Blood sugar level: Difference between revisions

The blood sugar concentration or blood glucose level is the amount of glucose (sugar) present in the blood of a human or animal. Normally, in mammals the blood glucose level is maintained at reference range between about 3.6 and 5.8 mM (mmol/L). It is tightly regulated as a part of metabolic homeostasis.

Glucose is primarily a compact energy store, and is the primary source of energy for body cells, fats and oils (ie, lipids). It is transported from the intestines or liver to body cells via the bloodstream, and is absorbed by body cells with the intervention of insulin, which is a hormone normally naturally produced by the body.

The mean normal blood glucose level in humans is about 5 mM (5 mmol/L or 90 mg/dL) (since the molecular weight of glucose, C₆H₁₂O₆, is about 180 g/mol). However, the glucose level fluctuates during the day. It rises after meals for an hour or two by a few grams and is usually lowest in the morning, before the first meal of the day (termed "the fasting level"). The total amount of glucose normally in human blood is only about 3.3 to 7g (assuming an ordinary adult blood volume of 5 litres, plausible for an average adult male).

When a blood sugar level is outside the normal range, it may be an indicator of a medical condition. If it is persistently high it may indicate hyperglycemia or if low it may indicate hypoglycemia. Diabetes mellitus is characterized by persistent hyperglycemia from any of several causes, and is the most prominent disease related to failure of blood sugar regulation. A temporary elevated blood sugar level may also result from severe stress, such as trauma, stroke, heart attack, or surgery. Also, certain drugs can increase or decrease glucose levels.

Units of blood glucose

In most countries, blood glucose levels are reported in terms of a molar concentration, measured in mmol/L (or millimolar, abbreviated mM). In the United States, and in other places, mass concentration, measured in mg/dL, is typically used.^[1]

The difference between the two scales is a factor of 18, so that 1 mmol/L is equivalent to 18 mg/dL.

Normal values

Despite widely variable intervals between meals or the occasional consumption of meals with a substantial carbohydrate load, human blood glucose levels normally remain within a remarkably narrow range. In most humans this varies from about 4.4 to 6.1 mmol/L (82-110 mg/dL) except shortly after eating when the blood glucose level rises temporarily up to maybe 7.8 mmol/L (140 mg/dL) or a bit more in non-diabetics. The American Diabetes Association recommends a post-meal glucose level less than 10 mmol/L (180 mg/dl) and a pre-meal plasma glucose of 5 to 7.2 mmol/l (90-130 mg/dl). ^[2]

The actual amount of glucose in the blood and body fluids is very small. The control mechanism in the human body works on very small quantities of glucose. In a healthy adult male of 75 kg (165 lb) with a blood volume of 5 litres (1.3 gal), a blood glucose level of 100 mg/dL or 5.5 mmol/L corresponds to about 5 g (0.2 oz or 0.002 gal, 1/500 of the total) of glucose in the blood and approximately 45 g (1½ ounces) in the total body water (which includes more than merely blood and will be usually about 60% of the total body weight in men). (A small sugar packets provided in many restaurants with coffee or tea is about 5 grams.)

Regulation

The homeostatic mechanism which keeps the blood value of glucose in a remarkably narrow range is composed of several interacting systems, of which hormone regulation is the most important.

There are two types of mutually antagonistic metabolic hormones affecting blood glucose levels:

• catabolic hormones (such as glucagon, growth hormone, cortisol and catecholamines) which increase blood glucose;
• and one anabolic hormone (insulin), which decreases blood glucose.

Glucose measurement

Sample type

Glucose can be measured in whole blood or serum (ie, plasma). Historically, blood glucose values were given in terms of whole blood, but most laboratories now measure and report the serum glucose levels. Because red blood cells (erythrocytes) have a higher concentration of protein (eg, hemoglobin) than serum, serum has a higher water content and consequently more dissolved glucose than does whole blood. To convert from whole-blood glucose, multiplication by 1.15 has been shown to generally give the serum/plasma level.

