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Mannitol

Mannitol is a naturally occurring six-carbon sugar alcohol, also known as a polyol, with the molecular formula C₆H₁₄O₆ and serving as an isomer of sorbitol. It appears as a white crystalline powder or free-flowing granules that is freely soluble in water, providing approximately 1.6 calories per gram and exhibiting about half the sweetness of sucrose along with a cooling effect in the mouth. Chemically designated as D-mannitol, it is minimally metabolized in the body, with around 80% excreted unchanged in the urine, and has an elimination half-life of 0.5 to 2.5 hours. In the food industry, mannitol functions as a low-calorie sweetener and bulking agent, particularly in products like chewing gums, candies, and diabetic-friendly foods, where it does not significantly elevate blood sugar levels and can mask bitter tastes. It is recognized as generally safe for consumption, though excessive intake may produce a laxative effect due to its poor absorption in the small intestine. Additionally, mannitol is widely used as an excipient in pharmaceuticals, acting as a diluent in tablets and capsules, a tonicity agent in solutions, and a bulking agent in lyophilized preparations, owing to its stability and non-hygroscopic properties under controlled conditions. Medically, mannitol is primarily employed as an intravenous osmotic diuretic to promote diuresis, reduce elevated intracranial pressure in cerebral edema, and lower intraocular pressure in conditions like glaucoma. It works by increasing the osmolarity of the glomerular filtrate, thereby inhibiting water reabsorption in the kidneys and drawing fluid from tissues into the bloodstream. Other applications include irrigation during transurethral surgical procedures to prevent hemolysis and, in inhalation form, as a diagnostic tool for assessing airway hyperresponsiveness in asthma or to improve lung function in cystic fibrosis patients. Mannitol is commercially produced through chemical hydrogenation of fructose or via microbial fermentation, ensuring its availability for these diverse therapeutic roles.

Chemistry

Molecular structure

Mannitol has the molecular formula C6H14O6 and the systematic IUPAC name (2R,3R,4R,5R)-hexane-1,2,3,4,5,6-hexol. As a hexitol, it features a straight-chain aliphatic backbone with six carbon atoms, each bearing a hydroxyl group, resulting in an open-chain polyol structure without a carbonyl group. Unlike its parent sugar D-mannose, which predominantly exists in cyclic hemiacetal forms such as pyranose or furanose rings, mannitol remains acyclic due to the absence of an aldehyde group, though minor cyclic derivatives can form under specific chemical modifications. Mannitol is the C-2 epimer of sorbitol, differing only in the stereochemical configuration at the second carbon atom, where mannitol has the 2R configuration compared to sorbitol's 2S. It is derived from the reduction of D-mannose, an aldohexose epimer of D-glucose at the C-2 position. In contrast to glucose (an aldose) and fructose (a ketose), which cyclize via hemiacetal formation and exhibit reducing properties, mannitol functions as a non-reducing sugar alcohol or polyol, contributing to its stability and low reactivity. The molecule possesses four chiral centers at carbons 2, 3, 4, and 5, conferring overall chirality to the D-enantiomer, which is the naturally occurring form. Its specific optical rotation is +23° to +25° ([α]D20, c=10 in water), reflecting the cumulative effect of these stereocenters. The open-chain Fischer projection of D-mannitol shows hydroxyl groups oriented as follows: left at C2, left at C3, right at C4, and right at C5, consistent with the D-series configuration.

Physical and chemical properties

Mannitol is a white, crystalline powder that is odorless and possesses a sweet taste, approximately 50-70% as sweet as sucrose. It exhibits high solubility in water, reaching 216 g/L at 25°C, while its solubility in ethanol is much lower, around 12 g/L, and it is practically insoluble in most other organic solvents. The compound has a melting point of 166–168 °C and a density of 1.52 g/cm³ at 20°C. Mannitol demonstrates good chemical stability under standard ambient conditions and is non-hygroscopic, making it resistant to moisture absorption. It remains stable when heated up to its melting point but undergoes thermal decomposition above 200°C, primarily through endothermic processes that release volatile products. It readily forms esters upon reaction with acids due to its multiple hydroxyl groups.

Natural occurrence

Sources in nature

Mannitol occurs naturally in a wide range of plants, where it serves as an osmoprotectant during stress responses such as drought or salinity. It is particularly abundant in the exudates of certain trees, including the manna ash (Fraxinus ornus) at 30–50% of the exudate composition and the plane tree (Platanus spp.) at 80–90%. Olive tree (Olea europaea) exudates also contain significant amounts of mannitol. In fruits and vegetables, it is present in low levels (typically <1%) in strawberries, celery, and pineapple, while mushrooms can accumulate up to 50% mannitol on a dry weight basis, making it a dominant storage carbohydrate in species like Agaricus bisporus. In algae and seaweeds, mannitol is a primary photosynthetic product, especially in brown algae (Phaeophyceae), where it constitutes 20–30% of the dry matter and aids in osmotic regulation. For instance, species such as Laminaria digitata and Macrocystis pyrifera exhibit high mannitol contents, up to 12.4% by weight in the latter. Microorganisms produce mannitol as an osmoprotectant to maintain cellular water balance under environmental stress. It is synthesized by fungi (e.g., Aspergillus niger, comprising 10–15% of conidiospore dry weight), bacteria (e.g., marine species like Zobellia galactanivorans), and yeasts, where it supports growth and survival in osmotic-challenging conditions. Although mannitol is ubiquitous across taxa, its presence in animals is minimal and not dietarily or endogenously significant.

