РефератыИностранный языкPrProlonged Preservation Of The Heart Prior To

Prolonged Preservation Of The Heart Prior To

Transplantation Essay, Research Paper


Biochemistry


Prolonged Preservation of the Heart Prior to Transplantation


Picture this. A man is involved in a severe car crash in


Florida which has left him brain-dead with no hope for any


kind of recovery. The majority of his vital organs are


still functional and the man has designated that his organs


be donated to a needy person upon his untimely death.


Meanwhile, upon checking with the donor registry board, it


is discovered that the best match for receiving the heart of


the Florida man is a male in Oregon who is in desperate need


of a heart transplant. Without the transplant, the man will


most certainly die within 48 hours. The second man’s


tissues match up perfectly with the brain-dead man’s in


Florida. This seems like an excellent opportunity for a


heart transplant. However, a transplant is currently not a


viable option for the Oregon man since he is separated by


such a vast geographic distance from the organ. Scientists


and doctors are currently only able to keep a donor heart


viable for four hours before the tissues become irreversibly


damaged. Because of this preservation restriction, the


donor heart is ultimately given to someone whose tissues do


not match up as well, so there is a greatly increased chance


for rejection of the organ by the recipient. As far as the


man in Oregon goes, he will probably not receive a donor


heart before his own expires.


Currently, when a heart is being prepared for


transplantation, it is simply submerged in an isotonic


saline ice bath in an attempt to stop all metabolic activity


of that heart. This cold submersion technique is adequate


for only four hours. However, if the heart is perfused with


the proper media, it can remain viable for up to 24 hours.


The technique of perfusion is based on intrinsically simple


principles. What occurs is a physician carefully excises


the heart from the donor. He then accurately trims the


vessels of the heart so they can be easily attached to the


perfusion apparatus. After trimming, a cannula is inserted


into the superior vena cava. Through this cannula, the


preservation media can be pumped in.


What if this scenario were different? What if doctors were


able to preserve the donor heart and keep it viable outside


the body for up to 24 hours instead of only four hours? If


this were possible, the heart in Florida could have been


transported across the country to Oregon where the perfect


recipient waited. The biochemical composition of the


preservation media for hearts during the transplant delay is


drastically important for prolonging the viability of the


organ. If a media can be developed that could preserve the


heart for longer periods of time, many lives could be saved


as a result.


Another benefit of this increase in time is that it would


allow doctors the time to better prepare themselves for the


lengthy operation. The accidents that render people


brain-dead often occur at night or in the early morning.


Presently, as soon as a donor organ becomes available,


doctors must immediately go to work at transplanting it.


This extremely intricate and intense operation takes a long


time to complete. If the transplanting doctor is exhausted


from working a long day, the increase in duration would


allow him enough time to get some much needed rest so he can


perform the operation under the best possible circumstances.


Experiments have been conducted that studied the effects of


preserving excised hearts by adding several compounds to the


media in which the organ is being stored. The most


successful of these compounds are pyruvate and a pyruvate


containing compound known as


perfluoroperhydrophenanthrene-egg yolk phospholipid


(APE-LM). It was determined that adding pyruvate to the


media improved postpreservation cardiac function while


adding glucose had little or no effect. To test the


function of these two intermediates, rabbit hearts were


excised and preserved for an average of 24.5 1 0.2 hours on


a preservation apparatus before they were transplanted back


into a recipient rabbit. While attached to the preservation


apparatus, samples of the media output of the heart were


taken every 2 hours and were assayed for their content. If


the compound in the media showed up in large amounts in the


assay, it could be concluded that the compound was not


metabolized by the heart. If little or none of the compound


placed in the media appeared in the assay, it could be


concluded that compound was used up by the heart metabolism.


The hearts that were given pyruvate in their media


completely consumed the available substrate and were able to


function at a nearly normal capacity once they were


transplanted. Correspondingly, hearts that were preserved


in a media that lacked pyruvate had a significantly lower


rate of contractile function once they were transplanted.


The superior preservation of the hearts with pyruvate most


likely resulted from the hearts use of pyruvate through the


citric acid cycle for the production of energy through


direct ATP synthesis (from the reaction of succinyl-CoA to


succinate via the enzyme succinyl CoA synthetase) as well


as through the production of NADH + H+ for use in the


electron transport chain to produce energy.


After providing a preservation media that contained


pyruvate, a better recovery of the heart tissue occurred.


Most of the pyruvate consumed during preservation was


probably oxidized by the myocardium in the citric acid


cycle. Only a small amount of excess lactate was detected


by the assays of the preservation media discharged by the


heart. The lactate represented only 15% of the pyruvate


consumed. If the major metabolic route taken by pyruvate


during preservation had been to form lactate dehydrogenase


for regeneration of NAD+ for continued anaerobic glycolysis,


rather than by the aerobic citric acid cycle (pyruvate


oxidation), then a higher ratio of excess lactate produced


to pyruvate consumed would have been observed.


Hearts given a glucose substrate did not transport or


consume that substrate, even when it was provided as the


sole exogenous substrate. It m

ight be expected that glucose


would be used up in a manner similar to that of pyruvate.