Collection of blood in clot tubes for serum chemistry analysis permits the metabolism of glucose in the sample by blood cells until separated by centrifugation. Red blood cells, for instance, do not require insulin to intake glucose from the blood. Higher than normal amounts of white or red blood cell counts can lead to excessive glycolysis in the sample with substantial reduction of glucose level if the sample is not processed quickly. Ambient temperature at which the blood sample is kept prior to centrifuging and separation of plasma/serum also affects glucose levels. At refrigerator temperatures, glucose remains relatively stable for several hours in a blood sample. At room temperature (25 °C), a loss of 1 to 2% of total glucose per hour should be expected in whole blood samples. Loss of glucose under these conditions can be prevented by using Fluoride tubes (ie, gray-top) since fluoride inhibits glycolysis. However, these should only be used when blood will be transported from one hospital laboratory to another for glucose measurement. Red-top serum separator tubes also preserve glucose in samples after being centrifuged isolating the serum from cells.

Particular care should be given to drawing blood samples from the arm opposite the one in which an intravenous line is inserted, to prevent contamination of the sample with intravenous fluids. Alternatively, blood can be drawn from the same arm with an IV line after the IV has been turned off for at least 5 minutes, and the arm elevated to drain infused fluids away from the vein. Inattention can lead to large errors, since as little as 10% contamination with 5% dextrose (D5W) will elevate glucose in a sample by 500 mg/dl or more. Remember that the actual concentration of glucose in blood is very low, even in the hyperglycemic.

Arterial, capillary and venous blood have comparable glucose levels in a fasting individual. After meals venous levels are somewhat lower than capillary or arterial blood; a common estimate is about 10%.

Measurement techniques

Two major methods have been used to measure glucose. The first, still in use in some places, is a chemical method exploiting the nonspecific reducing property of glucose in a reaction with an indicator substance that changes color when reduced. Since other blood compounds also have reducing properties (e.g., urea, which can be abnormally high in uremic patients), this technique can produce erroneous readings in some situations (5 to 15 mg/dl has been reported). The more recent technique, using enzymes specific to glucose, are less susceptible to this kind of error. The two most common employed enzymes are glucose oxidase and hexokinase.

In either case, the chemical system is commonly contained on a test strip, to which a blood sample is applied, and which is then inserted into the meter for reading. Test strip shapes and their exact chemical composition vary between meter systems and cannot be interchanged. Formerly, some test strips were read (after timing and wiping away the blood sample) by visual comparison against a color chart printed on the vial label. Strips of this type are still used for urine glucose readings, but for blood glucose levels they are obsolete. Their error rates were, in any case, much higher.

Urine glucose readings, however taken, are much less useful. In properly functioning kidneys, glucose does not appear in urine until the renal threshold for glucose has been exceeded. This is substantially above any normal glucose level, and so is evidence of an existing severe hyperglycemic condition. However, urine is stored in the bladder and so any glucose in it might have been produced at any time since the last time the bladder was emptied. Since metabolic conditions change rapidly, as a result of any of several factors, this is delayed news and gives no warning of a developing condition. Blood glucose monitoring is far preferable, both clinically and for home monitoring by patients.

