Bioactives of Momordica charantia as Potential Anti-Diabetic/Hypoglycemic Agents

Momordica charantia L., a member of the Curcubitaceae family, has traditionally been used as herbal medicine and as a vegetable. Functional ingredients of M. charantia play important roles in body health and human nutrition, which can be used directly or indirectly in treating or preventing hyperglycemia-related chronic diseases in humans. The hypoglycemic effects of M. charantia have been known for years. In this paper, the research progress of M. charantia phytobioactives and their hypoglycemic effects and related mechanisms, especially relating to diabetes mellitus, has been reviewed. Moreover, the clinical application of M. charantia in treating diabetes mellitus is also discussed, hoping to broaden the application of M. charantia as functional food.


Introduction
Due to globalization, industrialization and changes of human environment, hyperglycemia is widely prevalent [1]. Diabetes mellitus has been estimated to be the fifth leading cause of death globally, characterized by hyperglycemia due to defects in insulin action, insulin secretion, or both [2,3]. Characterized by altered carbohydrate, lipid and protein metabolism, diabetes mellitus is the leading cause of renal, neurological, and gastrointestinal manifestations in developed and developing countries [4][5][6][7]. Type 1 diabetes mellitus (T1DM), chiefly genetic, is characterized by disruption of pancreas function and absolute insulin insufficiency [8]. Insulin resistance plays a critical role in the development of type 2 diabetes mellitus (T2DM) and related complications [9]. T2DM is the major type of diabetes mellitus, affecting 90% of overall diabetes patients. Therefore, optimizing diabetes mellitus therapy is a modern critical medical and social challenge [8]. In particular, effective control of postprandial blood glucose levels may play key roles in diabetes care [10].
Many pharmacological approaches have been used to improve hyperglycemia, mainly through stimulating insulin release, increasing glucose transport activity, inhibiting gluconeogenesis, and reducing absorption of glucose from the intestine [10]. Currently, available therapies may be used as monotherapy or in combination to provide better glycemic regulation [11]. In addition to dietary management, hypoglycemic drugs are often used to treat T2DM [8]. However, the available hypoglycemic reagents have inadequate efficacy and some serious mechanism-based side effects, including hypoglycemia, gastrointestinal stimulation, and edema [12,13]. Owing to thesevere side-effects of synthetic hypoglycemic drugs, more effective and safer hypoglycemic agents from natural sources are greatly needed [14][15][16][17][18].

Antidiabetic Activity of M. charantia
M. charantia could effectively combat diabetes mellitus (Table 1). In obese diabetic db/db mice, M. charantia fruit water extract alone or together with platycodin-D significantly decreased obesity-related changes, and the water extract:platycodin-D (1:4) showed the most dramatic and synergic obesity-inhibiting effects [35]. In alloxan diabetic albino rats, acetone extract of whole M. charantia fruit lowered blood glucose from 13 to 50% after 8-30 days treatment [36]. Administration of M. charantia fruit methanol extract for 28 days lowered blood glucose levels in a dose-dependent manner in both normal and diabetic animals [37]. In the normal glucose primed rat model, alcoholic extract of M. charantia fruit significantly depressed plasma glucose levels by 10-15% at 1 h [38]. In both normal and streptozotocin-induced diabetic rats, subcutaneous administration of protein extract of M. charantia fruit pulp significantly decreased plasma glucose concentrations in a dosedependent manner [39].
In normal rats, M. charantia pulp juice (250 mg/2 mL water) lowered fasting blood glucose levels significantly (p < 0.05 at 120 min), and the effect was even more pronounced with saponin-free methanol extract (150 mg/2 mL water) [40]. In diet-induced obesity C57BL/6 mice (male, 8 wk old), freeze-dried M. charantia fruit powder was seen to significantly reduce body weight, as the final body weights of mice receiving 10% M. charantia powder were almost the same as the control mice [41]. In normoglycemic Sprague-Dawley rats, aqueous extracts of M. charantia fruit (100 mg/kg) greatly reduced blood glucose levels [42].
In patients with T2DM, M. charantia extracts of unripe fruit could effectively lower the average fasting glucose level in an age-and sex-independent manner, showing no serious adverse events [43]. In a study of 52 individuals with prediabetes, M. charantia fruit extracts lowered elevated fasting plasma glucose [44]. Moreover, M. charantia fruit pulps at 2000 mg/day showed a modest hypoglycemic effect in patients with T2DM, and fructosamine levels were significantly reduced [45]. Among 112 patients with T2DM, administration of M. charantia fruit powder (2 or 4 g/day) significantly improved blood lipids, atherogenic index, body weight, and systolic blood pressure [46].