Biosynthetic pathways

In plants and algae, mannitol biosynthesis primarily occurs through the polyol pathway, where fructose-6-phosphate is reduced to mannitol-1-phosphate by the enzyme mannitol-1-phosphate dehydrogenase (M1PDH), an NADPH-dependent reductase, followed by dephosphorylation of mannitol-1-phosphate to yield free mannitol via mannitol-1-phosphatase (M1Pase). This two-step process is prominent in brown algae, where mannitol serves as a major photosynthetic product and carbon storage compound, accumulating to levels representing up to 30% of the organism's dry weight in species such as Saccharina japonica. In fungi and bacteria, mannitol is synthesized via a distinct pathway involving mannitol dehydrogenase (MDH), which catalyzes the reversible reduction of fructose or mannose to mannitol using NADPH as a cofactor. This enzyme is widespread among filamentous fungi, where it facilitates a cyclical metabolism of mannitol for redox balancing and osmoprotection, and in bacteria like Lactobacillus species, where MDH homologs enable mannitol production from hexose substrates. Mannitol accumulation plays a critical osmoregulatory role in these organisms, particularly under salt or drought stress, where it functions as a compatible solute in the polyol pathway to maintain cellular turgor and protect against dehydration without disrupting enzymatic activity. In algae and plants, stress-induced upregulation of M1PDH enhances mannitol synthesis to counter osmotic imbalances, while in bacteria such as Pseudomonas putida, MDH-mediated production helps stabilize cytoplasmic water potential during high-salinity exposure. Genetically, mannitol biosynthesis is governed by key enzyme-encoding genes, such as those for M1PDH (often denoted as mtlD or homologs in bacteria) and MDH (mtlK in some fungi), which are regulated by environmental cues like salinity to modulate polyol levels. In algae, these genes exhibit diversity across taxa, with brown algal M1PDH variants showing redox sensitivity that fine-tunes synthesis under fluctuating conditions. Unlike sorbitol biosynthesis, which relies on aldose-6-phosphate reductase to convert glucose-6-phosphate to sorbitol-6-phosphate in certain plants, mannitol production specifically utilizes ketose-specific reductases like M1PDH or MDH to process fructose-6-phosphate or free fructose, reflecting adaptations to different metabolic niches and stress responses.

Production

Natural extraction

Mannitol can be extracted from natural sources such as plant exudates and marine algae through physical separation and purification techniques. In plant-based methods, mannitol is primarily obtained from the exudate known as manna produced by the manna ash tree (Fraxinus ornus), native to regions like Sicily, Italy. The process involves collecting the sweet sap exudate from incisions in the tree bark during summer, followed by leaching the crude manna in water to dissolve the mannitol content, and subsequent crystallization by evaporation and cooling. Historical extraction yields from this method were relatively low, typically ranging from 10% to 20% of the raw manna due to inefficient collection and processing techniques, although the manna itself can contain up to 50% mannitol by weight. For algal sources, mannitol is isolated from brown seaweeds such as Laminaria species, which accumulate 10% to 30% mannitol in their dry biomass as a photosynthetic product. Extraction typically employs hot water (around 100°C) or ethanol solvents to leach mannitol from the algal tissue, followed by purification steps including filtration to remove solids and ion exchange chromatography to separate it from other polyols and salts. Modern optimized processes achieve yields of up to 25% mannitol from dry algal biomass, with extraction efficiencies reaching 78% of the available mannitol under controlled conditions. Despite these advances, natural extraction faces challenges including contamination with other polyols like sorbitol or algal components such as alginate and polyphenols, which complicate purification, as well as seasonal variability in mannitol content influenced by environmental factors like temperature and rainfall. In F. ornus, mannitol levels peak during drought periods, while in brown algae, concentrations are highest in summer and autumn. Overall, these methods are environmentally sustainable with low energy inputs compared to synthetic alternatives, but production is limited by source availability; traditional manna harvesting yields only 1 to 5 tons annually from Sicilian groves covering about 6,700 hectares historically. The purification process for both sources generally involves evaporation of the leachate to concentrate the solution, filtration to eliminate impurities, and recrystallization through controlled cooling to achieve high purity levels exceeding 99%. This stepwise approach ensures the removal of residual contaminants, yielding white crystalline mannitol suitable for pharmaceutical and food applications.