This expectation is because glucose is a precursor to


pyruvate via the glycolytic pathway however, this was not


the case. It was theorized this lack of glucose use may


have been due to the fact that the hormone insulin was not


present in the media. Without insulin, one may think the


tissues of the heart would be unable to adequately take


glucose into their tissues in any measurable amount, but


this is not the case either. It is known that hearts


working under physiologic conditions do use glucose in the


absence of insulin, but glucose consumption in that


situation is directly related to the performance of work by


the heart, not the presence of insulin.


To further test the effects of the addition of insulin to


the glucose media, experiments were done in which the


hormone was included in the heart preservation media5-7.


Data from those studies does not provide evidence that the


hormone is essential to insure glucose use or to maintain


the metabolic status of the heart or to improve cardiac


recovery. In a hypothermic (80C) setting, insulin did not


exert a noticeable benefit to metabolism beyond that


provided by oxygen and glucose. This hypothermic setting is


analogous to the setting an actual heart would be in during


transportation before transplant.


Another study was done to determine whether the compound


perfluoroperhydrophenanthrene-egg yolk phospholipid,


(APE-LM) was an effective media for long-term hypothermic


heart preservation3. Two main factors make APE-LM an


effective preservation media. (1) It contains a lipid


emulsifier which enables it to solubilize lipids. From this


breakdown of lipids, ATP can be produced. (2) APE-LM


contains large amounts of pyruvate. As discussed earlier,


an abundance of energy is produced via the oxidation of


pyruvate through the citric acid cycle.


APE-LM-preserved hearts consumed a significantly higher


amount of oxygen than hearts preserved with other media.


The higher oxygen and pyruvate consumption in these hearts


indicated that the hearts had a greater metabolic oxidative


activity during preservation than the other hearts. The


higher oxidative activity may have been reflective of


greater tissue perfusion, especially in the coronary beds,


and thereby perfusion of oxygen to a greater percentage of


myocardial cells. Another factor contributing to the


effectiveness of APE-LM as a transplantation media is its


biologically compatible lipid emulsifier, which consists


primarily of phospholipids and cholesterol. The lipid


provides a favorable environment for myocardial membranes


and may prevent perfusion-related depletion of lipids from


cardiac membranes. The cholesterol contains a bulky steroid


nucleus with a hydroxyl group at one end and a flexible


hydrocarbon tail at the other end. The hydrocarbon tail of


the cholesterol is located in the non polar core of the


membrane bilayer. The hydroxyl group of cholesterol


hydrogen-bonds to a carbonyl oxygen atom of a phospholipid


head group. Through this structure, cholesterol prevents


the crystallization of fatty acyl chains by fitting between


them. Thus, cholesterol moderates the fluidity of


membranes.8


The reason there are currently such strict limits on the


amount of time a heart can remain viable out of the body is


because there must be a source of energy for the heart


tissue if it is to stay alive. Once the supply of energy


runs out, the tissue suffers irreversible damage and dies.


Therefore, this tissue cannot be used for transplantation.


If hypothermic hearts are not given exogenous substrates


that they can transport and consume, like pyruvate, then


they must rely on glycogen or lipid stores for energy


metabolism. The length of time that the heart can be


preserved in vitro is thus related to the length of time


before these stores become too low to maintain the required


energy production needs of the organ. It is also possible


that the tissue stores of ATP and phosphocreatine are


critical factors. It is known that the amount of ATP in


heart muscle tissues is sufficient to sustain contractile


activity of the muscle for less than one second. This is


why phosphocreatine is so important. Vertebrate muscle


tissue contains a reservoir of high-potential phosphoryl


groups in the form of phosphocreatine. Phosphocreatine can


transfer its phosphoryl group to ATP according to the


following reversible reaction:


phosphocreatine + ADP + H+ 9 ATP + creatine


Phosphocreatine is able to maintain a high concentration of


ATP during periods of muscular contraction. Therefore, if


no other energy producing processes are available for the


excised heart, it will only remain viable until its


phosphocreatine stores run out.


A major obstacle that must be overcome in order for heart


transplants to be successful, is the typically prolonged


delay involved in getting the organ from donor to recipient.


The biochemical composition of the preservation media for


hearts during the transplant and transportation delays are


extremely important for prolonging the viability of the


organ. It has been discovered that adding pyruvate, or


pyruvate containing compounds like APE-LM, to a preservation


medium greatly improves post-preservation cardiac function


of the heart. As was discussed, the pyruvate is able to


enter the citric acid cycle and produce sufficient amounts


of energy to sustain the heart after it has been excised


until it is transplanted.


Increasing the amount of time a heart can remain alive


outside of the body prior to transplantation from the


current four hours to 24 hours has many desirable benefits.


As discussed earlier, this increase in time would allow


doctors the ability to better match the tissues of the donor


with those of the recipient. Organ rejection by recipients


occurs frequently because their tissues do not suitably


match those of the donors. The increase in viability time


would also allow plenty of opportunity for the organ to be


transported to the needy person, even if it must go across


the country.


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