Improving Insulin Secretory and Resistance
M. charantia fruit extract could significantly increase islet size, number of β-cells, and total β-cell area, and also induce the regeneration of β-cells in the pancreatic islets of diabetic rats [47]. Furthermore, M. charantia fruit juice significantly increased the number of pancreatic β cells through reviving β cells and recovering partially destroyed β cells in streptozocin (STZ)-induced diabetic rats, but showed no effect on pancreatic α and δ cells [48]. In alloxan diabetic albino rats, acetone extract of M. charantia fruit showed antihyperglycemic activities through stimulating the recovery of pancreatic islet β cells [36]. Saponin-free methanol extract of M. charantia pulp juice (150 mg/2 mL water) showed significant hypoglycemic effects both in fasting (p < 0.05 at 120 min) and in postprandial states in non-insulin-dependent diabetes mellitus (NIDDM) model rats, through improving the insulin secretory capacity of B cells and enhancing insulin action, indicating the presence of non-sapogenin hypoglycemic compound(s) in M. charantia fruit pulp [40].
In MIN6 β-cells, M. charantia extracts rich in saponin significantly stimulated insulin secretion [29]. In particular, momordicine II and kuguaglycoside G also stimulated insulin secretion at concentrations of 10 µg/mL and 25 µg/mL, respectively [29]. The dried powder of M. charantia fruit pulp could also increase insulin secretion [49]. In INS-1 cells and rat pancreatic islets, M. charantia green fruit methanol extract and its ethyl acetate fraction could increase ATP content, augment insulin secretion in a dose-dependent manner, increase serum insulin levels after glucose loading, and decrease blood glucose levels significantly [50]. In MIN6 β-cells, purified momordicoside U (15.8-197.2 µM) moderately enhanced insulin secretion [30]. In both normal and streptozotocin-induced diabetic rats, protein extract of M. charantia fruit pulp raised plasma insulin concentrations 2-fold at 4 h following subcutaneous administration [39]. The protein extract of M. charantia fruit pulp (10 µg/mL) increased insulin secretion in perfused rat pancreases, and exerted insulin secretagogue and insulinomimetic activities to lower blood glucose concentrations [39]. In male high-fat-fed (HFD) Wistar rats, M. charantia fruit extract notably improved insulin sensitivity, and reduced fasting insulin [51].
The mcIRBP exhibited hypoglycemic effects in mice through interaction with insulin receptors (IR) [27]. In particular, the mcIRBP-19 (spanning residues 50-68 of mcIRBP) could enhance the binding of insulin to IR, stimulate phosphorylation of PDK1 and Akt, as well as stimulate the uptake of glucose in cells and clearance of glucose in diabetic mice ( Figure 3) [52]. M. charantia fruit extract supplementation together with a high-fat diet (HFD) improved the insulin-stimulated tyrosine phosphorylation of insulin receptor subtrate-1 (IRS-1) [51]. In rats fed high fat diets, M. charantia freeze-dried unripe fruit juice (0.75%) could improve insulin resistance, as well as lower serum insulin and leptin [53]. mcIRBP phosphorylation of PDK1 and Akt, stimulate the uptake of glucose and clearance of glucose, [27] freeze-dried unripe fruit juice 0.75% rats fed high fat diets improve insulin resistance, lower serum insulin and leptin, improve oral glucose tolerance, lower body weight and visceral fat mass, raise serum-free fatty acid concentration, reduce adiposity, [53] momordicosides (Q, R, S, and T) and karaviloside XI _ L6 myotubes, 3T3-L1 adipocytes, mice enhance AMPK activity, stimulate GLUT4 translocation to the cell membrane, enhance fatty acid oxidation and glucose disposal [32] nanoparticles synthesized with filtrate of methanolic extract and silver nitrate 50 mg/kg STZ-induced diabetic rats regulate signaling pathways, up-regulate expression level of glucokinase [60] [35] acetone extract of whole fruit 25-75 mg/100 g body weight alloxan diabetic albino rats, lower blood glucose, stimulate the recovery of pancreatic islet β cells [36] methanol extract of fruit 200-600 mg/kg normal and diabetic animals lower blood glucose level, [37] alcoholic extract of fruit 500 mg/kg normal glucose primed rat depress plasma glucose levels, enhance glycogen synthesis in liver [38] protein extract of fruit pulp 5-10 mg/kg normal and STZ-induced diabetic rats exert insulin secretagogue and insulinomimetic activities, decrease plasma glucose concentrations, raise plasma insulin concentrations [39] fruit mcIRBP induce expression of GLUT4, stimulate phosphorylation of PDK1 and Akt, stimulate the uptake of glucose and clearance of glucose, [27] freeze-dried unripe fruit juice 0.75% rats fed high fat diets improve insulin resistance, lower serum insulin and leptin, improve oral glucose tolerance, lower body weight and visceral fat mass, raise serum-free fatty acid concentration, reduce adiposity, [53] momordicosides (Q, R, S, and T) and karaviloside XI _ L6 myotubes, 3T3-L1 adipocytes, mice enhance AMPK activity, stimulate GLUT4 translocation to the cell membrane, enhance fatty acid oxidation and glucose disposal [32] nanoparticles synthesized with filtrate of methanolic extract and silver nitrate 50 mg/kg STZ-induced diabetic rats regulate signaling pathways, up-regulate expression level of glucokinase [60] Molecules 2022, 27, 2175 8 of 17