Chemical synthesis

Mannitol is industrially synthesized through catalytic hydrogenation, a non-biological chemical process that reduces fructose or glucose-fructose mixtures to the corresponding sugar alcohols. The primary method employs Raney nickel as the catalyst, operating at temperatures of 80–130°C and hydrogen pressures of 50–100 bar in aqueous solution. This reaction typically yields a mixture where mannitol constitutes 45–50% from fructose feedstocks, with the balance primarily sorbitol. Historically, the process begins with the inversion of sucrose to generate an equimolar glucose-fructose mixture (invert sugar), followed by hydrogenation. The overall reduction can be represented by the equation: \text{C}_6\text{H}_{12}\text{O}_6 + \text{H}_2 \rightarrow \text{C}_6\text{H}_{14}\text{O}_6 This step converts the keto or aldose form to the polyol, with Raney nickel facilitating the stereospecific addition of hydrogen. Post-reaction, purification is essential due to the 1:1 mannitol-sorbitol ratio from fructose reduction. Separation commonly involves chromatographic fractionation to isolate high-purity mannitol fractions (>98%), or crystallization exploiting differences in solubility—mannitol being less soluble in ethanol-water mixtures. Alternative pure chemical routes include electroreduction of fructose using copper-based cathodes, achieving up to 60% conversion to mannitol and sorbitol, though these remain largely experimental and not scaled industrially. Enzymatic-chemical hybrids exist but deviate from strictly abiotic synthesis. This catalytic approach supports global production of approximately 150,000 tons annually as of 2024, with bulk costs ranging from $5–10 per kg; however, the high-temperature and high-pressure conditions make it energy-intensive compared to biological alternatives.

Biotechnological production

Biotechnological production of mannitol relies on microbial fermentation processes utilizing engineered yeasts and bacteria, with glucose or fructose serving as primary substrates to achieve high conversion efficiencies. Yeasts such as Candida magnoliae convert fructose-glucose mixtures into mannitol through mannitol dehydrogenase activity, yielding up to 209 g/L with 83% efficiency in optimized conditions. Similarly, lactic acid bacteria like Lactobacillus reuteri and Lactococcus lactis produce mannitol from fructose, with engineered strains reaching yields of 66% or more by redirecting metabolic flux from lactic acid production. Engineered variants of these organisms, including Leuconostoc mesenteroides, have demonstrated yields exceeding 90% from fructose in fed-batch systems. Genetic engineering plays a central role in enhancing productivity, particularly through overexpression of mannitol-2-dehydrogenase (MDH), which catalyzes the reduction of fructose to mannitol. In Lactococcus lactis, introducing the mtlD gene from Lactobacillus plantarum boosts mannitol accumulation by up to 27% of glucose substrate in lactate dehydrogenase-deficient strains. Cofactor balancing, especially maintaining NADPH availability for MDH, is critical; strategies like co-expressing NADPH-dependent enzymes or transhydrogenases improve redox equilibrium and prevent bottlenecks in reduction steps. The typical process employs fed-batch fermentation to minimize substrate inhibition, conducted at 30–37°C and pH 5–6 to optimize enzyme activity and cell viability. Substrates are incrementally added to maintain concentrations below 100–150 g/L, enabling productivities of 1–2 g/L/h over 48–96 hours. Downstream recovery involves ultrafiltration to remove biomass and proteins, followed by ion-exchange purification and vacuum evaporation, culminating in cooling crystallization to isolate mannitol crystals with >99% purity. Compared to chemical synthesis, biotechnological methods offer lower energy requirements due to milder operating conditions and higher product purity from selective microbial pathways, reducing purification needs. Recent studies, including 2024 reports on optimized Lactobacillus strains, demonstrate fructose conversions exceeding 50%, often approaching 90% in engineered systems, while utilizing renewable feedstocks like agricultural byproducts. Pilot-scale operations, such as 100 L fermenters with Leuconostoc species, have validated scalability with yields of 93–97%, paving the way for industrial outputs in the tens of tons annually. Despite these advances, challenges persist, including byproduct inhibition from lactic acid or ethanol accumulation, which reduces yields below 80% in non-optimized strains, and difficulties in scaling to industrial volumes due to oxygen transfer limitations and cofactor instability. Economic viability remains constrained by substrate costs and downstream losses, though ongoing strain adaptations address these to support commercial pilots targeting 100 tons/year.

Medical uses

Intravenous administration

Mannitol is administered intravenously as an osmotic diuretic to reduce intracranial pressure (ICP) in cases of cerebral edema and elevated intraocular pressure when not responsive to other therapies, with off-label use to promote diuresis in the prevention and treatment of oliguria or anuria due to acute renal failure. For osmotic diuresis, a test dose of 0.2 g/kg body weight is typically given as a 25% solution over 3 to 5 minutes; if adequate urine flow (at least 30 to 50 mL per hour) occurs for 2 to 3 hours, a therapeutic dose of 0.5 to 1 g/kg is administered as a 20% solution over 30 to 60 minutes. This approach helps maintain urine flow and prevent acute kidney injury in high-risk patients, such as those undergoing cardiovascular or major abdominal surgery. In neurosurgical settings, intravenous mannitol is used to reduce elevated ICP associated with cerebral edema, particularly in traumatic brain injury or post-surgical swelling, with effects onsetting within 15 to 30 minutes and lasting 3 to 8 hours. Doses for ICP reduction range from 0.25 to 1.5 g/kg body weight, infused as a 15% to 25% solution over 30 to 60 minutes, with cumulative daily doses typically limited to less than 200-300 g to avoid rebound effects. Efficacy studies indicate that mannitol can lower ICP by approximately 20% to 30% in responsive patients, improving cerebral perfusion and reducing brain volume through osmotic effects. Mannitol exerts its effects by increasing the osmolarity of the glomerular filtrate, creating an osmotic gradient that inhibits water reabsorption in the renal tubules and draws fluid from tissues into the bloodstream. During administration, patients require close monitoring of serum electrolytes, osmolality, urine output, and fluid balance to prevent complications such as electrolyte imbalances or volume depletion. Contraindications include established anuria without response to a test dose, active intracranial bleeding, severe pulmonary congestion or edema, and severe dehydration. Mannitol injection for intravenous use has been FDA-approved since 1964 for these indications.

