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General principles of insulin therapy in diabetes mellitus

General principles of insulin therapy in diabetes mellitus
Literature review current through: Jan 2024.
This topic last updated: Nov 08, 2023.

INTRODUCTION — Insulin is used in the treatment of people with most types of diabetes. In general, the need for insulin depends upon the degree of insulin deficiency. All people with type 1 diabetes need insulin treatment; many individuals with type 2 diabetes will require insulin as their beta cell function declines over time.

Available formulations of insulin, insulin pharmacokinetics, and determinants of efficacy will be reviewed here. The specifics of insulin therapy for type 1 and type 2 diabetes and intensive insulin therapy for critically ill adults who become hyperglycemic are discussed separately.

(See "Management of blood glucose in adults with type 1 diabetes mellitus".)

(See "Insulin therapy in type 2 diabetes mellitus".)

(See "Glycemic control in critically ill adult and pediatric patients".)

(See "Pregestational (preexisting) diabetes mellitus: Antenatal glycemic control", section on 'Insulin pharmacotherapy'.)

(See "Gestational diabetes mellitus: Glucose management and maternal prognosis", section on 'Insulin'.)

(Related Pathway(s): Diabetes: Initiation and titration of insulin therapy in non-pregnant adults with type 2 DM.)

INSULIN PREPARATIONS — Most people with diabetes use either human insulin or an insulin analog injected subcutaneously. Animal-sourced insulins (derived from the pancreas of cows and pigs) are no longer produced in the United States but are available on a limited basis in some countries (eg, United Kingdom) for rare people who cannot manage their diabetes with biosynthetic insulin. Compared with human insulin, porcine insulin differs by one amino acid and bovine by three amino acids, and the generation of antibodies to these animal insulins may change their pharmacokinetics [1].

The time to peak and the duration of action of older human insulin preparations (regular insulin and neutral protamine Hagedorn [NPH]) do not replicate endogenous postprandial insulin secretion and basal insulin secretion, respectively, which is particularly important in treating insulin-deficient type 1 diabetes. The rapid-acting (lispro, lispro-aabc, glulisine, aspart, and faster aspart) and long-acting (glargine, detemir, and degludec) insulin analogs were developed to provide a more physiologic insulin profile (table 1 and figure 1) [2].

The usual concentration of insulin is 100 units per mL (U-100). More concentrated formulations (U-200, U-300, U-500) of some types of insulin are available to treat hyperglycemia in severely insulin-resistant individuals (eg, requiring more than 200 total units of insulin daily). (See "Insulin therapy in type 2 diabetes mellitus", section on 'Insulin resistance'.)

U-300 insulin glargine is also used in people who are not insulin resistant because of its longer half-life when compared with U-100 insulin glargine.

Human insulins

Regular insulin — Regular insulin (short-acting) is a soluble insulin complexed with zinc that has the same amino acid sequence as endogenous human insulin. It can be used to control the postprandial rise in glucose. After regular insulin is injected subcutaneously, the hexamers that have formed dissociate into dimers and monomers that are absorbed. This causes a delay in rise of insulin concentrations in the bloodstream, resulting in a need to inject at least 30 minutes before the meal to best cover post-meal glycemic excursions.

This timing of mealtime injections is difficult for many individuals with diabetes. In addition, the duration of action of regular insulin exceeds the duration of the postprandial rise in glucose observed after most meals, particularly meals that are not high in carbohydrate and fat. This can cause hypoglycemia several hours after eating, which can be prevented by eating a snack.

Regular insulin is also used intravenously in inpatient settings (eg, to treat diabetic ketoacidosis). (See "Diabetic ketoacidosis and hyperosmolar hyperglycemic state in adults: Treatment", section on 'Intravenous regular insulin' and "Glycemic control in critically ill adult and pediatric patients".)

NPH insulin — NPH (intermediate-acting insulin) is a crystallized suspension of human insulin, protamine, and zinc in a neutral buffer that delays the release of the insulin into the bloodstream (figure 1). To provide 24-hour basal coverage, NPH needs to be administered at least twice daily. When given in the morning, there is an increased risk of hypoglycemia if food is not consumed during the time of its peak action. When given in the evening or at bedtime, a bedtime snack may be needed to avoid nocturnal hypoglycemia. Subsequently, fasting glucose concentrations may be above target.

NPH, which is a suspension, should be administered at room temperature and mixed immediately before injection. This is accomplished by rolling the insulin pen or vial in your hands at least 10 times and then inverting the pen or vial at least 10 times [3].

Although NPH can be mixed with regular insulin or rapid-acting insulins in a single syringe for injection, which may be convenient and advantageous, the two insulins should be mixed immediately before injection. The regular ("clear") insulin should be drawn up before the NPH ("cloudy") insulin. It is important to avoid introducing protamine (NPH) into the regular insulin vial since that would change the pharmacokinetics of the regular insulin. This mixture should then be injected immediately after preparation. If NPH is mixed with a rapid-acting insulin analog, it should be injected within minutes prior to a meal.

U-500 regular insulin — U-500 regular insulin contains 500 units per mL of regular insulin. It is used infrequently given the availability of potent GLP-1 receptor agonists as well as concentrated forms of insulin analogs (see 'Analog insulins' below). U-500 insulin may be useful for treating severely insulin-resistant individuals (eg, requiring more than 200 total units of insulin daily). In one observational study of 11 individuals with obesity and severe insulin resistance (requiring >200 units of insulin daily), substituting U-500 regular insulin for U-100 NPH insulin improved glycemic management (mean glycated hemoglobin [A1C] decrease from 9.9 to 7.1 percent) [4].

The duration of action of U-500 regular insulin is most similar to that of NPH, but with a faster time of onset. Higher doses can result in significantly longer duration of insulin action (figure 1) [5,6]. The pharmacokinetics can be highly variable and hypoglycemia remains a potential risk [7,8]. Dosing is reviewed separately. (See "Insulin therapy in type 2 diabetes mellitus", section on 'Insulin resistance'.)