Regulating Glucose Uptake
Glucose transporters (GLUT) are widely distributed in body cells, facilitating the maintenance of the blood glucose level in the human body [61,62]. Sodium-coupled glucose transporters (SGLUTs) are scattered across the human body, and the selective inhibition of SGLUT1 could significantly slow postprandial gut uptake of glucose, as well as increase plasma levels of GLP-1 and GIP in healthy volunteers [63,64]. GLUT2 plays bidirectional roles in specific transportation of glucose in hepatocytes, as well as the absorption and reabsorption of glucose from enterocytes and renal tubules particularly [65]. Therefore, GLUT2 is considered as a competent target in treating diabetes mellitus [66]. The potential target proteins in diabetes contain dipeptidyl peptidase-IV (DPP-IV), GLUT, SGLTs, peroxisome proliferator-activated receptors, and α-glucosidase inhibitors [67]. The mcIRBP-19 could induce expression of GLUT4 (Figure 3) [52].

Regulating Glucose Uptake
Glucose transporters (GLUT) are widely distributed in body cells, facilitating the maintenance of the blood glucose level in the human body [61,62]. Sodium-coupled glucose transporters (SGLUTs) are scattered across the human body, and the selective inhibition of SGLUT1 could significantly slow postprandial gut uptake of glucose, as well as increase plasma levels of GLP-1 and GIP in healthy volunteers [63,64]. GLUT2 plays bidirectional roles in specific transportation of glucose in hepatocytes, as well as the absorption and reabsorption of glucose from enterocytes and renal tubules particularly [65]. Therefore, GLUT2 is considered as a competent target in treating diabetes mellitus [66]. The potential target proteins in diabetes contain dipeptidyl peptidase-IV (DPP-IV), GLUT, SGLTs, peroxisome proliferator-activated receptors, and α-glucosidase inhibitors [67]. The mcIRBP-19 could induce expression of GLUT4 (Figure 3) [52].

Improving Glucose Metabolism
Diabetes mellitus is associated with irregular glucose homeostasis, so the effective control of blood glucose level is critical in preventing or reversing diabetic complications and improving life quality in diabetic patients [68]. In male HFD Wistar rats, M. charantia

Improving Glucose Metabolism
Diabetes mellitus is associated with irregular glucose homeostasis, so the effective control of blood glucose level is critical in preventing or reversing diabetic complications and improving life quality in diabetic patients [68]. In male HFD Wistar rats, M. charantia fruit extract notably improved glucose tolerance [51]. In STZ-induced diabetic rats, alcoholic extract of M. charantia fruit improved the oral glucose tolerance, and led to significant reduction in plasma glucose of 26% at 3.5 h [38]. In rats fed high-fat diets, M. charantia freeze-dried unripe fruit juice (0.75%) could improve oral glucose tolerance [53]. The hypoglycemic activities of M. charantia fruit extracts might partly be due to increased glucose utilization in the liver [38]. M. charantia leaf nanoparticles, synthesized with filtrate from methanolic extract with silver nitrate (1 mM), could significantly up-regulate the expression level of glucokinase in diabetic rats [60]. Momordicilin exhibited antidiabetic activities through blocking the active site of glycogen synthase kinase-3 (GSK-3), which can phosphorylate and inactivate glycogen synthase [7]. In normally fed rats, alcoholic extract of M. charantia fruit (500 mg/kg) enhanced glycogen synthesis (4-5 fold) from U-14 C-glucose in the liver [38].

