1GKT Medical School, Kings College London, St Thomas Hospital, London SE1 7EH, UK. 2Russells Hall Hospital, Dudley, West Midlands DY1 2HQ, UK
Keywords: metabolism, diabetes; complications; metabolism, insulin; hormones; anaesthesia; surgery
![]() |
Introduction |
---|
The results of pancreas extirpation and pancreas grafting are best explained by supposing that the islet tissue produce an Autacoid which passes into the blood stream and effects carbohydrate metabolism and carbohydrate storage in such a manner that there is no undue accumulation of glucose in the blood. Provisionally it will be convenient to refer to this hypothetical substance as insuline.
Sir Edward Schafer, The Endocrine Organs (1916)
![]() |
Historical background |
---|
It must however be stated that it has yet to be determined whether the active substance is produced as such in the pancreas or whether it exists there as pro-insuline which becomes elsewhere converted into the active autacoid.
Insulin was discovered 8 yr later by Banting and Best in 1921. The first patient was treated a year later in 1922 and pro-insulin was discovered (and re-named) more than 50 yr later by George Steiner of the University of Chicago in 1967.
Schafer deliberately avoided using the word hormone and used his preferred terms autacoid and chalone. This was as a result of long-standing academic rivalry with his contemporaries Professors Baylis and Starling at University College, London. They had previously described secretin as the first hormone to be isolated and characterized. They had coined the term hormones to describe the class of substance produced in one part of the body and acting elsewhere. Schafer preferred his own terms, which were based on terms used at the time to describe actions of drugs, autacoid being a substance with excitatory action and chalone one with inhibitory action.
Schafer went on to describe how insuline had both excitatory and inhibitory actions. His description of how he thought the hypothetical substance insuline acted in the body is remarkable because the passage of time has shown him to be correct almost word for word. Things have been confused, however, by a 20 yr black age of endocrinology (between approximately 1960 and 1980), where leading scientiststhrough extrapolating beyond their new discoveriesconfused scientific thinking and teaching. They formulated new hypotheses based for the first time on hard scientific evidence but they got it badly wrong through extrapolating (incorrectly) from in vitro experimental data in rat tissues to in vivo metabolism in humans.
The effects of this black age are still with us because these incorrect hypotheses have, with the passage of time, been turned into dogma and become cast into tablets of stone in undergraduate textbooks. They are also carried forward into postgraduate teaching. For example, even in well respected texts it is still common to find statements such as The basic action of insulin is to facilitate glucose entry into cells, primarily skeletal muscle and hepatocytes.1
![]() |
Purpose of this review |
---|
![]() |
Insulin as an autacoid and chalone |
---|
|
![]() |
The nature of fasting hyperglycaemia |
---|
When this question was posed to participants of the Royal College of Anaesthetists Basic Science Course in 1998 and 1999, a show of hands revealed virtually unanimous support for the second alternative, with only one or two hands in favour of the correct answer (overproduction of glucose by the liver). This is a typical response, seen from the overwhelming majority of both undergraduate and postgraduate audiences in the UK and the rest of the world. It is important to have the right understanding if insulin is to be used appropriately and to maximum benefit. This may perhaps seem a trivial or pedantic point but it is not. Correct understanding of what goes wrong with metabolism in the face of insulin deficiency is essential in the understanding and execution of logical and safe forms of treatment.
Fasting normoglycaemia
Consider a person with a normal fasting blood glucose concentration of 5 mmol litre1. The stable fasting blood glucose concentration conceals an underlying dynamic steady state where the glucose that is continuously being cleared from the circulation for metabolism is exactly matched by new glucose being added by the liver. This dynamic steady state is normally controlled very tightly by insulin. Glucose input into the circulation (rate of appearance, or Ra) is normally approximately 12 µmol kg1 min1 (2 mg kg1 min1), and in the fasting state is exclusively from the liver, exactly matches glucose disposal in peripheral tissues (rate of disappearance, or Rd). The main contributors to glucose disappearance (or clearance) in the fasting, resting state are the brain (~50%), lean tissues (~30%), adipose tissue (~10%) and red blood cells (~10%). This is illustrated in Fig. 2.
|
It is now easy to measure Ra and Rd experimentally and thus answer the question posed at the beginning of this section. Initially, this was done by injecting radioactive (14C- or 3H-labelled) glucose and measuring the rate at which it was diluted with unlabelled glucose from the liver (the concentration of glucose remains constant but the concentration of 14C- or 3H-labelled glucose falls exponentially with time). It is quite easy to calculate accurately the actual rates of glucose production and utilization from this isotope dilution curve. It is now possible to make these measurements without the need for radioactive tracers, using instead glucose labelled with a natural stable isotope of carbon (13C), thus avoiding any radiation hazard and even allowing research on diabetes in pregnancy.