Inhaled administration

Inhaled mannitol is administered as a dry powder via oral inhalation using a dedicated device, primarily for diagnostic and therapeutic purposes in respiratory conditions. For diagnostic use, mannitol serves as a challenge agent in the bronchial hyperresponsiveness test to assess airway sensitivity in patients suspected of asthma or other obstructive lung diseases. The test involves sequential inhalation of increasing doses starting from 0 mg up to a cumulative dose of 635 mg, with spirometry monitoring for a ≥15% decline in FEV1 indicating positive hyperresponsiveness. This non-invasive method offers a safer alternative to methacholine challenges, with Aridol (the branded diagnostic kit) approved in the EU in 2009, Australia in 2006, and the US in 2010. Therapeutically, dry powder mannitol (Bronchitol) is indicated as an add-on maintenance therapy to improve pulmonary function in adults with cystic fibrosis (CF) by promoting osmotic hydration of airway surfaces, which enhances mucus clearance and reduces viscosity. Administered as 400 mg (contents of 10 × 40 mg capsules) twice daily via inhalation, it has demonstrated sustained improvements in lung function, with clinical phase 3 trials showing an average increase in FEV1 of 5–10% from baseline over 26 weeks compared to control. Bronchitol received approval in Australia in 2011, the EU in 2012, and the US in 2020 for this use in CF patients aged 18 and older. In non-CF bronchiectasis, inhaled mannitol at 400 mg twice daily has been investigated for its mucolytic effects, hydrating mucus to improve clearance and lung function, though it is not universally approved and efficacy varies by region. Short-term studies (up to 2 weeks) have shown enhancements in mucus hydration, quality of life, and spirometric parameters, supporting its role as a potential adjunct in select patients where standard therapies are insufficient. In Australia, it has been considered for bronchiectasis management following early approvals, but long-term phase 3 data indicated no significant reduction in exacerbations, limiting broader adoption. The formulation features spray-dried mannitol particles with an aerodynamic diameter of 2–5 μm, optimized for deep lung deposition and minimal oropharyngeal impaction during inhalation. This design, combined with its non-steroidal nature and portable inhaler, provides a convenient, steroid-free option for chronic respiratory management, though common side effects such as cough and throat irritation may occur (see Safety profile section).

Oral administration

Mannitol is primarily administered orally as an osmotic laxative to facilitate bowel preparation for procedures such as colonoscopy. Due to its poor absorption in the gastrointestinal tract—typically around 10-20% of the dose—it remains largely unabsorbed, increasing intraluminal osmolarity and drawing water into the intestines to induce catharsis. Doses for this purpose commonly range from 100 to 200 g, often dissolved in 750 mL to 2 L of water and consumed 4-6 hours before the procedure, with studies demonstrating effective cleansing comparable to other agents while maintaining good tolerability. In pharmaceutical applications, oral mannitol functions as an excipient in chewable tablets, lozenges, and other formulations, where its mild sweetness and characteristic cooling effect upon dissolution improve palatability and mask bitter tastes of active ingredients. For therapeutic oral use beyond bowel preparation, such as short-term relief of constipation, doses are substantially lower, typically 1-5 g, administered as powders or solutions to minimize gastrointestinal side effects. Oral mannitol is commonly used for short-term laxative effects in constipation, particularly when other agents are unsuitable, but emphasize monitoring for dehydration. It is listed on the WHO Model List of Essential Medicines as an osmotic diuretic, though primarily in injectable form; oral use aligns with its cathartic properties for episodic constipation relief. Concomitant administration with diuretics, such as loop or thiazide agents, may potentiate electrolyte imbalances or dehydration due to enhanced osmotic diuresis. Post-2020 developments have focused on optimizing oral mannitol for bowel preparation, with phase III trials confirming high efficacy and superior patient satisfaction compared to polyethylene glycol regimens, though no major expansions into new therapeutic roles have emerged, reinforcing its established position as a laxative and excipient.

Other uses

Food applications

Mannitol functions as a low-calorie sweetener in food products, delivering 50–70% of the sweetness of sucrose with a caloric value of 1.6 kcal/g, making it suitable for reducing overall energy content in formulations. In the European Union, it is approved as the food additive E421 for such uses. In confectionery, mannitol is commonly incorporated into chewing gum and hard candies, where it provides a desirable cooling sensation upon dissolution and serves as an anti-caking agent to prevent clumping in powdered coatings. Its low hygroscopicity further enhances product stability by minimizing moisture absorption in these applications. As a bulking agent, mannitol adds volume and texture to low-carbohydrate diet foods and products designed for diabetics, while its non-cariogenic nature helps reduce the risk of tooth decay compared to traditional sugars. Regulatory bodies have established mannitol as generally recognized as safe (GRAS) by the U.S. FDA for direct use as a sweetener and bulking agent in foods since the 1970s. To prevent laxative effects from osmotic activity in the intestines, intake should be limited to 20–30 g per day, with labeling required on products that may lead to exceeding 20 g in a single serving. Mannitol is found in specific items such as diet sodas for its sweetening without full caloric impact, ice cream as a texturizer in low-sugar variants, and baked goods where its melting point of 167–170°C ensures heat stability during processing.