Analog insulins — Insulin analogs, which are manufactured using recombinant DNA technology, were designed to produce more physiologic insulin profiles and reduce the risk of hypoglycemia. The rapid-acting insulin analogs (insulin lispro, lispro-aabc, aspart, faster aspart, and glulisine) have both faster onset and shorter duration of action than regular insulin for pre-meal coverage [9-13], while the long-acting analogs have a longer, flatter, and more predictable day-to-day profile than NPH for basal coverage (table 1 and figure 1). Insulin analogs with even longer durations of action (dosed once weekly) are under development [14,15].

Rapidly acting insulin analogs — To produce an insulin preparation with a faster onset and shorter duration of action than regular insulin, modifications were made in the insulin molecule to prevent it from forming hexamers or polymers that slow absorption and delay action (figure 1) [16,17].

Insulin aspart is identical to human regular insulin except for a substitution of aspartic acid for proline at position B28. This substitution results in a reduction in hexamer formation and, consequently, more rapid absorption, faster onset of action, and shorter duration of action [18]. Another formulation of insulin aspart, produced by adding L-arginine and nicotinamide, results in slightly faster initial absorption than aspart and a higher glycemic effect within the first 30 minutes [19-21]. The total glucose-lowering effect is similar for faster aspart and insulin aspart.

Insulin lispro is identical to human regular insulin except for a lysine and proline at positions B28 and B29, respectively. Another formulation of insulin lispro (lispro-aabc), produced by adding treprostinil (a prostacyclin analogue) and citrate, results in slightly faster initial absorption than lispro, and when administered at mealtime, slightly better postprandial glucose control [22,23].

Insulin glulisine has a lysine and glutamic acid at positions B3 and B29 respectively.

With respect to short-term outcomes, such as A1C and risk of hypoglycemia, rapid-acting insulins may have a glycemic advantage over short-acting (regular) insulin in people with type 1 diabetes but not necessarily in people with type 2 diabetes. Although rapid-acting insulins are more expensive than regular insulin, the convenience for timing of pre-meal administration and reduction in hypoglycemia reported in some studies represent distinct advantages. For individuals using hybrid artificial pancreas systems, rapid-acting insulin analogs should be used since the algorithms driving the automatic insulin delivery are based on their pharmacokinetics. The trials examining these issues are reviewed separately. (See "Management of blood glucose in adults with type 1 diabetes mellitus", section on 'Prandial insulin options' and "Insulin therapy in type 2 diabetes mellitus", section on 'Designing an insulin regimen' and "Continuous subcutaneous insulin infusion (insulin pump)".)

Concentrated rapidly acting insulin analogs, U-200 lispro and U-200 lispro-aabc, contain 200 units/mL instead of 100 units/mL in the U-100 preparation. They are useful for individuals requiring high doses of prandial insulin and are available in prefilled pens to minimize the risk of dosing errors. The dose window shows the number of units of insulin to be delivered, and no conversion is needed. U-200 compared with U-100 lispro was shown to improve glycemic management in some people with type 2 diabetes [24].

Basal insulin analogs — Different alterations result in the slower absorption and longer duration of action of basal insulin analogs (table 1 and figure 1).

Insulin glargine – Glargine is identical to human insulin except for a substitution of glycine for asparagine in position A21 and by the addition of two arginine molecules to the amino terminus of the B-chain of the insulin molecule [25]. After subcutaneous administration, glargine precipitates in the tissue, forming hexamers, which delays absorption and prolongs duration of action.

Glargine, which is in an acidic solution, cannot be mixed with rapid-acting insulins, as the kinetics of both the glargine and rapid-acting insulin will be altered. U-100 glargine has no appreciable peak; however, it does have somewhat greater glucose-lowering effect in the first 12-hours than the subsequent 12 hours. Glargine has less nocturnal hypoglycemia than is observed with NPH insulin [26,27]. The duration of action of U-100 insulin glargine is usually 24 hours enabling once-daily dosing, but because its half-life is 12 hours, some individuals, especially with type 1 diabetes, have better basal coverage with twice-daily dosing.

The more concentrated formulation of insulin glargine (U-300 glargine) contains 300 units/mL instead of 100 U/mL. It has an even flatter and more prolonged duration of action than U-100 insulin glargine, lasting >24 hours (figure 1) [28]. It is used in type 1, as well as in type 2 diabetes, and in individuals with and without insulin resistance. Two prefilled pens are available: 1.5 mL (contains 450 units) and 3.0 mL (contains 900 units). These pens allow for delivery of the same number of insulin units as glargine but in a smaller volume. However, on a unit-to-unit basis, U-300 glargine has a lower glucose-lowering effect than U-100 glargine [29,30].

In trials comparing U-300 glargine with glargine 100 units/mL in people with type 2 diabetes inadequately controlled with oral agents and/or insulin, A1C levels decreased similarly in both glargine groups with no difference in severe hypoglycemia and little difference in nocturnal hypoglycemia [30-32]. In a network meta-analysis of trials comparing U-300 glargine with other basal insulin preparations in individuals with type 2 diabetes, glycemic control was similar among the preparations. The risk of nocturnal hypoglycemia was lower with U-300 glargine, compared with NPH and pre-mixed insulins, but the total frequency of hypoglycemia was not significantly different. Moreover, the frequency of severe hypoglycemia requiring assistance for treatment was very low and not significantly different among insulin types [33].

Insulin detemir – Detemir is an acylated insulin; the fatty acid side chain allows reversible albumin binding as well as concentration-dependent self-association (ie, formation of dihexamers) that results in prolongation of action (figure 1). Higher doses are associated with longer durations of action. It is considerably less potent than human insulin and, therefore, it is formulated using a 4:1 molar ratio (ie, one detemir unit contains four times as many insulin detemir molecules as one unit of any other insulin). Compared with glargine, it does have a noticeable peak and rarely lasts 24 hours.