Modulating Lipid and Amino Acid Metabolism
In male HFD Wistar rats, M. charantia fruit extract notably reduced triacylglycerol, cholesterol and epidydimal fat [51]. Momordicoside(s) could enhance fatty acid oxidation and glucose disposal in both insulin-sensitive and insulin-resistant mice [32]. In STZinduced diabetic rats, M. charantia fruit powder (10 or 50 g/kg diet for 6 weeks) could improve body mass gain and low-density lipoprotein (LDL) cholesterol values, which could be dampened by co-administered trivalent chromium (Cr) [56]. In rats fed high-fat diets, M. charantia freeze-dried unripe fruit juice (0.75%) could lower body weight and visceral fat mass, raise serum free fatty acid concentration, and reduce adiposity without affecting fat absorption [53].
Microbes inhabiting the gut may play important roles in hosts' metabolism homeostasis and health maintenance [69][70][71]. Oral administration of M. charantia fruit significantly prevented hyperlipidemia, but the effects substantially diminished when co-treated with antibiotics [57]. In particular, M. charantia fruit moderately increased diversity and shifted the overall structure of gut microbiota via enhancing the relative abundance of short-chain fatty acid (SCFAs)-producing genera and increasing fecal SCFAs content [57]. The transplantation of gut flora from M. charantia fruit-treated donor mice significantly decreased serum lipids in male recipient mice [57]. In L6 rat myotubes, M. charantia fruit juice (1, 5 and 10 µg/mL) enhanced the N-methyl-amino-α-isobutyric acid uptakes in a time-dependent manner, as M. charantia fruit juice exerted a hypoglycemic effect partly through stimulating amino acid uptake into skeletal muscle cells like insulin [55].

Protective Effects of M. charantia
In STZ-induced diabetic rats, M. charantia fruit juice normalized the structural abnormalities of peripheral nerves, including the mean cross-sectional myelinated nerve fibers, axonal area, myelin area, and maximal fiber area [54]. In Cr-co-supplemented type 2 diabetic rats, M. charantia fruit powder could decrease Cr content in liver and kidneys through binding of Cr by polyphenol-type compounds [55,56]. In STZ-induced diabetic rats, M. charantia leaf nanoparticles (50 mg/kg) could alleviate diabetes nephropathy through regulating SOCS/JAK/STAT and PI3K/Akt/PTEN signaling pathways: levels of Akt, PI3k, TGF-β, JAK2, STAT3 were down-regulated; the expressions of PTEN, SOCS3 and SOCS4 were up-regulated [60]. In type 2 diabetic db/db mice, the gastro-resistant peptide mcIRBP-9 showed anti-inflammatory and reno-protective abilities, as well as controlling blood glucose and HbA1c levels [72]. The mcIRBP-9 could ameliorate diabetic nephropathy through reducing renal vascular leakage and histopathological changes, altering pathways involved in inflammatory and immune responses, as well as improving inflammatory characteristics of mice [72]. In particular, nuclear factor-κB (NF-κB) played an important role in regulating mcIRBP-9-affected immune pathways [72]. In obese and diabetic OLETF rats, treatment with M. charantia edible portion (3%) down-regulated the levels of proinflammatory cytokines in liver, muscle and epididymal fats [73]. Administration of dried powder of M. charantia fruit pulp (2000 mg/day) significantly reduced the levels of glycated hemoglobin A1c, 2-h glucose, areas under the curve (AUC) of glucose, weight, fat percentage, body mass index, and waist circumference [49]. In 112 patients with T2DM, M. charantia fruit powder ameliorated diabetes-associated cardiovascular risk factors more effectively than glibenclamide [46]. In 40 diabetic patients (over 18 years old), M. charantia administration (two capsules, three times a day after meals, for 3 months) slightly decreased levels of glycosylated hemoglobin (hemoglobin A1c or HbA1c) by 0.22% [59]. M. charantia active components could reduce oxidative stress, decrease insulin resistance, increase insulin release, reduce adiposity, modulate glycolysis and gluconeogenesis, as well as lower oxidative status [74].
Diabetic patients often suffer from chronic nonhealing wounds, such as foot ulcers, which often result in amputations [75][76][77]. In diabetic patients, hyperglycemia can cause arteries to narrow, result in poor oxygenation of wound tissue, and delay wound repair and regeneration [58,78]. Moreover, the wound-healing response can be further compromised by chronic hyperglycemia-induced damage to both the peripheral nerves and the immune system [58,79]. Diabetes also has deleterious effects on granulation tissue cells, especially fibroblasts and endothelial cells [80]. In male Sprague-Dawley rats with diabetes, M. charantia fruit appeared to benefit the formation of wound granulation tissue, as distinct cellular layers were well-formed [75]. Moreover, M. charantia fruit treatment increased angiogenesis in diabetic granulation tissue, which was marked by abundant microvessels and large blood vessels [58]. In particular, locally applied M. charantia fruit extract could prevent regression of granulation tissue and blood vessels, and improve wound healing in diabetic wounds, showing no effect on systemic blood glucose levels or insulin receptor substrate 1 [58].