Analytical applications

Mannitol is widely employed in analytical chemistry for the determination of boron through the formation of a stable complex with boric acid, which converts the weak boric acid into a stronger acid suitable for titration. This complexation allows for precise acid-base titration, typically using sodium hydroxide as the titrant, with the equivalence point detected at approximately pH 9.0 using indicators like phenolphthalein or pH meters; the method achieves high accuracy for boron concentrations in environmental, soil, and industrial samples, with detection limits as low as 0.1 μg/mL. In chromatographic separations, mannitol functions as a reference standard for identifying and quantifying sugar alcohols in complex mixtures, such as food extracts or biological fluids. High-performance liquid chromatography (HPLC) methods, often utilizing ion-exclusion columns like Rezex ROA-Organic Acid H+ with dilute sulfuric acid as the mobile phase, separate mannitol from analogs like sorbitol and xylitol; under typical conditions (e.g., 0.01 N H₂SO₄ at 80°C), mannitol exhibits a retention time of about 12-15 minutes, enabling baseline resolution and relative standard deviations below 2% for peak area quantification. For pharmaceutical quality control, the United States Pharmacopeia (USP) specifies chromatographic assays to evaluate mannitol purity, primarily through liquid chromatography with refractive index detection on amino columns, which quantifies mannitol content above 97% while identifying impurities like sorbitol at levels not exceeding 2.0%. Complementary enzymatic methods, employing mannitol-2-dehydrogenase to oxidize mannitol to fructose with NADH production monitored at 340 nm, provide rapid specificity for mannitol in formulations, with linear ranges from 0.5 to 50 μg/mL and recoveries exceeding 98%. Mannitol also serves as a reagent in qualitative tests for reducing sugars, acting as a non-reducing polyol negative control in assays like Benedict's or Fehling's, where its lack of reaction confirms the specificity for aldoses and ketoses; this utility stems from its stable, non-oxidizable structure under alkaline conditions. Furthermore, mannitol contributes to buffer stability in analytical protocols, such as in capillary electrophoresis or HPLC mobile phases, by maintaining ionic strength and preventing pH drift without interfering with analyte interactions, as demonstrated in its use for protein stabilization during storage. Recent advancements in metabolomics have integrated mannitol as a biomarker for plant stress responses, particularly in post-2020 studies profiling abiotic stresses like drought and salinity; for instance, elevated mannitol accumulation in root tips of rice under drought stress signals adaptive osmotic regulation.

Industrial applications

Mannitol serves as a plasticizer in various resins, notably enhancing the flexibility and processability of polyvinyl alcohol (PVA) films used in packaging and coatings. By reducing the glass transition temperature and increasing free volume in the polymer matrix, mannitol at loadings of 5–10 wt% improves film elongation and mechanical properties without significantly compromising tensile strength. In the cosmetics industry, mannitol functions as a humectant in lotions and creams, drawing moisture to the skin to maintain hydration and prevent dryness. Its non-irritating nature makes it suitable for sensitive formulations, where it also aids in stabilizing emulsions. Additionally, mannitol provides a cooling sensation in toothpastes due to its endothermic dissolution, enhancing user comfort without altering flavor profiles. Beyond these, mannitol acts as a desiccant in diagnostic kits, leveraging its low moisture uptake to protect moisture-sensitive components during storage and transport. In biotechnology, it serves as a cryoprotectant for preserving cells, proteins, and nanoparticles during freeze-drying and long-term storage, minimizing ice crystal formation and maintaining structural integrity. The application of mannitol in bioplastics has seen growth since 2020, driven by its role in sustainable polyol production for degradable polyesters and thermoplastic starch films. As a biobased alditol, it contributes to eco-friendly alternatives in packaging and agricultural films, aligning with the expanding bio-based polyols market, valued at USD 11.6 billion in 2025 and projected to reach USD 35.1 billion by 2035.

Pharmacology

Mechanism of action

Mannitol functions primarily as an osmotic agent due to its impermeability to most cell membranes, which allows it to establish an osmotic gradient that draws water from intracellular and interstitial spaces into the extracellular fluid and vascular compartment. This property underlies its therapeutic effects across various physiological systems, as the non-reabsorbable nature of mannitol prevents equilibration across cellular barriers, promoting fluid shifts without direct interaction with cellular transport proteins. In the renal system, mannitol is freely filtered at the glomerulus but not reabsorbed in the proximal tubule, where it remains in the tubular lumen as a non-reabsorbable solute. This creates an osmotic force that retains water in the tubule, inhibiting the reabsorption of sodium and accompanying water by reducing the osmotic driving force for paracellular transport and limiting contact time between tubular fluid and epithelium. As a result, mannitol promotes diuresis by increasing urine volume and solute excretion, primarily through this osmotic mechanism in the proximal tubule and loop of Henle. Within the central nervous system, mannitol reduces intracranial pressure by elevating plasma osmolality, which reverses the osmotic gradient across the blood-brain barrier and draws water from brain parenchyma into the vasculature. This dehydration of the cerebral interstitium shrinks swollen cells and decreases overall brain volume, with the process governed by Starling forces that facilitate net fluid movement out of the tissue. The osmotic reflection coefficient of mannitol at the intact blood-brain barrier (approximately 0.9) ensures effective water extraction without significant penetration into brain cells. In the respiratory tract, particularly when administered via inhalation, mannitol exerts an osmotic effect by attracting water into the airway surface liquid layer, thereby hydrating the mucus and reducing its viscosity and elasticity. This enhanced hydration facilitates mucociliary clearance by improving ciliary beat frequency and cough efficacy, aiding the removal of retained secretions without altering ion transport directly. Mannitol also exhibits a minor antioxidant role through its capacity to scavenge reactive oxygen species (ROS), a function prominent in plants and certain microbes where it protects against oxidative stress by quenching hydroxyl radicals and stabilizing cellular structures. However, this ROS-scavenging activity is limited in human physiology, with negligible contributions to antioxidant defense compared to its primary osmotic actions. Mannitol undergoes minimal metabolism in most human cells, remaining largely unmetabolized and excreted unchanged via the kidneys, which accounts for its predictable pharmacokinetics. Its biological half-life is approximately 100 minutes, reflecting rapid renal clearance without significant hepatic processing.