In the fasting state, virtually all glucose Ra comes from the liver, from a combination of glycogenolysis and gluconeogenesis. When hepatic glycogen stores are plentiful, most glucose comes from glycogenolysis, but as the hepatic glycogen stores become depleted, more comes from gluconeogenesis. After 24 h of starvation, hepatic glycogen stores are completely exhausted and all glucose production comes from gluconeogenesis (muscle glycogen cannot contribute to blood glucose as there is no glucose-6-phosphatase in muscle and glucose transporters cannot transport glucose 6-phosphate out of muscle. The kidney may, on occasions, make a minor contribution to gluconeogenesis.)
Experimental observations in people with newly diagnosed diabetes or in insulin-withdrawn patients with both type 1 and type 2 diabetes have shown that there is a strongly positive relationship between the fasting blood glucose concentration and the rate of hepatic glucose production (Ra). This was first shown in the early 1970s in animals and in the mid-1970s in humans.3 It is illustrated in Fig. 3.
|
![]() |
The normal fastingfeeding cycle (energy metabolism) |
---|
The fact that fasting blood glucose concentration remains constant over minutes and hours reflects an exact balance between input and output of glucose from the circulation (Ra=Rd). In non-diabetics, all of Rd is going to metabolism, so the hormonal control mechanisms are geared to releasing sufficient glucose to match the bodys need. This is a very basic and robust process, so that a healthy individual can survive a remarkably long time without eating, so long as they have access to water. Hypoglycaemia is not a feature of prolonged starvation; there are powerful survival values in being able to maintain brain function during prolonged famine. Since hepatic glycogen stores are depleted within 24 h of fasting, blood glucose concentrations are maintained thereafter entirely through gluconeogenesis. Gluconeogenesis is mainly dependent on protein breakdown (a small amount comes from the glycerol released during lipolysis) and it thus results in protein wasting. It is the effects of protein malnutrition that lead to the eventual lack of ability to cough properly and keep the airways clear, in turn leading to pneumonia and death during prolonged starvation; hypoglycaemia does not occur. During fasting, mobilization of fat and the consumption of fat and ketones by some tissues as alternative substrates ensures that protein loss is minimized and used to provide glucose for tissues, such as the brain, that cannot survive without it.
With normal feeding, digestion of carbohydrates leads to a rise in blood glucose, which normally triggers a brisk insulin response of sufficient magnitude to control blood glucose concentration very tightly in the 410 mmol litre1 range. The average peak plasma insulin response to a high carbohydrate meal in a group of normal healthy slim individuals rises 10-fold from a mean fasting value of 5 mU litre1 to a peak of about 50 mU litre1. The range of insulin response in this group is enormous, however, with peak values ranging between 15 and 250 mU litre1 while glucose values are no different between individuals. This reflects a genetically determined variation in insulin sensitivity between individuals.
Some glucose is stored in muscle as glycogen. This compartment of stored glucose is entirely for the local use of muscle and is integral to the flight or fight survival mechanism that has resulted in humans being the dominant creatures on earth. Muscle lacks a certain phosphorylase enzyme that removes the phosphate group from glucose 6-phosphate and as a result, free intracellular glucose is not produced by glycogenolysis in muscle (unlike the liver) and muscle cannot therefore export glucose into the circulation. Muscle glycogen allows a sudden burst of fuel (through anaerobic metabolism of glycogen to glucose to lactate) which allows muscle to undertake an immediate sudden burst of extreme activity on locally available energy stores before blood flow builds up to carry the lactate away and bring other energy fuels to sustain more prolonged exercise. Thus the fuel used by muscle progresses from local glycogen (sprint) to glucose and fatty acids brought via the circulation (middle distance) to predominantly fat (marathon).