Clinical trials in people with type 1 diabetes have suggested that twice-per-day injections may be necessary to achieve acceptable basal rate coverage and optimal glycemic control [34]. In type 2 diabetes, where endogenous insulin secretion may mask any deficiencies in basal insulin, the data are less clear [35]. However, in our clinical experience, detemir also often requires twice-daily administration in people with type 2 diabetes. Detemir cannot be mixed with rapid-acting insulins, as the kinetics of both the detemir and rapid-acting insulin will be altered.

Insulin degludec – Degludec is almost identical to human insulin, except for deletion of threonine at position B30 and the addition of a glutamyl link from LysB29 to a hexadecanedioic fatty acid, facilitating self-association and albumin binding [36]. Soluble multihexamers form at the injection site, from which monomers slowly separate and are absorbed. This property confers a long duration of action (>40 hours) and reduces variability in plasma concentration with once-daily dosing (figure 1). Steady-state insulin concentrations are attained in three to five days. In contrast to glargine and detemir insulins, degludec may be mixed with rapid-acting insulins without appreciably altering the kinetics of the degludec or the rapid-acting insulin.

The more concentrated formulation of insulin degludec (U-200 degludec) contains 200 units/mL instead of 100 units/mL in the U-100 preparation, and it is useful in adults with high dose insulin requirements. It is available in a prefilled pen to minimize the risk of dosing errors. The dose window shows the number of units of insulin to be delivered and no conversion is needed. The pharmacokinetics and pharmacodynamics of U-100 and U-200 insulin degludec are similar.

Insulin icodec – Insulin icodec is an investigational ultra-long-acting basal insulin (half-life of one week) [37]. Additional studies are needed to determine which individuals may benefit in clinical practice from use of ultra-long-acting insulin compared with daily basal insulin.

Type 2 diabetes – In a preliminary trial comparing once-weekly insulin icodec with once-daily U-100 insulin glargine in 247 adults with type 2 diabetes inadequately controlled on oral agents, the reduction in A1C was similar in the two groups (-1.33 and -1.15 percentage points, respectively) [14]. Mild (≤70 mg/dL [≤3.9 mmol/L], 53.6 versus 37.7 percent) and clinically important (<54 mg/dL [<3 mmol/L], 16 versus 10 percent) hypoglycemia were more common in the icodec group, but the latter difference did not reach statistical significance.

Type 1 diabetes – In a trial comparing once-weekly insulin icodec with once-daily insulin degludec in 655 adults with type 1 diabetes, the mean reduction in A1C after 26 weeks was similar in both groups (-0.47 and -0.51 percentage points, respectively) [38]. However, icodec treatment led to a higher rate of clinically significant (<54 mg/dL [<3 mmol/L]) or severe hypoglycemia (85 versus 76 percent with degludec).

Basal insulin-Fc (LY3209590) – LY3209590 is an investigational ultra-long-acting immunoglobulin G (IgG) Fc-fusion insulin. In the first phase 2 trial of weekly administration of LY3209590 compared with daily insulin degludec in 399 adults with type 2 diabetes, LY3209590 was noninferior to degludec with respect to the primary endpoint (A1C) over 32 weeks [15]. Results from additional trials will help inform the safety and efficacy of this insulin in the treatment of type 1 and type 2 diabetes.

Compared with NPH, there can be a glycemic advantage to the long-acting insulin analogs (glargine, detemir, and degludec) due to less symptomatic and nocturnal hypoglycemia, particularly in individuals with type 1 diabetes. In type 2 diabetes, the frequency of severe hypoglycemia (requiring assistance) is much lower than in type 1 diabetes, but risk of nocturnal hypoglycemia is lower with the long-acting analogs than with NPH. (See "Management of blood glucose in adults with type 1 diabetes mellitus", section on 'Basal insulin options' and "Insulin therapy in type 2 diabetes mellitus", section on 'Insulin initiation'.)

Safety — There is theoretical concern that changes in the structure of the insulin molecule (as occurs with the synthesis of insulin analogs) may inadvertently change other properties of insulin. As an example, glargine and detemir have different affinities (glargine higher, detemir lower) than human insulin for the insulin-like growth factor-1 (IGF-1) receptor, which theoretically could alter mitogenic activity [17]. An increase in mitogenic activity could increase the risk of some known diabetes complications, such as retinopathy, and could theoretically increase neoplastic transformation.

There are few studies comparing insulin analogs and human insulin with respect to long-term outcomes, such as diabetic complications or mortality. In a retrospective review of four multinational trials of glargine versus NPH, more participants randomly assigned to glargine had an increase in three steps or more on the Early Treatment Diabetic Retinopathy Study (ETDRS) scale [39]. However, the results from a randomized trial and retrospective cohort study do not support this conclusion [40,41]. In the five-year trial in over 1000 participants with type 2 diabetes previously treated with oral hypoglycemic agents, insulin, or both, there was no evidence of a greater risk of retinopathy progression (defined as three ETDRS steps or more) in people randomly assigned to once-daily glargine versus twice-daily NPH [40].

Although there are conflicting data regarding use of insulin analogs and risk of cancer [42-52], there is insufficient evidence to make a recommendation against glargine (or other insulin analogs) based on risk of malignant neoplasms [53]. Insulin choices should continue to be individualized. (See "Management of blood glucose in adults with type 1 diabetes mellitus" and "Insulin therapy in type 2 diabetes mellitus".)