I. CHEMICAL METHODS
A. Oxidation-Reduction Reaction
${\displaystyle \mathrm {Glucose} +\mathrm {Alkaline\ Copper\ Tartarate} {\xrightarrow {\mathrm {Reduction} }}\mathrm {Cuprous\ Oxide} }$
1. Alkaline Copper Reduction
Folin Wu Method	${\displaystyle \mathrm {Cu} ^{++}+\mathrm {Phosphomolybdic\ Acid} {\xrightarrow {\mathrm {Oxidation} }}\mathrm {Phosphomolybdenum\ Oxide} }$	Blue end-product
Benedict's method	Modification of Folin wu for Qualitative Urine Glucose
Nelson Somogyi Method	${\displaystyle \mathrm {Cu} ^{++}+\mathrm {Arsenomolybdic\ Acid} {\xrightarrow {\mathrm {Oxidation} }}\mathrm {Arsenomolybdenum\ Oxide} }$	Blue end-product
Neocuproine Method	${\displaystyle \mathrm {Cu} ^{++}+\mathrm {Neocuproine} {\xrightarrow {\mathrm {Oxidation} }}\mathrm {Cu} ^{++}\mathrm {Neocuproine\ Complex} }$*	Yellow-orange color Neocuproine
Shaeffer Hartmann Somogyi	Utilizes the principle of Iodine reaction with Cuprous byproduct. Excess I2 is then titrated with thiosulfate.
2. Alkaline Ferricyanide Reduction
Hagedorn Jensen	${\displaystyle \mathrm {Glucose} +\mathrm {Alk.\ Ferricyanide\ Yellow} \longrightarrow \mathrm {Ferrocyanide} }$	Colorless end product; other reducing substances interfere with reaction
B. Condensation
Ortho-toluidine Method	Utilizes aromatic amines and hot acetic acid Forms Glycosylamine and Schiff's base which is emerald green in color This is the most specific method, but the reagent used is toxic
Anthrone (Phenols) Method	Forms hydroxymethyl furfural in hot acetic acid
II. ENZYMATIC METHODS
A. Glucose Oxidase
${\displaystyle \mathrm {Glucose} +\mathrm {O} ^{2}{\xrightarrow[{\mathrm {Oxidation} }]{\mathrm {glucose\ oxidase} }}\mathrm {Cuprous\ Oxide} }$
Saifer–Gerstenfeld Method	${\displaystyle \mathrm {H_{2}O_{2}} +{\textrm {{\textit {O}}-dianisidine}}{\xrightarrow[{\mathrm {Oxidation} }]{\mathrm {peroxidase} }}\mathrm {H_{2}O} +\mathrm {oxidized\ chromogen} }$	Inhibited by reducing substances like BUA, Bilirubin, Glutathione, Ascorbic Acid
Trinder Method	uses 4-aminophenazone oxidatively coupled with Phenol Subject to less interference by increases serum levels of Creatinine, Uric Acid or Hemoglobin Inhibited by Catalase
Kodak Ektachem	A Dry Chemistry Method Uses Reflectance Spectrophotometry to measure the intensity of color through a lower transparent film
Glucometer	Home monitoring blood glucose assay method Uses a strip impregnated with a Glucose Oxidase reagent
B. Hexokinase
${\displaystyle {\begin{alignedat}{2}&\mathrm {Glucose} +\mathrm {ATP} {\xrightarrow[{\mathrm {Phosphorylation} }]{\mathrm {Hexokinase} +\mathrm {Mg} ^{++}}}{\textrm {G-6PO}}_{4}+\mathrm {ADP} \\&{\textrm {G-6PO}}_{4}+\mathrm {NADP} {\xrightarrow[{\mathrm {Oxidation} }]{\textrm {G-6PD}}}{\textrm {G-Phosphogluconate}}+\mathrm {NADPH} +\mathrm {H} ^{+}\\\end{alignedat}}}$
NADP as cofactor NADPH (reduced product) is measured in 340 nm More specific than Glucose Oxidase method due to G-6PO_4, which inhibits interfering substances except when sample is hemolyzed

Blood glucose laboratory tests

1. fasting blood sugar (ie, glucose) test (FBS)
2. urine glucose test
3. two-hr postprandial blood sugar test (2-h PPBS)
4. oral glucose tolerance test (OGTT)
5. intravenous glucose tolerance test (IVGTT)
6. glycosylated hemoglobin (HbA_1C)
7. self-monitoring of glucose level via patient testing

Clinical correlation

The fasting blood glucose (FBG) level is the most commonly used indication of overall glucose homeostasis, largely because disturbing events such as food intake are avoided. Conditions affecting glucose levels are shown in the table below. Abnormalities in these test results are due to problems in the multiple control mechanism of glucose regulation.

The metabolic response to a carbohydrate challenge is conveniently assessed by a postprandial glucose level drawn 2 hours after a meal or a glucose load. In addition, the glucose tolerance test, consisting of several timed measurements after a standardized amount of oral glucose intake, is used to aid in the diagnosis of diabetes. It is regarded as the gold standard of clinical tests of the insulin / glucose control system, but is difficult to administer, requiring much time and repeated blood tests. Note that food commonly includes carbohydrates which don't participate in the metabolic control system; simple sugars such as fructose, many of the disaccarhides (which either contain simple sugars other than glucose or cannot be digested by humans) and the more complex sugars which also cannot be digested by humans. And there are carbohydrates which are not digested even with the assistance of gut bacteria; several of the fibres (soluble or insoluble) are chemically carbohydrates. Food also commonly contains components which affect glucose (and other sugar's) digestion; fat, for example slows down digestive processing, even for such easily handled food constituents as starch. Avoiding the effects of food on blood glucose measurement is important for reliable results since those effects are so variable.