The roles of fat and protein
The other major fuel required for energy metabolism is fat. Stored fat is in the form of triglyceride and contains enormous amounts of stored energy. Fat contains 9 kcal g1 stored energy while glycogen contains only 2 kcal g1 because there is water of hydration in glycogen in both muscle and the liver. This means that glycogen stores are heavy and of limited value to mobile creatures like us. They are there for short-term needs but, when food is scarce, a transition occurs to substitution of fat in all tissues that can metabolize it. Hepatic glycogen stores are soon lost during fasting, and gluconeogenesismainly from proteinis then required to maintain glucose supplies to the central nervous system. Since protein stores are also limited and critical to survival, the substitution of fat wherever possible is of great value. The enormous amount of energy stored in fat is liberated through lipolysis where triglyceride is hydrolysed to its constituents, glycerol and non-esterified fatty acids (NEFA; also known as free fatty acids (FFA)). Fat is able to substitute for glucose as an energy substrate in many but not all tissues. In muscle, there is no real preference for glucose or NEFA and the tissue can and does readily change from one to the other. The brain and other neural tissues have an obligatory requirement for glucose and cannot survive without it; however, they can substitute ketones (but not NEFA) for some, but not all, of their energy needs.
Protein is used mainly for structural processes but is continuously being synthesized and broken down. When food is short and glycogen stores are depleted, protein becomes the major source of gluconeogenic precursors via the glucogenic amino acids released during proteolysis. Proteolysis is inhibited by insulin (another of Schafers chalonic actions) and, in states of relative insulin lack such as prolonged fasting, insulin concentrations fall low enough to allow release of sufficient gluconeogenic amino acids to maintain blood glucose in the normal range. The price for this is a gradual but progressive loss of structural protein. As stated earlier, it is this that determines survival during prolonged fasts.
![]() |
What goes wrong in diabetes? |
---|
Even when the fasting blood glucose concentration is as high as 20 mmol litre1, it remains constant over several hours of fasting. During this time, a dynamic steady state exists when glucose production matches glucose disappearance from the bloodstream exactly. The magnitude of the hyperglycaemia is determined by the absolute rate of hepatic glucose production (Fig. 3) and this in turn is determined by the extent of, on one hand, the insulin deficiency and, on the other hand, the magnitude of the glucagon rise in response to insulin deficiency. This is another key point. In patients with diabetes mellitus secondary to pancreatectomy, where glucagon concentrations are low, fasting hyperglycaemia is modest. In type 1 diabetes, glucagon production is unimpaired and, in the face of insulin deficiency, plasma concentrations rise rapidly to high concentrations. In a group of insulin-withdrawn type 1 patients, where no insulin had been given for 24 h, fasting plasma glucose (and hence hepatic glucose production) correlated remarkably closely with fasting plasma glucagon2 as shown in Fig. 4.
|
This mass action effect accounts for the observations which show unequivocally that tissue glucose uptake can exceed normal even in the face of severe insulin deficiency such as occurs in uncontrolled diabetes mellitus.
Ketosis inhibits glucose uptake in many tissues and thus can spare structural protein
Glucose uptake is not, however, increased in all diabetic patients with hyperglycaemia. When significant ketosis occurs, this can inhibit glucose metabolism in cells, because the ketone bodies (3-hydroxybutyrate, acetoacetate and acetone) are freely soluble in both water and fat and diffuse across the cell membrane in direct proportion to their concentration in plasma. They are metabolized intracellularly to acetoacetate, which enters the Krebs cycle and becomes oxidized to carbon dioxide and water. When ketone concentrations in the plasma are high (above about 15 mmol litre1), their metabolism can account for most of the energy needs of the Krebs cycle. This results in a physiological damming back of glycolysis from glucose. As a result, the concentration of the intermediate compounds in the glycolytic pathway increases until the tissue concentration of glucose 6-phosphate is so high that further phosphorylation of glucose that has been transported into the cell becomes inhibited. Even when this stage is reached, glucose transport into the cell continues but, rather than being phosphorylated and passing down the glycolytic pathway and oxidized in the Krebs cycle, glucose is transported back out of the cell (futile cycling). The glucose transporter is specific for glucose and cannot transport glucose 6-phosphate.