Pharmacokinetics

Mannitol exhibits route-dependent absorption. Intravenous administration achieves 100% bioavailability, as it is directly introduced into the systemic circulation. Oral administration results in a systemic bioavailability of approximately 20%, with the majority acting locally in the gastrointestinal tract. Inhaled administration has an absolute systemic bioavailability of approximately 59%, though a significant portion exerts local effects in the respiratory system. Following administration, mannitol distributes primarily to the extracellular fluid, with a volume of distribution of approximately 0.2–0.4 L/kg. It does not readily cross the intact blood-brain barrier due to its osmotic properties and molecular size. Metabolism of mannitol is negligible, with less than 5% of the dose undergoing any transformation, and no involvement of hepatic enzymes, as it is largely inert in human physiology. Excretion occurs almost entirely via renal filtration, with 80–90% of the administered dose recovered unchanged in the urine within 3 hours in individuals with normal renal function. The renal clearance is approximately 100 mL/min, reflecting minimal tubular reabsorption. Serum mannitol levels require monitoring, particularly in renal impairment, to prevent accumulation, as clearance is prolonged in such cases; therapeutic levels are typically maintained below levels that risk toxicity.

Safety profile

Adverse effects

Mannitol administration, particularly via intravenous route, commonly leads to headache, nausea, and thirst due to its osmotic diuretic effects. These symptoms arise from fluid shifts and increased urinary output, often resolving with dose adjustment or hydration. Renal adverse effects are significant with overuse, including acute tubular necrosis and electrolyte imbalances such as hyponatremia and hypokalemia. Acute kidney injury occurs in approximately 6-10% of patients receiving mannitol for conditions like intracranial hypertension, primarily from osmotic nephrosis and dehydration. These imbalances stem from excessive diuresis and can exacerbate underlying renal impairment. When administered via inhalation, such as in cystic fibrosis therapy, mannitol frequently causes cough and throat irritation, affecting 5-10% of users, alongside rare instances of bronchospasm. These respiratory effects result from osmotic stimulation of airway mucosa and typically manifest shortly after dosing. Post-2020 data from long-term lung use continue to highlight these issues without emergence of novel severe effects, though monitoring for bronchoconstriction remains essential. Chronic oral intake of mannitol exceeding 20 g per day often induces osmotic diarrhea and bloating due to its poor absorption in the gut. These gastrointestinal disturbances occur as unabsorbed mannitol draws water into the intestines, with symptoms intensifying in a dose-dependent manner. Rare adverse effects include skin necrosis at injection sites from extravasation and pulmonary edema from fluid overload or hypersensitivity. These complications, though infrequent, necessitate prompt intervention to prevent tissue damage or respiratory compromise.

Contraindications

Mannitol is contraindicated in patients with known hypersensitivity to the drug, as it may lead to severe allergic reactions including anaphylaxis. Absolute contraindications also include well-established anuria due to severe renal disease, where mannitol's osmotic diuretic effects cannot promote urine output and may exacerbate renal failure. Severe pulmonary congestion or frank pulmonary edema represents another absolute contraindication, as mannitol can worsen fluid overload in the lungs. Active intracranial bleeding, except during craniotomy, is contraindicated due to the risk of expanding the hematoma through osmotic shifts. Additionally, severe dehydration precludes mannitol use, as the agent can further deplete intravascular volume and precipitate hypovolemic shock. Relative contraindications encompass conditions where mannitol should be used with extreme caution or avoided if possible. In patients with heart failure, mannitol risks exacerbating fluid overload and pulmonary edema through its osmotic effects. Renal impairment, particularly with an estimated glomerular filtration rate (GFR) below 50 mL/min, is a relative contraindication due to heightened risk of acute kidney injury from osmotic nephrosis. Drug interactions must be considered to avoid additive toxicities. Concomitant use with other diuretics can potentiate electrolyte imbalances, including hypokalemia, through enhanced renal losses of potassium. Mannitol should be avoided or closely monitored in patients with hyponatremia, as it may worsen serum sodium dilution via osmotic diuresis and fluid shifts. Regarding pregnancy, the FDA prescribing information states that there are limited data on mannitol use in pregnant women to evaluate for a drug-associated risk of major birth defects, miscarriage, or adverse maternal or fetal outcomes; mannitol has been detected in amniotic fluid following maternal administration in the third trimester. Animal reproduction studies have not been conducted. Mannitol should be used during pregnancy only if the potential benefit justifies the potential risk to the fetus. For breastfeeding, there are no data available on the presence of mannitol in human milk, the effects on the breastfed infant, or the effects on milk production. The developmental and health benefits of breastfeeding should be considered along with the mother's clinical need for mannitol and any potential adverse effects on the breastfed infant from mannitol or from the underlying maternal condition. Recent guidelines, including a 2023 review on managing increased intracranial pressure (ICP), recommend limiting mannitol to cases with confirmed ICP elevation via monitoring, avoiding empirical administration to prevent complications like rebound ICP.

