate the effects of brain death. Another aim was to develop a donor management and organ preservation strategy to ameliorate the effects of ischaemia-reperfusion injury on the heart, thereby extending ischaemic preservation times. A porcine model of the brain-dead multi-organ donor with orthotopic cardiac transplantation was utilised. Donor HR was shown to improve cardiac contractility and haemodynamics, thereby reducing inotrope requirements. A follow-up study investigating the effects of three different donor management protocols demonstrated that donor haemodynamics, renal arterial flow and creatinine clearance were superior in HR animals compared with animals treated with noradrenaline or intravenous fluid alone. Noradrenaline was associated with a significant deterioration in pulmonary function (PaO2 and alveolar-arterial oxygen gradient) and a decline in donor pH. HR was not associated with any detrimental effects on the lungs, liver or pancreas compared with the other two groups. Preservation strategies incorporating glyceryl trinitrate (GTN) and cariporide, a Na+-H+ exchange inhibitor, were investigated to safely extend cardiac ischaemic preservation times. Pre-treatment with intravenous cariporide prior to heart explantation (donor) and reperfusion of the transplanted heart (recipient) was shown to effectively extend ischaemic time to 14 hours, evidenced by weaning off cardiopulmonary bypass. GTN and cariporide-supplemented Celsior, used as a cardioplegic/storage solution, was also effective in extending preservation time to 14 hours, with superior cardiac contractility compared with cariporide pre-treated hearts. Both treatments also ameliorated reperfusion injury, stabilising haemodynamics for up to three hours post-bypass. This thesis has demonstrated the effectiveness of HR to ameliorate the negative effects of donor brain death. It also provides evidence that combined GTN and cariporide-supplemented Celsior improves long-term preservation of the donor heart. These strategies offer the potential to increase the proportion of transplantable organs, to improve donor organ quality, and thereby improve transplantation outcomes.
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Cardioprotective effects of Glucagon-like Peptide 1 (GLP-1) and their mechanismsGiblett, Joel Peter January 2017 (has links)
Background: Glucagon-like Peptide 1 (GLP-1) is a human incretin hormone that has been demonstrated to protect against non-lethal ischaemia reperfusion injury in the left ventricle in humans. It has been suggested from some animal research that this protection may be mediated through the pathway of ischaemic conditioning, of which the opening of the mKATP channel is a key step. Furthermore, it is uncertain whether the protection applies to the right ventricle. Finally, there is limited human evidence of a protective effect against lethal ischaemia reperfusion injury. Methods: Two studies use non-lethal ischaemia to test whether GLP-1 protection is maintained despite blockade of the mKATP channel with the sulfonylurea, glibenclamide. A demand ischaemia study uses dobutamine stress echo to compare LV function. The other uses transient coronary balloon occlusion to generate supply ischaemia during GLP-1 infusion, assessed by conductance catheter. A further transient balloon occlusion is also used to assess the effect of supply ischaemia on RV function. Finally, the GOLD PCI study assesses whether GLP-1 protects against periprocedural myocardial infarction when administered during elective PCI in a randomised, placebo controlled double blind trial. Results: Glibenclamide did not affect GLP-1 cardioprotection in either supply of demand ischaemia suggesting that GLP-1 protection is not mediated through the mKATP channel. The RV experienced stunning with RCA balloon occlusion but there was little evidence of cumulative ischaemic dysfunction with further occlusions. GOLD PCI is continuing to recruit patients. The nature of the study means results cannot be assessed until recruitment is complete. Conclusions: GLP-1 is an agent with potential for clinical use as a cardioprotective therapy. It’s mechanism of action in the heart remains uncertain.
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