Thus glucose transport and uptake into cells are dependent on the degree of ketosis. In the face of extreme ketosis, such as that not uncommonly seen in type 1 diabetes, where concentrations rise to as high as 25 mmol litre1, glucose uptake can be reduced to almost zero in tissues, such as muscle, that can metabolize ketones as readily as glucose. Under these conditions, glucose uptake in brain and other neural tissues (which can metabolize limited amounts of ketones) is reduced but ketones can never substitute completely for glucose. Red blood cells, on the other hand, do not have nuclei or mitochondria, cannot metabolize ketones at all and rely entirely on glucose conversion to lactate for their energy needs.
Ketoacidosis in diabetes is an uncontrolled process where serious lack of insulin takes the brake off lipolysis and ketogenesis. The result is severe ketosis, which can readily become ketoacidosis and can easily be fatal once ketoacids reach concentrations above 20 mmol litre1 and compensatory mechanisms become exhausted.
Controlled ketosis occurs with prolonged fasting in non-diabetics. Insulin levels fall sufficiently to release enough NEFA and to activate the hepatic enzymes of ketogenesis sufficiently to allow ketoacids to reach concentrations of <7 mmol litre1. This is a 70-fold increase over their normal fasting concentration (around 0.1 mmol litre1) and sufficient to supply energy for those tissues able to substitute ketones for glucose. In muscle this is as high as 100%, in red blood cells it is 0 and in the central nervous system it can be as high as about 50%. Thus the need for glucose is reduced and structural protein is preserved.
![]() |
Mechanisms leading to the development of diabetic ketoacidosis and hyperosmolar non-ketotic diabetic coma |
---|
|
Proteolysis is enhanced as a result of lack of insulin in muscle, providing a supply of glucogenic and ketogenic amino acids. The glucogenic amino acids (alanine, arginine, etc.) pass to the liver to fuel the furnace of gluconeogenesis. In addition, lack of insulin at the liver activates the enzymes of gluconeogenesis. The ketogenic amino acids (leucine, isoleucine and valine) released from proteolysis contribute to the substrates for hepatic ketogenesis.
As a result of lack of insulin in adipose tissue, lipolysis proceeds at an accelerated rate and this is further enhanced by over-secretion of growth hormone and catecholamines. Stored triglyceride is hydrolysed to glycerol and NEFA. The glycerol passes to the liver and contributes significantly to gluconeogenesis while the NEFA are transported to the liver and provide the major substrate for ketogenesis. Plasma concentrations of NEFA rarely increase above 1.5 mmol litre1 since NEFA are insoluble in water (highly non-polar) and rely on albumin binding for transport in the extracellular fluids. At 1.5 mmol litre1, all protein binding is saturated. NEFA are metabolized very quickly with a plasma half-life of 12 min, thus flux through the blood can be very high without the concentration rising above 1.5 mmol litre1.
As a result of insulin lack, the liver is also primed for ketogenesis as insulin deficiency activates the appropriate enzymes of ketogenesis. With increased flux of NEFA substrate arriving at the liver from accelerated lipolysis, the net result is that the liver pours out ketoacids (3-hydroxybutyric and acetoacetic acids) into the blood stream, where Ra exceeds Rd, so their concentrations in the blood increase progressively. In this case, although ketones are excreted in the urine, there is no renal threshold and unlike glucose the urinary losses are not very great and do not lead to the development of a new steady-state blood ketone concentration. The only significant loss of ketones from the circulation is, therefore, from metabolism. Since ketones are freely soluble in water and lipid, they enter all cells at high concentrations and are metabolized in preference to glucose in cells capable of doing so. If unchecked, ketone concentrations increase progressively and lead to the development of a progressively serious metabolic acidosis. If unchecked, ketoacids accumulate and exceed the bodys compensatory mechanisms (buffering with bicarbonate and hyperventilation) and H+ concentration rises to the point where blood pH drops to around 6.76.8 (when total acids reach about 25 mmol litre1). Beyond this, the condition is rapidly fatal. Of considerable diagnostic importance is the fact that the ratio of the concentrations of 3-hydroxybutyric acid:acetoacetic acid is determined by the H+ concentration such that the acetoacetic acid concentration decreases as blood pH decreases. Since the conventional bedside tests for ketones (Ketostix or Acetest tablets) react only with acetoacetic acid and require >12 mmol litre1 acetoacetic acid to trigger a positive test, it is possible to have a patient with severe ketoacidosis with a plasma 3-hydroxybutyrate concentration as high as 20 mmol litre1 and a urine ketone test showing only a trace of ketones (from a blood aceto-acetate concentration of 2 mmol litre1). This may often be ignored as irrelevant and the patient incorrectly assumed to have lactic acidosis; this can be a fatal mistake as the treatment of lactic acidosis is quite different from that of ketoacidosis.