History

Discovery and early research

Mannitol was first isolated in 1806 by the French chemist Joseph Louis Proust from manna, a sweet exudate derived from the flowering ash tree (Fraxinus ornus), and named accordingly due to its resemblance to the biblical substance. Proust identified it as a crystalline, sweet-tasting compound present in the manna sap, marking the initial recognition of mannitol as a distinct sugar alcohol. In the early 1880s, Croatian chemist Julije Domac advanced the understanding of mannitol's chemical structure through his doctoral research at the University of Graz, where he analyzed samples obtained from Caspian manna. Domac determined the position of the double bond in related hexene derivatives and confirmed mannitol's hexitol framework, providing one of the earliest detailed structural elucidations. Building on this, Emil Fischer's work in the 1890s further clarified mannitol's stereochemistry by oxidizing it to mannonic acid and comparing it to derivatives from mannose, establishing mannitol as the alditol corresponding to the C2 epimer of glucose-derived sorbitol. Fischer's reduction and oxidation experiments with aldohexoses, including the synthesis of mannitol from mannose, were pivotal in resolving the configurations of the hexose series. Early 20th-century research explored mannitol's physiological properties, with pre-commercial synthesis attempts focusing on chemical reductions of sugars, though yields remained low until later advancements. During World War II in the 1940s, mannitol gained attention for measuring glomerular filtration rate (GFR) in clinical settings, introduced by physiologist Homer Smith to assess renal function in injured soldiers and patients with acute kidney issues, leveraging its inertness and osmotic behavior for accurate clearance studies. By the 1950s, mannitol's role as an osmotic diuretic was recognized, with initial therapeutic applications for reducing intracranial pressure and edema, paving the way for its broader medical adoption despite early comparisons to urea.

Commercial development

Mannitol entered commercial production in the mid-20th century, initially marketed as Osmitrol by Barnes-Hind Laboratories in the 1950s for pharmaceutical applications, particularly as an osmotic diuretic to promote urine production and reduce intracranial or intraocular pressure. The U.S. Food and Drug Administration (FDA) granted approval for Osmitrol under New Drug Application (NDA) 013684 on June 8, 1964, marking the first regulatory endorsement for its intravenous use in diuresis and cerebral edema management. Industrial-scale manufacturing advanced in the 1970s through the commercialization of catalytic hydrogenation processes, including methods developed by Imperial Chemical Industries (ICI) to convert sugars derived from sucrose or starch into mannitol with improved yields and efficiency. This approach, exemplified in ICI's U.S. Patent 4,173,514 (1979) for high-mannitol-content production via epimerization, isomerization, and hydrogenation, enabled cost-effective large-volume output and supported mannitol's transition from niche medical use to broader applications. A seminal earlier patent, U.S. Patent 3,044,904 (1962, filed 1960), facilitated synthesis and chromatographic separation of mannitol from sugar mixtures, laying groundwork for these advancements. Market expansions in the late 20th century included food-grade applications, where the FDA established regulations permitting mannitol's use as a low-calorie sweetener, humectant, and anticaking agent under interim food additive status (21 CFR 180.25), with proposals for GRAS affirmation dating to 1973 but remaining under interim status and used in accordance with good manufacturing practices. In pharmaceuticals, innovations continued with the approval of an inhaled formulation, Bronchitol (dry powder mannitol), by the European Commission on April 13, 2012, as an add-on therapy to improve lung function in cystic fibrosis patients aged 10 and older. In the United States, the FDA approved Bronchitol on October 30, 2020, for use as add-on maintenance therapy to improve pulmonary function in adult patients 18 years and older with cystic fibrosis. Post-2000 biotechnological patents, such as WO 2006044608A1 (2006) for continuous fed-batch fermentative production using engineered microorganisms and U.S. Patent 8,338,147 B2 (2012) for D-mannitol via Lactobacillus fermentation, introduced sustainable alternatives to chemical synthesis, enhancing purity and reducing costs. By 2020, mannitol's global market had expanded significantly from its pharmaceutical origins to encompass food, cosmetics, and industrial sectors, achieving an estimated value of around $375–400 million, driven by demand for sugar-free products and advanced drug delivery systems.