Error rates for blood glucose measurements systems vary, depending on laboratories, and on the methods used. Colorimetry techniques can be biased by color changes in test strips (from airborne or finger borne contamination, perhaps) or interference (eg, tinting contaminants) with light source or the light sensor. Electrical techniques are less susceptible to these errors, though not to others. In home use, the most important issue is not accuracy, but trend. Thus if your meter / test strip system is consistently wrong by 10%, there will be little consequence, as long as changes (eg, due to exercise or medication adjustments) are properly tracked. In the US, home use blood test meters must be approved by the Federal Food and Drug Administration before they can be sold.

Finally, there are several influences on blood glucose level aside from food intake. Infection, for instance, tends to change blood glucose levels, as does stress either physical or psychological. Exercise, especially if prolonged or long after the most recent meal, will have an effect as well. In the normal person, maintenance of blood glucose at near constant levels will nevertheless be quite effective.

Health effects

If blood sugar levels drop too low, a potentially fatal condition called hypoglycemia develops. Symptoms may include lethargy, impaired mental functioning, irritability, shaking, weakness in arm and leg muscles, sweating and loss of consciousness. Brain damage is even possible.

If levels remain too high, appetite is suppressed over the short term. Long-term hyperglycemia causes many of the long-term health problems associated with diabetes, including eye, kidney, heart disease and nerve damage.

Low blood sugar

Some people report drowsiness or impaired cognitive function several hours after meals, which they believe is related to a drop in blood sugar, or "low blood sugar". For more information, see:

• idiopathic postprandial syndrome
• hypoglycemia

Mechanisms which restore satisfactory blood glucose levels after hypoglycemia must be quick and effective, because of the immediately serious consequences of insufficient glucose; in the extreme, coma, but also less immediately dangerous, confusion or unsteadiness, amongst many other symptoms. This is because, at least in the short term, it is far more dangerous to have too little glucose in the blood than too much. In healthy individuals these mechanisms are generally quite effective, and symptomatic hypoglycemia is generally only found in diabetics using insulin or other pharmacological treatment. Such hypoglycemic episodes vary greatly between persons and from time to time, both in severity and swiftness of onset. For severe cases, prompt medical assistance is essential, as damage (to brain and other tissues) and even death will result from sufficiently low blood glucose levels.

Comparative content

Etymology and use of term

The term 'blood sugar' has colloquial origins.^{[citation needed]} In a physiological context, the term is a misnomer because it refers to glucose, yet other sugars besides glucose are always present. Food contains several different types (eg, fructose (largely from fruits/table sugar/industrial sweeteners). galactose (milk and dairy products), as well as several food additives such as sorbitol, xylose, maltose, ...). But because these other sugars are largely inert with regard to the metabolic control system (ie, that controlled by insulin secretion), since glucose is the dominant controlling signal for metabolic regulation, the term has gained currency, and is used by medical staff and lay folk alike. The table above reflects some of the more technical and closely defined terms used in the medical field.

Blood glucose in birds and reptiles

In birds and reptiles the processing of sugars is done differently, the pancreas is slightly more well developed in birds than in mammals, perhaps as a partial compensation for the lack of saliva and chewing. It produces carbohydrate, fat and protein digesting enzymes which are secreted into the small intestine. The liver has two distinct lobes each with its own duct leading into the small intestine. The liver, as in mammals, houses the bile, which in birds however is acidic and not alkaline as it is in mammals. Many birds do not have a gall bladder to hold the bile, and it is secreted directly into the pancreatic ducts.

References

• John Bernard Henry, M.D.: Clinical diagnosis and Management by Laboratory Methods 20th edition, Saunders, Philadelphia, PA, 2001.
• Ronald A. Sacher and Richard A. McPherson: Widmann's Clinical Interpretation of Laboratory Tests 11th edition, F.A. Davis Company, 2001* .

See also

• Current research - Boronic acids in supramolecular chemistry: Saccharide recognition
• Blood glucose monitoring