Thus, there are two parallel metabolic processes that go wrong in the face of insulin deficiency: (i) glucose over-production and (ii) ketone over-production. Usually, both go wrong together and this is what one sees when insulin is withdrawn from a longstanding type 1 diabetic patient. Hyperglycaemia and ketoacidosis develop simultaneously and in parallel. Occasionally one pathway dominates. The commonest clinical scenario is hyperosmolar non-ketotic diabetic coma (HONK). This happens when insulin supplies are not quite zero and there is sufficient present to inhibit lipolysis but not gluconeogenesis. There is often an aggravating factor present: the patient may turn to a high-energy drink to quench the thirst arising from the osmotic diuresis of the underlying type 2 diabetes. In the early stages, the patients may feel unwell and lacking in energy and, as a result of television advertising, try high-glucose drinks in the hope that they will make them feel more energetic. This just augments the already elevated rate of glucose entry into the circulation, aggravates osmotic diuresis and accelerates the process of decompensation. The very high glucose concentrations may themselves also help suppress lipolysis and ketogenesis by encouraging re-esterification of NEFA released from fat.
A rarer occurrence is normoglycaemic ketotacidosis. This arises usually in an established diabetic patient who becomes unwell and cuts down food intake, monitors his/her own blood glucose and takes extra insulin to prevent hyperglycaemia. Occasionally the drive of fat-mobilizing hormones, such as catecholamines and growth hormone, break through the inhibition of insulin on lipolysis and ketosis results. However, this is very uncommon.
The development of electrolyte disturbances
During the hyperglycaemic phase when the hyperglycaemia-induced osmotic diuresis leads to thirst and polyuria, the choice of fluid that people make to slake their thirst varies enormously and often has a profound effect on outcome. We have already covered the scenario where a patient turns to a sweet beverage; in the case of another person who chooses a hypo-osmolar fluid such as water, the outcome may be quite different. In this case the fluid lost through the osmotic diuresis is nearly matched with the water intake and a tenuous compensated osmotic diuresis exists and can be maintained for a long time. Despite this, electrolytes, particularly sodium, are continually lost with the diuresis. In the early stages of diuresis, sodium is lost at around 150 mmol litre1 of urine (and potassium at around 5 mmol litre1 of urine). If this is replaced by water, reasonable osmolar balance is maintained. The net result, however, is progressive depletion of sodium. This activates the reninangiotensin system and aldosterone secretion increases, leading to increased sodium resorption from the tubules. Sodium losses decline as aldosterone concentrations increase. Aldosterone is very effective in retaining sodium even in the face of an osmotic diuresis. This hypersecretion of aldosterone has a knock-on effect on potassium stores since the high aldosterone concentrations reduce potassium resorption and urinary potassium excretion increases. The longer the phase of compensated osmotic diuresis, where osmolar balance is maintained within reasonable limits, the greater the degree of overall sodium and potassium depletion. There is always also a free water deficit as water, in the relative absence of sodium, is carried out with the diuresis.
Eventually, if untreated and if significant ketoacidosis does not develop, the sodium depletion reaches the stage where dehydration is so great that hypotension occurs. The patient then becomes oliguric and uraemic in the face of a substantial osmolar load. This is a very precarious situation characterized by a prune-like appearance with marked hypotension and raised serum creatinine and urea. If not treated promptly with parenteral rehydration, it is rapidly fatal. At this stage, the patient is depleted of, at the very least, 6 litres of water, 600 mmol of sodium and 500 mmol of potassium. Although the patient is so depleted of potassium, plasma potassium may be dangerously high as a result of potassium leaking out of cells into the extracellular fluid but no longer being excreted by diuresis. The most severe cases of fluid and electrolyte depletion are often seen in those who do not develop ketoacidosis. The depressed mental state correlates most closely with the degree of hyperosmolality and dehydration. Therapy should be targeted at correcting the electrolyte disturbance; insulin administration is of secondary importance.