Basal versus bolus — Basal insulin suppresses hepatic glucose production and when used in appropriate doses should maintain near normoglycemia in the fasting state, while prandial (pre-meal) bolus insulin covers the extra requirements after food is absorbed, thereby decreasing postprandial glucose excursions. Physiologic replacement of insulin with "basal-bolus" insulin therapy should be started as early as possible following the diagnosis of type 1 diabetes. People with type 2 diabetes requiring insulin often start with basal insulin first (in addition to oral and non-insulin injectable agents), but bolus insulin may be necessary as insulin secretion wanes. (See "Management of blood glucose in adults with type 1 diabetes mellitus", section on 'Insulin regimens' and "Insulin therapy in type 2 diabetes mellitus", section on 'Insulin initiation'.) (Related Pathway(s): Diabetes: Initiation and titration of insulin therapy in non-pregnant adults with type 2 DM.)

Basal – Intermediate- to long-acting preparations (NPH, detemir, glargine, or degludec) are typically administered once or twice daily to provide basal insulin levels. Intermediate-acting insulin (NPH) also provides some peak coverage for breakfast and lunch intake, although not as physiologic as replacement with rapidly acting insulin given at mealtimes.

Basal insulin levels can also be achieved by continuous infusion of a rapid-acting insulin via an insulin pump, used mostly in type 1 diabetes. (See "Continuous subcutaneous insulin infusion (insulin pump)".)

Bolus – Short-acting (regular) or rapid-acting (lispro, lispro-aabc, aspart, faster aspart, or glulisine) insulin is typically provided as a pre-meal bolus to control the glucose excursions that otherwise occur after food is absorbed. The approximate time of onset, peak activity, and duration of action of the most commonly used insulins are shown in the table (table 1).

Both glucose and insulin metabolism are altered in individuals with chronic kidney disease. The changes in the insulin regimen that must be made in these individuals are discussed separately. (See "Management of hyperglycemia in patients with type 2 diabetes and advanced chronic kidney disease or end-stage kidney disease".)

Pre-mixed insulins — We almost never prescribe commercially fixed-ratio pre-mixed insulins in the treatment of type 1 diabetes. Intensive regimens require frequent adjustments of the pre-meal bolus of short- or rapid-acting insulin. For people who will not or cannot comply with an intensive regimen, pre-mixed lispro/NPH in type 1 diabetes may be appropriate [54].

Some people with type 2 diabetes can use pre-mixed preparations with reasonable effect, and pre-mixed human insulins are generally less expensive than insulin analogs [55]. However, if the aim is to truly vary the dose of fast-acting insulin before a meal, it would be optimal to adjust the dosing of premeal insulin independently, rather than using a fixed ratio. Nevertheless, some people with type 2 diabetes who require pre-meal insulin in addition to basal insulin prefer pre-mixed insulins for convenience and lower cost. When using pre-mixed NPH and regular insulin, the peak action varies directly with the proportion of regular insulin in the combination (figure 2).

Inhaled insulin — In 2014, a second formulation of regular insulin in a dry powder received approval by the US Food and Drug Administration (FDA) for oral inhalation. A previously approved inhaled insulin introduced in 2006 was withdrawn from the market by the manufacturer, largely owing to poor sales. Studies have shown that oral inhaled insulin causes a more rapid rise in serum insulin concentration (and reduced hypoglycemia two to five hours after eating) compared with rapid-acting insulin analogs [56]. However, due to its inefficient absorption, higher doses of insulin must be administered to achieve a therapeutic response. Inhaled insulin dosing can only be adjusted in 4-unit increments, and it is contraindicated in the presence of chronic lung disease. Use requires initial pulmonary function testing, with repeat testing after six months of use and yearly thereafter. (See "Inhaled insulin therapy in diabetes mellitus".)

INSULIN DELIVERY — Subcutaneous insulin is delivered by injection or infusion using an insulin pump. Injectable insulin is available in prefilled disposable insulin pens, reusable insulin pens with disposable insulin cartridges, or in vials. Insulin pump therapy is reviewed separately. (See "Continuous subcutaneous insulin infusion (insulin pump)".)

Insulin pens are more convenient to use than insulin vials with syringes. When small doses of regular insulin (less than 5 units) are being given, the error in measuring the dose is almost 50 percent less when using pen injectors than with conventional insulin syringes [57]. "Smart" or "connected" pens are available, which communicate to smartphones to record insulin doses and have additional helpful features, such as insulin calculators, temperature sensors, reminders, and "share" features, but they are more expensive.

Use of insulin vials with syringes is less expensive than use of insulin pens. There are 0.3, 0.5 ("low-dose") and 1 mL insulin syringes available. The 0.3 mL syringe is useful if the insulin dose does not exceed 30 units; the 1 mL syringe is used for insulin doses up to 100 units. Magnifiers for syringes are available for individuals with vision problems to assist with accurate dosing.

When using insulin pens or vials with syringes, the shortest available needle is recommended (eg, 4 or 5 mm for pen needles) to avoid intramuscular injection and to minimize discomfort and tissue damage.

High-pressure jet injectors use a compressed spring or a compressed gas cartridge to supply pressure to inject the insulin through the skin without using a needle. Although they reduce the size of the subcutaneous depot and lead to a more rapid fall in blood glucose concentrations and a shorter duration of insulin action, there is no evidence that the variability in insulin absorption is improved [58,59]. Jet injectors may also cause less pain than traditional needles and syringes. However, they are expensive, difficult to maintain and are not recommended for routine use.

DETERMINANTS OF INSULIN EFFICACY — Effective use of insulin requires an understanding of the major variables that affect the degree of glycemic control. In addition to the type of insulin preparation discussed above, these include the site of injection, injection technique, the size of the subcutaneous depot, and subcutaneous blood flow.

Injection sites — Insulin can be injected into the abdominal wall, leg, arm, or buttock (figure 3). Human insulins are absorbed fastest from the abdominal wall, slowest from the leg and buttock, and at an intermediate rate from the arm. These differences can be useful clinically:

Pre-meal regular insulin should be rapidly absorbed, and injection into the abdominal wall may therefore be preferable.

