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Stem bromelain
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Looking for Stem bromelain API 37189-34-7?
- Description:
- Here you will find a list of producers, manufacturers and distributors of Stem bromelain. You can filter on certificates such as GMP, FDA, CEP, Written Confirmation and more. Send inquiries for free and get in direct contact with the supplier of your choice.
- API | Excipient name:
- Stem bromelain
- Synonyms:
- Bromelain, stem , Pineapple stem bromelain
- Cas Number:
- 37189-34-7
- DrugBank number:
- DB12249
- Unique Ingredient Identifier:
- ZLM4P8929R
General Description:
Stem bromelain, identified by CAS number 37189-34-7, is a notable compound with significant therapeutic applications. The primary therapeutic use for which stem bromelain is currently and formally indicated is as a burn wound eschar debridement agent that has been approved by the EMA since 2012 and marketed under the brand name Nexobrid . Bromelain itself belongs to a category of protein-digesting enzymes that are obtained commercially from the fruit or stem of pineapples . Although both fruit and stem bromelain are prepared differently and contain different enzymatic compositions, the general term bromelain typically refers to stem bromelain . Bromelain is consequently a composite mixture of several different endopeptidases that can facilitate many different reactions with many different substrates. This action allows bromelain to demonstrate a wide range of therapeutic benefits ranging from cardiovascular to anticancer therapy - but the specific mechanisms of action by which it can elicit these effects are currently not properly understood.
Indications:
This drug is primarily indicated for: The primary medical purpose for which stem bromelain (SB) is currently indicated for is the removal of eschar in adults with deep partial- and full-thickness thermal burns . Besides this official indication, however, it is also believed that SB may be used as a treatment for several other purposes as well, including cardiovascular health, osteoarthritis, autoimmunity, blood clotting, diarrhea, cancer, surgery, and debridement - although the specific mechanisms of action for these indications remain to be elucidated . Its use in specific medical scenarios underscores its importance in the therapeutic landscape.
Metabolism:
Stem bromelain undergoes metabolic processing primarily in: Given its protein structure, it is assumed that stem bromelain, when administered would experience hydrolysis in the gut or eventually in the bloodstream after absorption . Regardless, radiolabelled, intact stem bromelain has been found circulating in the plasma after administration . This metabolic pathway ensures efficient processing of the drug, helping to minimize potential toxicity and side effects.
Absorption:
The absorption characteristics of Stem bromelain are crucial for its therapeutic efficacy: It appears that stem bromelain can be absorbed from the human gastrointestinal tract to a small but significant extent while remaining undegraded or functionally intact . In a study involving 19 healthy men, daily oral administration of 3g/day of bromelain resulted in a mean plasma concentration of approximately 5000 pg/ml by 48 hours, although the maximum peak blood concentration of bromelain varied between 2000 to 10,000 pg/ml between subjects . The average blood concentration of bromelain in the period range of 3 to 51 hours was 10.28 ug . The drug's ability to rapidly penetrate into cells ensures quick onset of action.
Half-life:
The half-life of Stem bromelain is an important consideration for its dosing schedule: The estimated plasma half-life of stem bromelain is 6-9 hours . This determines the duration of action and helps in formulating effective dosing regimens.
Protein Binding:
Stem bromelain exhibits a strong affinity for binding with plasma proteins: It was determined that approximately 50% of bromelain is associated with plasma proteins like alpha 2-macroglobulin and alpha 1-antichymotrypsin, which are antiproteinases found in the blood . This property plays a key role in the drug's pharmacokinetics and distribution within the body.
Route of Elimination:
The elimination of Stem bromelain from the body primarily occurs through: No readily accessible data regarding the route of eliminiation of stem bromelain is available. Understanding this pathway is essential for assessing potential drug accumulation and toxicity risks.
Volume of Distribution:
Stem bromelain is distributed throughout the body with a volume of distribution of: No readily accessible data regarding the volume of distribution of stem bromelain is available. This metric indicates how extensively the drug permeates into body tissues.