Regulatory status

Compendial standards

Mannitol is subject to stringent compendial standards established by major pharmacopeias to ensure its quality, purity, and suitability for pharmaceutical, food, and technical applications. These standards specify tests for identity, assay, impurities, and physical characteristics, with harmonization efforts among pharmacopeias to align requirements where possible. In the United States Pharmacopeia (USP) and National Formulary (NF), the monograph for Mannitol requires not less than 97.0% and not more than 102.0% mannitol on the dried basis, determined by liquid chromatography. Limits for elemental impurities include nickel not more than 1 ppm, in line with general elemental impurity controls effective since 2018. Microbial enumeration limits include total aerobic microbial count not more than 1000 cfu/g and total combined yeasts and molds not more than 100 cfu/g. Identity is confirmed via infrared absorption. The European Pharmacopoeia (Ph. Eur.) monograph aligns closely with USP requirements, mandating 97.0% to 102.0% mannitol by liquid chromatography assay. Identity is verified using infrared spectroscopy, with additional specifications for particle size distribution in inhalation-grade mannitol to ensure aerodynamic properties. Heavy metals are limited to less than 5 ppm, and microbial limits mirror those in USP. Reducing sugars are controlled at not more than 0.1%. The Japanese Pharmacopoeia (JP) specifies optical rotation between +137° and +145° for D-Mannitol, with loss on drying not exceeding 0.30% (1 g, 105°C, 4 hours). The assay requires not less than 98.0% and not more than 102.0% mannitol, tested via liquid chromatography. Heavy metals are limited to not more than 5 ppm, and chloride content to not more than 0.007%. The Chinese Pharmacopoeia (ChP) monograph requires conformity to similar purity standards, with loss on drying less than 0.3%, ensuring compatibility with international harmonized texts. Assay is not less than 98.0% by liquid chromatography. Mannitol is available in various grades to meet specific applications: pharmaceutical grades comply with USP/NF, Ph. Eur., British Pharmacopoeia (BP), Indian Pharmacopoeia (IP), or JP monographs for use in drug formulations; food grades adhere to Food Chemicals Codex (FCC) standards, which specify 97.0% to 102.0% mannitol with limits on lead (not more than 0.5 ppm) and loss on drying (not more than 0.3%); technical grades lack pharmacopeial certification but meet basic purity thresholds (typically >98%) for industrial uses like resin production, often verified by in-house HPLC assays. In the United States, mannitol is affirmed as generally recognized as safe (GRAS) as a direct food substance (21 CFR 184.1449) and as a multiple-purpose GRAS food substance (21 CFR 182.5470). Key testing methods include high-performance liquid chromatography (HPLC) with refractive index or evaporative light-scattering detection for assay and related substances, and gas chromatography (GC) for residual solvents. Updates in the 2025 editions of USP-NF and Ph. Eur. incorporate enhanced controls for elemental impurities and potential biotech-derived contaminants in excipients, though mannitol-specific revisions focus on refining organic impurity limits via improved chromatographic methods.

Controversies and recent developments

In the 2010s, inhaled mannitol faced significant regulatory scrutiny for its proposed use in treating cystic fibrosis (CF), with debates centering on its efficacy in improving lung function and reducing exacerbations. The U.S. Food and Drug Administration's Pulmonary-Allergy Drugs Advisory Committee voted unanimously 14-0 against approval in January 2013, citing insufficient evidence from clinical trials demonstrating a clear clinical benefit beyond bronchodilator effects. This decision delayed U.S. market entry despite prior approvals in Europe and Australia, prompting additional studies that ultimately led to FDA approval of Bronchitol in October 2020 for adult CF patients. Regulatory controversies also arose in the 1990s regarding mannitol's use in sugar-free chewing gum, where its laxative effects at high intakes sparked debates over labeling requirements. The FDA amended its regulations in 1995 to allow "sugar-free" claims on gums containing polyols like mannitol, but mandated disclosures about potential laxative effects if foreseeable consumption could exceed 50 grams per day, addressing concerns over gastrointestinal disturbances such as diarrhea. Further updates in 1996 clarified GRAS status for mannitol while reinforcing warning labels for products with significant polyol content to prevent consumer health risks. Environmental concerns have highlighted the drawbacks of traditional chemical synthesis of mannitol, which involves multi-step hydrogenation processes generating substantial waste and energy consumption, contrasting with the growing push for green biotechnological alternatives. Bioproduction via microbial fermentation reduces reliance on petrochemical feedstocks and minimizes byproducts, offering a more sustainable pathway amid increasing regulatory pressure for eco-friendly manufacturing. This shift addresses the environmental footprint of chemical methods, which contribute to higher carbon emissions and wastewater issues compared to enzyme-catalyzed biotech routes. Recent advancements in 2024 have focused on biotechnological production, with engineered bacterial strains achieving mannitol titers up to 150 g/L through optimized metabolic pathways in Escherichia coli and other hosts, improving scalability and cost-effectiveness. The global mannitol market is projected to reach approximately USD 751 million by 2033, driven primarily by pharmaceutical demand for its role as an osmotic diuretic and excipient in drug formulations. Regulatory developments include ongoing EFSA re-evaluations of individual polyols under food additive frameworks, with mannitol assessments emphasizing safer handling in industrial applications under REACH. Emerging sustainable extraction methods from marine brown algae, such as Saccharina species, are gaining traction for their lower resource demands and reduced environmental impact compared to terrestrial sourcing. Ongoing research explores mannitol's potential in Alzheimer's disease through osmotic mechanisms to enhance blood-brain barrier permeability and promote amyloid clearance, with recent preclinical studies in 2024 demonstrating safe chronic induction of barrier opening in animal models. These efforts build on mannitol's established role in transient barrier disruption, paving the way for potential clinical translation in neurodegenerative therapies.