Rapid-acting insulin absorption is increased when the insulin is injected into an exercising limb due to increased blood flow.

Pre-evening meal dosing of intermediate-acting insulin should be slowly absorbed to ensure a duration of action that lasts through the night, and injection in the leg or buttock may be preferable.

The absorption of the long-acting basal insulin analogs, glargine and degludec, do not appear to be significantly influenced by injection site [60,61].

Injection technique — Adults initiating insulin therapy should be referred to a certified diabetes care and education specialist (CDCES) to be taught proper insulin injection.

A clean site, without evidence of infection, inflammation, skin breakdown, fibrosis, or lipohypertrophy, should be used. The depth of penetration affects the rate of insulin absorption. Very shallow insertion can cause a painful intradermal injection that is not well absorbed. In comparison, a perpendicular injection in a lean area may result in an intramuscular injection, from which absorption is more rapid [62]. For very thin adults, young children, or anyone in whom the length of the needle is thought to be greater than or equal to the distance to muscle, the needle should be inserted perpendicularly into a lifted skinfold. For many individuals who use a short (4 mm) needle, the risk of an intramuscular injection is low and the needle can be inserted perpendicularly without "pinching" the subcutaneous fat between two fingers [62]. If a 6 mm needle is used, the individual can inject at a 45-degree angle instead of lifting a skinfold. Whether using insulin pens or syringes, the injection site should be rotated to avoid lipohypertrophy.

Insulin pens need to be primed per manufacturer's instructions and insulin delivered (plunger depressed) only after the needle is fully inserted. After insulin delivery, the needle should be held in place for 10 seconds before being withdrawn to assure full delivery and prevent leakage. For syringe users, first air should be drawn up in the syringe. The amount of air should be the same or slightly more than the intended dose. The air should then be injected into the vial of insulin before the insulin is withdrawn. Care should be made to remove any air bubbles from the syringe before injecting.

The practice of cleaning the skin with an alcohol swab before injection is usually not necessary. If used, the area should be completely dry before injecting. In a crossover study of 50 participants who received over 13,000 injections, there was no difference when the usual manner of injection was compared with injections through clothing [63]. The only problem with the latter was an occasional blood stain on the clothing. However, this is generally not recommended, because the individual cannot inspect the site prior to injection or lift a skinfold if needed [62].

Size of subcutaneous depot — When insulin is injected subcutaneously, it forms a subcutaneous depot. The variability in absorption is increased and net absorption is reduced with increasing size of the subcutaneous depot [64]. This can become a limiting factor in people who are insulin resistant and require large doses given several times per day.

One of the reasons why continuous subcutaneous insulin infusions may serve to smooth blood glucose control is that usually only rapid-acting insulin is used and the size of the subcutaneous depot is very small (since the reservoir is held in a syringe or other chamber, outside the body) [65]. Moreover, the consistent delivery site for each catheter placement reduces the variability inherent in syringe injections, where each injection is in a different site, with varying angles, depths, and underlying blood flow. (See "Continuous subcutaneous insulin infusion (insulin pump)", section on 'General principles'.)

Alterations in subcutaneous blood flow — The degree of insulin absorption is also determined by the rate of subcutaneous blood flow. Thus, insulin absorption is reduced by smoking [66] and increased by any increases in skin temperature [67] induced by exercise, saunas or hot baths, and local massage [68-71]. These variations are more marked with regular and rapid-acting insulins than with longer-acting insulins [70].

Insulin pump infusion sites — The continuous flow of insulin from insulin pumps can be partially or totally interrupted, by blockages at the aperture under the skin, kinking of the infusion set tubing as well as dislodgment of the inserted cannula. This topic is reviewed separately. (See "Continuous subcutaneous insulin infusion (insulin pump)", section on 'Pump failure'.)

SOCIETY GUIDELINE LINKS — Links to society and government-sponsored guidelines from selected countries and regions around the world are provided separately. (See "Society guideline links: Diabetes mellitus in adults" and "Society guideline links: Diabetes mellitus in children".)

INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.

Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)

Basics topics (see "Patient education: Type 1 diabetes (The Basics)" and "Patient education: Type 2 diabetes (The Basics)" and "Patient education: Using insulin (The Basics)" and "Patient education: Should I switch to an insulin pump? (The Basics)")

Beyond the Basics topics (see "Patient education: Type 1 diabetes: Overview (Beyond the Basics)" and "Patient education: Type 2 diabetes: Overview (Beyond the Basics)" and "Patient education: Type 1 diabetes: Insulin treatment (Beyond the Basics)" and "Patient education: Type 2 diabetes: Insulin treatment (Beyond the Basics)")

SUMMARY AND RECOMMENDATIONS

Commonly used insulin preparations – Human insulin or an insulin analog can be used to treat diabetes. The approximate time of onset, peak activity, and duration of action of the most commonly used insulins are shown in the table (table 1). The insulin analogs (lispro, aspart, glulisine, glargine, detemir, degludec) were developed to provide more physiologic insulin profiles. The rapid-acting insulin analogs (insulin lispro, lispro-aabc, aspart, faster aspart, and glulisine) have both faster onset and shorter duration of action than regular insulin for pre-meal coverage, while the long-acting analogs have a longer and flatter profile than NPH for basal coverage (figure 1). (See 'Insulin preparations' above.)

Concentrated forms of insulin – Concentrated forms of insulin can be used to control hyperglycemia in severely insulin-resistant individuals (eg, requiring more than 200 total units of insulin daily). (See 'U-500 regular insulin' above and 'Basal insulin analogs' above and 'Rapidly acting insulin analogs' above.)