Clearance:
The clearance rate of Stem bromelain is a critical factor in determining its safe and effective dosage: No readily accessible data regarding the clearance of stem bromelain is available. It reflects the efficiency with which the drug is removed from the systemic circulation.
Pharmacodynamics:
Stem bromelain exerts its therapeutic effects through: Stem bromelain is ultimately a mixture of various different thiol endopeptidases that are capable of catalyzing a range of reactions on a number of different substrates, which is perhaps why stem bromelain can evidently be used as some manner of treatment in a range of therapeutic contexts. This notion is facilitated by the fact that various topical and oral administration stem bromelain preparations exist as well, further diversifying the ways in which the medication can be used. Perhaps the most important aspect of stem bromelain, however, is its ability to undergo intestinal absorption undegraded in a functionally intact form, ultimately preserving its proteolytic actions in the plasma . This kind of pharmacodynamic characteristic is another element that perhaps allows stem bromelain to remain active within the body and elicit a number of actions at several major body systems. The drug's ability to modulate various physiological processes underscores its efficacy in treating specific conditions.
Mechanism of Action:
Stem bromelain functions by: Stem bromelain is ultimately a mixture of a number of thiol endopeptidases and other elements including phosphatases, glucosidase, peroxidases, cellulases, glycoproteins, carbohydrates, and various protease inhibitors . The many different substrates and reactions that these varied enzymes can catalyze results in a number of different and possible mechanisms of action. Stem bromelain is currently principally used as a topical agent for debridement of necrotic tissue from wounds or second to third-degree burns . As bromelain can contain escharase as one of its component enzymes, it is thought that various stem bromelain creams or gels can accelerate the healing process of wounds by facilitating the rapid removal of necrotic layers of dermis while preserving unburned/unharmed tissues and/or perhaps by accelerating the recovery of blood perfusion in wound tissue, control the expression of TNF-alpha, and raise the expression of TGT-beta, as demonstrated in the pig animal model . This kind of enzymatic debridement is ultimately preferred to surgical debridement as physical, surgical procedures are naturally painful, non-selective, and involve the possibility of repeat or excessive anesthesia and/or bleeding . With regards to cardiovascular health, certain studies suggest that stem bromelain is capable of breaking down cholesterol plaques, eliciting a strong fibrinolytic activity, and inhibiting blood platelet aggregation - all of which protect against ischemia/reperfusion injury in skeletal muscle and minimize the risk of arterial thrombosis and embolism . Additionally, stem bromelain has also been shown to attenuate allergic airway disease by altering CD4+ and CD8+ T lymphocyte populations - an action that may be beneficial in treating human asthma or hypersensitivity disorders . Finally, stem bromelain has also been used to induce cardioprotection against ischemia-reperfusion injury via the Akt/Foxo pathway in rat model myocardium . In the treatment of osteoarthritis, it is believed that stem bromelain has analgesic properties which are thought to be the result of direct influence on pain mediators such as bradykinin . In addition, various trials suggest that the medication could be useful in reducing swelling, bruising, and pain in women having surgery like episiotomy . Moreover, stem bromelain may also be used for treating acute inflammation and sports injuries . Furthermore, stem bromelain has also been studied as an adjuvant therapy for chronic inflammatory, malignant, and autoimmune diseases . Certain in vitro experiments have demonstrated that stem bromelain can modulate surface adhesion molecules on T cells, macrophages, and natural killer cells and also cause the secretion of IL-1B, IL-6, and Tumor Necrosis Factor-alpha (TNF-alpha) via peripheral blood mononuclear cells . The agent has also been able to block the Raf-1/extracellular-regulated-kinase-2 (ERK-2) pathways by preventing T cell signal transduction . In particular however, treating cells with stem bromelain decreases the activation of CD4(+) T cells and reduces the expression of CD25 . Additionally, there is also evidence to suggest that oral therapy with stem bromelain produces certain analgesic and anti-inflammatory effects in patients with rheumatoid arthritis, which is a particularly common autoimmune disease . Stem bromelain also affects blood coagulation by increasing the serum fibrinolytic ability and by preventing the synthesis of fibrin, a