If ketoacidosis does develop, the problems of metabolic acidosis may appear to dominate the clinical picture. It is important to remember, however, that severe fluid and electrolyte depletion is inevitable and that correction of this in a timely and appropriate manner is the hallmark of successful treatment.
![]() |
Insulin replacement and the control of metabolism in diabetes |
---|
How then does insulin lower the blood glucose in diabetes?
Again this question is simple to answer and, by now, the answer will not be surprising. The use of tracer glucose infusions has shown not only that hyperglycaemia in the face of insulin deficiency is the result of over-production of glucose by the liver but also that insulin infusion lowers blood glucose by inhibiting hepatic glucose production. Indeed, rather than stimulating glucose uptake in tissues such as muscle, insulin in fact reduces glucose uptake. This is because the main factor driving glucose uptake is the mass action effect of hyperglycaemia and the concentration gradient between the extracellular and intracellular glucose concentrations. Glucose transporters are not rate limiting under these conditions, even in the face of severe insulin deficiency.
Some of the experimental data behind our understanding of these mechanisms are illustrated in the results2 shown in Fig. 6. In these studies a group of established type 1 diabetic patients volunteered to be studied on three occasions in the insulin-withdrawn state 24 h after their last dose of insulin. The order of events was randomized. Patients received either an infusion of saline, low-dose insulin (2.6 u h1) or high-dose insulin (10.6 u h1) for 2 h. Tracer glucose was infused for 2 h before the insulin was started and the rates of glucose production and utilization were measured before and during the insulin infusions. Blood glucose concentration decreased more rapidly with high-dose rather than low-dose insulin and declined very slowly during the saline infusion (Fig. 6A). Insulin produced an immediate reduction of 50% in hepatic glucose production (Ra); this was the only change leading to the decrease in glucose during the low-dose study. The reduction in blood glucose concentration produced by the low-dose insulin infusion was followed by a reduction in glucose uptake (Rd) in keeping with the primary importance of the glucose concentration gradient rather than the insulin concentration in the regulation of glucose disposal. Thus insulin administration lowered glucose uptake into peripheral tissues. During the high-dose infusion there was a similar immediate halving of hepatic glucose production but insulin stimulated glucose uptake as well as inhibiting glucose production, so the decrease in blood glucose was more rapid (Fig. 6B). Under physiological conditions, plasma insulin concentrations rarely increase above 100 mu litre1 except transiently for a few minutes after a very high carbohydrate load. The low-dose infusion at 2.6 u h1 produce insulin concentrations around 3050 mU litre1 whereas with 10.6 u h1 concentrations may exceed 200 mU litre1, which is rarely seen in normal life. The results are very much in keeping with Schafers concept of a primary role of insulin in regulating blood glucose concentration through control of hepatic glucose storage, hence the evolution of the endocrine pancreas within the portal circulation.
|
![]() |
Why is it important to understand the mechanisms regulating energy metabolism? |
---|
We conclude this article by examining how this basic science approach might influence the management of a common clinical scenario; the well controlled, uncomplicated diabetic scheduled for elective surgery.
![]() |
The well controlled diabetic undergoing elective surgery |
---|
HbA1c is only a measure of recent glycaemic control; fortunately, however, in the vast majority of people with diabetes, if glycaemic control is good then so are other metabolic processes. Indeed, in patients with diabetes treated with insulin who have tight glycaemic control, there can be over-control of other metabolic processes. This is explained as follows. Exogenous insulin is given peripherally and the dose adjusted to control hepatic glucose production, not proteolysis. With subcutaneous or intravenous administration of insulin, the concentration in the portal circulation will always be less than in the systemic circulation. This is a reversal of the normal situation. Good glycaemic control thus invariably results in peripheral hyperinsulinaemia. Hence lipolysis and proteolysis are slightly over-controlled (protein synthesis is normalinsulin-independent and regulated by growth hormonebut protein breakdown is reduced as a result of the chalonic action of peripheral hyperinsulinaemia).