Premixed insulin – We typically do not prescribe commercially fixed-ratio pre-mixed insulins in the treatment of type 1 diabetes. Intensive regimens in people with type 1 diabetes require frequent adjustments of the pre-meal bolus of short- or rapid-acting insulin. Pre-mixed insulin may be used in some people with type 2 diabetes for convenience, if the insulin ratio is appropriate to the person's insulin requirement. Specific guidelines should be followed for pre-mixing to avoid changes in speed of absorption and peak action. (See 'Pre-mixed insulins' above.)

Determinants of insulin efficacy – Effective use of insulin requires an understanding of the major variables that affect the degree of glycemic control: the insulin preparation, injection site, injection technique, the size of the subcutaneous depot, and subcutaneous blood flow. (See 'Determinants of insulin efficacy' above.)

Insulin injection sites – Absorption is fastest from injections into the abdominal wall, especially with human insulins, and therefore, abdominal wall may be a preferable site for pre-meal insulin. Slower absorption from the leg or buttock may be appropriate for evening doses of intermediate-acting insulin. The absorption of the long-acting basal insulin analogs, glargine and degludec, do not appear to be significantly influenced by injection site. (See 'Injection sites' above.)

Insulin injection technique – All people using insulin should be instructed in proper insulin injection technique. (See 'Injection technique' above.)

Size of subcutaneous depot – Insulin absorption is variable between people and in the same person, especially for longer-acting preparations. Variability is greater with larger injection doses. (See 'Size of subcutaneous depot' above.)

ACKNOWLEDGMENT — The UpToDate editorial staff acknowledges David McCulloch, MD, who contributed to earlier versions of this topic review.