protein involved in blood clotting . In the rat animal model, the reduction of serum fibrinogen level seems to be dose-dependent when both prothrombin time and activated partial thromboplastin time become markedly prolonged at higher concentrations of administered stem bromelain . In vitro and in vivo studies also suggest stem bromelain can act as an effective fibrinolytic agent since it stimulates the conversion of plasminogen to plasmin, causing an increased fibrinolysis by degrading fibrin . In terms of potential antimicrobial effects of stem bromelain, there are varying observations regarding its specific mechanism of action . When counteracting the effects of some intestinal pathogens like Vibrio cholera or Escherichia coli (whose enterotoxin causes diarrhea in animals), some studies suggest that stem bromelain interacts with intestinal secretory signaling pathways like adenosine 3':5'-cyclic monophosphatase, guanosine 3':5'-cyclic monophosphatase, and/or calcium-dependent signaling cascades . Conversely, other studies propose that stem bromelain supplementation can lead to antiadhesion effects which prevent E. coli bacteria from attaching to particular glycoprotein receptors on the intestinal mucosa by proteolytically modifying those receptor attachment sites . Additionally, various studies have shown that stem bromelain also possesses anticancer activity. In particular, the agent has been found to increase the expression of p53 and Bax in mouse skin, both of which are well-known apoptosis activators . Stem bromelain can also evidently decrease the activity of cell survival regulators like Akt and Erk, therefore inducing apoptotic tumor cell death . Finally, stem bromelain has also been observed to downregulate NF-kB and Cox-2 expression in mouse papillomas and in models of skin tumorigenesis . It has also demonstrated the capability to inhibit bacterial endotoxin (LPS)-induced NF-kB activity as well as the expression of PGE2 and Cox-2 in human monocytic leukemia and murine microglial cell lines . This mechanism highlights the drug's role in inhibiting or promoting specific biological pathways, contributing to its therapeutic effects.
Toxicity:
Classification:
Stem bromelain belongs to the None, classified under the direct parent group Peptides. This compound is a part of the Organic Compounds, falling under the Organic Acids superclass, and categorized within the Carboxylic Acids and Derivatives class, specifically within the Amino Acids, Peptides, and Analogues subclass.
Categories:
Stem bromelain is categorized under the following therapeutic classes: Cysteine Endopeptidases, Cysteine Proteases, Endopeptidases, Enzymes, Enzymes and Coenzymes, Hydrolases, Peptide Hydrolases. These classifications highlight the drug's diverse therapeutic applications and its importance in treating various conditions.
Stem bromelain is a type of Enzyme Replacements/modifiers
Enzyme replacements/modifiers are a crucial category of pharmaceutical active pharmaceutical ingredients (APIs) utilized in the treatment of various enzyme-related disorders. Enzymes play a vital role in the normal functioning of the body by catalyzing specific biochemical reactions. However, in certain medical conditions, the body may lack or produce dysfunctional enzymes, leading to serious health complications.
Enzyme replacement therapy (ERT) involves administering exogenous enzymes to compensate for the enzyme deficiency in patients. These enzymes are typically derived from natural sources or produced using recombinant DNA technology. By introducing these enzymes into the body, they can effectively substitute the missing or defective enzymes, thereby restoring normal metabolic processes.
On the other hand, enzyme modifiers are API substances that regulate the activity of specific enzymes within the body. These modifiers can either enhance or inhibit the enzyme's function, depending on the therapeutic objective. By modulating enzyme activity, these APIs can restore the balance of enzymatic reactions, leading to improved physiological outcomes.
Enzyme replacements/modifiers have shown remarkable success in treating various genetic disorders, such as Gaucher disease, Fabry disease, and lysosomal storage disorders. Additionally, they have demonstrated potential in managing enzyme deficiencies associated with rare diseases and certain types of cancer.
The development and production of enzyme replacements/modifiers involve rigorous research, formulation optimization, and adherence to stringent quality control measures. Pharmaceutical companies invest substantial resources in developing these APIs to ensure their safety, efficacy, and compliance with regulatory standards.
Overall, enzyme replacements/modifiers represent a vital therapeutic category in modern medicine, offering hope and improved quality of life for patients with enzyme-related disorders.