A patient with an HbA1c of 7% is effectively normal. It is only when HbA1c is >9% that things begin to go wrong, especially with respect to the development of osmotic diuresis and consequent water and electrolyte loss. With an HbA1c of 1215%, the patient is on the verge of diabetic ketoacidosis. In these patients, electrolyte imbalance, fluid balance and improvement in metabolic control must be corrected preoperatively.
Immediate preoperative metabolic control
Type 1 patients. Within a few years of the onset of diabetes, and even in the presence of excellent control, all type 1 diabetics stop producing endogenous insulin. Therefore, no type 1 diabetic can tolerate prolonged periods without exogenous insulin. Once the effect of their last dose of insulin has worn off, the brake on hepatic glucose production and catabolism is removed, resulting in the development over many hours of hyperglycaemia and ketosis. Traditionally, many of these patients have been managed with a mixture of glucose, insulin and potassium combined in one bag and administered intravenously. The use of separate infusions of glucose and insulin is also popular and probably allows tighter control, but has generated concern regarding the sudden discontinuation of the glucose if the bag finishes, a disconnection occurs or the cannula becomes obstructed (and is later flushed). Some of these concerns are equally valid if a saline infusion is used. However, as long as a well controlled type 1 patient continues their normal regimen (diet and insulin) up to the night before surgery (possibly modifying (reducing) their evening dose of insulin), then on the morning of operation their insulin concentrations will be low and decreasing and their glucose normal or slightly increased. In all other respects they remain well controlled. From then on the consequence of continued starvation combined with avoidance of insulin has to be the gradual development of hyperglycaemia as the liver starts releasing increasing amounts of glucose. It thus seems logical that the only intervention these patients require to maintain good control in the preoperative period is insulin. They should not yet have developed any fluid or electrolyte imbalance greater than that in a non-diabetic. Therefore, they could be managed more simply, more safely and with tight control by the sole use of an insulin infusion in combination with a traditional sliding scale. This greatly simplifies the physical administration of treatment (only one cannula, no three-way taps or Y connectors with anti-reflux valves, no fluid pumps) and also avoids the complicated picture of matching insulin requirements to two variables: endogenous production of glucose and exogenous administration of glucose. The requirement for calories or fluid, or both, intra-operatively or later may require the commencement of a glucose, or other intravenous fluid, infusion at that time.
Type 2 patients. All type 2 diabetics, even those who require insulin for good control, produce endogenous insulin, and their metabolic state improves with fasting. Indeed studies have shown that prolonged starvation for up to 3 weeks normalizes glucose metabolism in type 2 patients. The immediate preoperative management of well controlled type 2 patients can and should be relatively simple. Normal treatment and diet should be continued up to the commencement of their preoperative fast (except, possibly, for reducing or omitting their evening dose of insulin or oral hypoglycaemic, respectively). Following their overnight fast they can safely omit the morning dose of insulin or oral hypoglycaemic and, apart from regular monitoring, no further intervention is likely to be necessary.
Intra- and post-operative management
The further management of all diabetic patients should be dictated by frequent assessment of glycaemic control and the patients ability to resume a normal diet (see reference 4). Hyperglycaemia in any diabetic patient unable to take a normal diet should probably be treated with an intravenous infusion of insulin from an infusion pump, the rate being guided by a sliding scale. The need for intravenous calories and fluids should be assessed, as it would be for non-diabetics in a similar setting.
![]() |
Footnotes |
---|
![]() |
References |
---|
2 Brown P, Tompkins C, Juul S, Sonksen PH. Mechanism of action of insulin in diabetic patients: a dose-related effect on glucose production and utilisation. BMJ 1978; i: 123942
3 Hall SE, Saunders J, Sonksen, PH. Glucose and free fatty acid turnover in normal subjects and in diabetic patients before and after insulin treatment. Diabetologia 1979; 16: 297306
4 McAnulty GR, Robertshaw HJ, Hall GM. Anaesthetic management of patients with diabetes mellitus. Br J Anaesth 2000; 85: 8090
5 Schafer E. The Endocrine Organs. London: Longman, Green & Co., 1916
6 Thomas SH, Wisher M, Brandenburg D, Sonksen PH. Insulin action on adipocytes: evidence that the anti-lipolytic and lipogenic effects of insulin are mediated by the same receptor. Biochem J 1979; 184: 35560