  1. Richter B, Neises G. 'Human' insulin versus animal insulin in people with diabetes mellitus. Cochrane Database Syst Rev 2005; :CD003816.
  2. Hirsch IB, Juneja R, Beals JM, et al. The Evolution of Insulin and How it Informs Therapy and Treatment Choices. Endocr Rev 2020; 41.
  3. Lucidi P, Porcellati F, Marinelli Andreoli A, et al. Pharmacokinetics and Pharmacodynamics of NPH Insulin in Type 1 Diabetes: The Importance of Appropriate Resuspension Before Subcutaneous Injection. Diabetes Care 2015; 38:2204.
  4. Davidson MB, Navar MD, Echeverry D, Duran P. U-500 regular insulin: clinical experience and pharmacokinetics in obese, severely insulin-resistant type 2 diabetic patients. Diabetes Care 2010; 33:281.
  5. Ma X, Benson CT, Prescilla R, et al. Pharmacokinetics and Pharmacodynamics of Human Regular U-500 Insulin Administered via Continuous Subcutaneous Insulin Infusion Versus Subcutaneous Injection in Adults With Type 2 Diabetes and High-Dose Insulin Requirements. J Diabetes Sci Technol 2022; 16:401.
  6. de la Peña A, Riddle M, Morrow LA, et al. Pharmacokinetics and pharmacodynamics of high-dose human regular U-500 insulin versus human regular U-100 insulin in healthy obese subjects. Diabetes Care 2011; 34:2496.
  7. Ballani P, Tran MT, Navar MD, Davidson MB. Clinical experience with U-500 regular insulin in obese, markedly insulin-resistant type 2 diabetic patients. Diabetes Care 2006; 29:2504.
  8. Shrestha RT, Kumar AF, Taddese A, et al. Duration and onset of action of high dose U-500 regular insulin in severely insulin resistant subjects with type 2 diabetes. Endocrinol Diabetes Metab 2018; 1:e00041.
  9. Howey DC, Bowsher RR, Brunelle RL, Woodworth JR. [Lys(B28), Pro(B29)]-human insulin. A rapidly absorbed analogue of human insulin. Diabetes 1994; 43:396.
  10. Home PD, Lindholm A, Hylleberg B, Round P. Improved glycemic control with insulin aspart: a multicenter randomized double-blind crossover trial in type 1 diabetic patients. UK Insulin Aspart Study Group. Diabetes Care 1998; 21:1904.
  11. Hirsch IB. Insulin analogues. N Engl J Med 2005; 352:174.
  12. Rapid acting insulin analogs. The Medical Letter 2009; 51:98.
  13. Becker RH, Frick AD. Clinical pharmacokinetics and pharmacodynamics of insulin glulisine. Clin Pharmacokinet 2008; 47:7.
  14. Rosenstock J, Bajaj HS, Janež A, et al. Once-Weekly Insulin for Type 2 Diabetes without Previous Insulin Treatment. N Engl J Med 2020; 383:2107.
  15. Frias JP, Chien J, Zhang Q, et al. Once Weekly Basal Insulin Fc (BIF) is Safe and Efficacious in Patients with Type 2 Diabetes Mellitus (T2DM) Previously Treated With Basal Insulin. J Endocr Soc 2021; 5:A448.
  16. Evans M, Schumm-Draeger PM, Vora J, King AB. A review of modern insulin analogue pharmacokinetic and pharmacodynamic profiles in type 2 diabetes: improvements and limitations. Diabetes Obes Metab 2011; 13:677.
  17. Zib I, Raskin P. Novel insulin analogues and its mitogenic potential. Diabetes Obes Metab 2006; 8:611.
  18. Owen WE, Roberts WL. Cross-reactivity of three recombinant insulin analogs with five commercial insulin immunoassays. Clin Chem 2004; 50:257.
  19. Biester T, Kordonouri O, Danne T. Pharmacological Properties of Faster-Acting Insulin Aspart. Curr Diab Rep 2017; 17:101.
  20. Heise T, Stender-Petersen K, Hövelmann U, et al. Pharmacokinetic and Pharmacodynamic Properties of Faster-Acting Insulin Aspart versus Insulin Aspart Across a Clinically Relevant Dose Range in Subjects with Type 1 Diabetes Mellitus. Clin Pharmacokinet 2017; 56:649.
  21. Heise T, Pieber TR, Danne T, et al. A Pooled Analysis of Clinical Pharmacology Trials Investigating the Pharmacokinetic and Pharmacodynamic Characteristics of Fast-Acting Insulin Aspart in Adults with Type 1 Diabetes. Clin Pharmacokinet 2017; 56:551.
  22. Klaff L, Cao D, Dellva MA, et al. Ultra rapid lispro improves postprandial glucose control compared with lispro in patients with type 1 diabetes: Results from the 26-week PRONTO-T1D study. Diabetes Obes Metab 2020; 22:1799.
  23. Malecki MT, Cao D, Liu R, et al. Ultra-Rapid Lispro Improves Postprandial Glucose Control and Time in Range in Type 1 Diabetes Compared to Lispro: PRONTO-T1D Continuous Glucose Monitoring Substudy. Diabetes Technol Ther 2020; 22:853.
  24. Gentile S, Fusco A, Colarusso S, et al. A randomized, open-label, comparative, crossover trial on preference, efficacy, and safety profiles of lispro insulin u-100 versus concentrated lispro insulin u-200 in patients with type 2 diabetes mellitus: a possible contribution to greater treatment adherence. Expert Opin Drug Saf 2018; 17:445.
  25. Heinemann L, Linkeschova R, Rave K, et al. Time-action profile of the long-acting insulin analog insulin glargine (HOE901) in comparison with those of NPH insulin and placebo. Diabetes Care 2000; 23:644.
  26. Owens DR, Traylor L, Mullins P, Landgraf W. Patient-level meta-analysis of efficacy and hypoglycaemia in people with type 2 diabetes initiating insulin glargine 100U/mL or neutral protamine Hagedorn insulin analysed according to concomitant oral antidiabetes therapy. Diabetes Res Clin Pract 2017; 124:57.
  27. Rosenstock J, Dailey G, Massi-Benedetti M, et al. Reduced hypoglycemia risk with insulin glargine: a meta-analysis comparing insulin glargine with human NPH insulin in type 2 diabetes. Diabetes Care 2005; 28:950.
  28. Becker RH, Dahmen R, Bergmann K, et al. New insulin glargine 300 Units · mL-1 provides a more even activity profile and prolonged glycemic control at steady state compared with insulin glargine 100 Units · mL-1. Diabetes Care 2015; 38:637.
  29. http://www.accessdata.fda.gov/drugsatfda_docs/label/2015/206538lbl.pdf (Accessed on March 13, 2015).
  30. Riddle MC, Bolli GB, Ziemen M, et al. New insulin glargine 300 units/mL versus glargine 100 units/mL in people with type 2 diabetes using basal and mealtime insulin: glucose control and hypoglycemia in a 6-month randomized controlled trial (EDITION 1). Diabetes Care 2014; 37:2755.
  31. Bolli GB, Riddle MC, Bergenstal RM, et al. New insulin glargine 300 U/ml compared with glargine 100 U/ml in insulin-naïve people with type 2 diabetes on oral glucose-lowering drugs: a randomized controlled trial (EDITION 3). Diabetes Obes Metab 2015; 17:386.
  32. Yki-Järvinen H, Bergenstal R, Ziemen M, et al. New insulin glargine 300 units/mL versus glargine 100 units/mL in people with type 2 diabetes using oral agents and basal insulin: glucose control and hypoglycemia in a 6-month randomized controlled trial (EDITION 2). Diabetes Care 2014; 37:3235.
  33. Freemantle N, Chou E, Frois C, et al. Safety and efficacy of insulin glargine 300 u/mL compared with other basal insulin therapies in patients with type 2 diabetes mellitus: a network meta-analysis. BMJ Open 2016; 6:e009421.
  34. Sanches AC, Correr CJ, Venson R, Pontarolo R. Revisiting the efficacy of long-acting insulin analogues on adults with type 1 diabetes using mixed-treatment comparisons. Diabetes Res Clin Pract 2011; 94:333.
  35. Swinnen SG, Simon AC, Holleman F, et al. Insulin detemir versus insulin glargine for type 2 diabetes mellitus. Cochrane Database Syst Rev 2011; :CD006383.
  36. Jonassen I, Havelund S, Hoeg-Jensen T, et al. Design of the novel protraction mechanism of insulin degludec, an ultra-long-acting basal insulin. Pharm Res 2012; 29:2104.
  37. Hövelmann U, Brøndsted L, Kristensen NR, et al. Insulin icodec: An insulin analog suited for once-weekly dosing in type 2 diabetes. Diabetes 2020; 69 Suppl 1:237.
  38. Russell-Jones D, Babazono T, Cailleteau R, et al. Once-weekly insulin icodec versus once-daily insulin degludec as part of a basal-bolus regimen in individuals with type 1 diabetes (ONWARDS 6): a phase 3a, randomised, open-label, treat-to-target trial. Lancet 2023; 402:1636.
  39. Davis MD, Beck RW, Home PD, et al. Early retinopathy progression in four randomized trials comparing insulin glargine and NPH [corrected] insulin. Exp Clin Endocrinol Diabetes 2007; 115:240.
  40. Rosenstock J, Fonseca V, McGill JB, et al. Similar progression of diabetic retinopathy with insulin glargine and neutral protamine Hagedorn (NPH) insulin in patients with type 2 diabetes: a long-term, randomised, open-label study. Diabetologia 2009; 52:1778.
  41. Lin JC, Shau WY, Lai MS. Long-acting insulin analogues and diabetic retinopathy: a retrospective cohort study. Clin Ther 2014; 36:1255.
  42. Hemkens LG, Grouven U, Bender R, et al. Risk of malignancies in patients with diabetes treated with human insulin or insulin analogues: a cohort study. Diabetologia 2009; 52:1732.
  43. Colhoun HM, SDRN Epidemiology Group. Use of insulin glargine and cancer incidence in Scotland: a study from the Scottish Diabetes Research Network Epidemiology Group. Diabetologia 2009; 52:1755.
  44. Jonasson JM, Ljung R, Talbäck M, et al. Insulin glargine use and short-term incidence of malignancies-a population-based follow-up study in Sweden. Diabetologia 2009; 52:1745.
  45. Currie CJ, Poole CD, Gale EA. The influence of glucose-lowering therapies on cancer risk in type 2 diabetes. Diabetologia 2009; 52:1766.
  46. Rosenstock J, Fonseca V, McGill JB, et al. Similar risk of malignancy with insulin glargine and neutral protamine Hagedorn (NPH) insulin in patients with type 2 diabetes: findings from a 5 year randomised, open-label study. Diabetologia 2009; 52:1971.
  47. Chang CH, Toh S, Lin JW, et al. Cancer risk associated with insulin glargine among adult type 2 diabetes patients--a nationwide cohort study. PLoS One 2011; 6:e21368.
  48. Morden NE, Liu SK, Smith J, et al. Further exploration of the relationship between insulin glargine and incident cancer: a retrospective cohort study of older Medicare patients. Diabetes Care 2011; 34:1965.
  49. Suissa S, Azoulay L, Dell'Aniello S, et al. Long-term effects of insulin glargine on the risk of breast cancer. Diabetologia 2011; 54:2254.
  50. Wu JW, Azoulay L, Majdan A, et al. Long-Term Use of Long-Acting Insulin Analogs and Breast Cancer Incidence in Women With Type 2 Diabetes. J Clin Oncol 2017; 35:3647.
  51. Pradhan R, Yin H, Yu OHY, Azoulay L. The Use of Long-Acting Insulin Analogs and the Risk of Colorectal Cancer Among Patients with Type 2 Diabetes: A Population-Based Cohort Study. Drug Saf 2020; 43:103.
  52. But A, De Bruin ML, Bazelier MT, et al. Cancer risk among insulin users: comparing analogues with human insulin in the CARING five-country cohort study. Diabetologia 2017; 60:1691.
  53. US Food and Drug Administration. FDA Drug Safety Communication: Update to ongoing safety review of Lantus (insulin glargine) and possible risk of cancer. http://www.fda.gov/Drugs/DrugSafety/ucm239376.htm (Accessed on January 17, 2011).
  54. Roach P, Bai S, Charbonnel B, et al. Effects of multiple daily injection therapy with Humalog mixtures versus separately injected insulin lispro and NPH insulin in adults with type I diabetes mellitus. Clin Ther 2004; 26:502.
  55. American Diabetes Association. 9. Pharmacologic Approaches to Glycemic Treatment: Standards of Medical Care in Diabetes-2020. Diabetes Care 2020; 43:S98.
  56. Bode BW, McGill JB, Lorber DL, et al. Inhaled Technosphere Insulin Compared With Injected Prandial Insulin in Type 1 Diabetes: A Randomized 24-Week Trial. Diabetes Care 2015; 38:2266.
  57. Lteif AN, Schwenk WF. Accuracy of pen injectors versus insulin syringes in children with type 1 diabetes. Diabetes Care 1999; 22:137.
  58. Engwerda EEC, Tack CJ, de Galan BE. Pharmacokinetic and Pharmacodynamic Variability of Insulin When Administered by Jet Injection. J Diabetes Sci Technol 2017; 11:947.
  59. Engwerda EEC, Tack CJ, de Galan BE. A comparison of the pharmacodynamic profiles of jet-injected regular human insulin versus conventionally administered insulin aspart in healthy volunteers. Diabetes Res Clin Pract 2016; 121:86.
  60. Owens DR, Coates PA, Luzio SD, et al. Pharmacokinetics of 125I-labeled insulin glargine (HOE 901) in healthy men: comparison with NPH insulin and the influence of different subcutaneous injection sites. Diabetes Care 2000; 23:813.
  61. Nosek L, Coester HV, Roepstorff C, et al. Glucose-lowering effect of insulin degludec is independent of subcutaneous injection region. Clin Drug Investig 2014; 34:673.
  62. Frid AH, Kreugel G, Grassi G, et al. New Insulin Delivery Recommendations. Mayo Clin Proc 2016; 91:1231.
  63. Fleming DR, Jacober SJ, Vandenberg MA, et al. The safety of injecting insulin through clothing. Diabetes Care 1997; 20:244.
  64. Binder C, Lauritzen T, Faber O, Pramming S. Insulin pharmacokinetics. Diabetes Care 1984; 7:188.
  65. Lauritzen T, Pramming S, Deckert T, Binder C. Pharmacokinetics of continuous subcutaneous insulin infusion. Diabetologia 1983; 24:326.
  66. Klemp P, Staberg B, Madsbad S, Kølendorf K. Smoking reduces insulin absorption from subcutaneous tissue. Br Med J (Clin Res Ed) 1982; 284:237.
  67. Riccio A, Avogaro A, Valerio A, et al. Improvement of basal hepatic glucose production and fasting hyperglycemia of type I diabetic patients treated with human recombinant ultralente insulin. Diabetes Care 1994; 17:535.
  68. Koivisto VA, Felig P. Effects of leg exercise on insulin absorption in diabetic patients. N Engl J Med 1978; 298:79.
  69. Koivisto VA. Sauna-induced acceleration in insulin absorption from subcutaneous injection site. Br Med J 1980; 280:1411.
  70. Linde B. Dissociation of insulin absorption and blood flow during massage of a subcutaneous injection site. Diabetes Care 1986; 9:570.
  71. Berger M, Cüppers HJ, Hegner H, et al. Absorption kinetics and biologic effects of subcutaneously injected insulin preparations. Diabetes Care 1982; 5:77.
Topic 1752 Version 46.0

References

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