Inhibitory Effects of Related Enzymes
The α-glucosidase, located in the brush-border membranes of human intestinal cells, is involved in carbohydrate metabolism and the post-translational processing of glycoproptein [81]. The α-amylase, an important secretory product generated by the pancreas and salivary glands, can catalyze the initial step of starch hydrolysis to a mixture of oligosaccharides through cleavaging the α-D (1-4) glycosidic bonds [82,83]. In particular, α-glucosidase and α-amylase have long been proposed as candidate drug targets for the modulation of postprandial hyperglycemia [84].

Regulation of Signal Pathways
AMPK plays multiple critical roles in the body's overall metabolic balance, response to exercise, hormonal stimulation, nutritional stress, as well as glucose-lowering drugs metformin and rosiglitazone [10,86]. AMPK consists of a catalytic α subunit and two noncatalytic subunits (β and γ), forming active 1:1:1 heterotrimers. Moreover, the activation of AMPK can induce the expression of PPARα and carnitine palmitoyltransferase I (CPT-1), which further increase fatty acid oxidation and improve insulin sensitivity [87]. In L6 myotubes and LKB1-deficient HeLa cells, M. charantia triterpenoids increased AMPK activity by 20-35% through regulating the upstream kinase CaMKKβ in a Ca 2+ -independent manner [31]. As an AMPK activator, M. charantia triterpenoids could increase the expression of AMPK, and further control the balance of blood glucose ( Figure 5).

Regulation of Signal Pathways
AMPK plays multiple critical roles in the body's overall metabolic balance, response to exercise, hormonal stimulation, nutritional stress, as well as glucose-lowering drugs metformin and rosiglitazone [10,86]. AMPK consists of a catalytic α subunit and two noncatalytic subunits (β and γ), forming active 1:1:1 heterotrimers. Moreover, the activation of AMPK can induce the expression of PPARα and carnitine palmitoyltransferase I (CPT-1), which further increase fatty acid oxidation and improve insulin sensitivity [87]. In L6 myotubes and LKB1-deficient HeLa cells, M. charantia triterpenoids increased AMPK activity by 20-35% through regulating the upstream kinase CaMKKβ in a Ca 2+ -independent manner [31]. As an AMPK activator, M. charantia triterpenoids could increase the expression of AMPK, and further control the balance of blood glucose ( Figure 5).
PPARs could be activated by a ligand, heterodimerize with retinoid X receptor, binding to a peroxisome proliferator responsive element (PPRE), and promote transcription of target genes participating in lipid catabolism. Therefore, PPARs play important roles in regulating lipid and glucose homeostasis through genomic action [88]. The 9c,11t,13t-CLN, isolated from wild M. charantia fruit, could significantly induce ACO activity in a peroxisome proliferator-responsive murine hepatoma cell line (H4IIEC3) [28]. As a PPARα activator, 9c,11t,13t-CLN regulated lipid and glucose homeostasis through PPARα signaling pathways in vivo [28]. In obese and diabetic OLETF rats, treatment with M. charantia edible portion (3%) significantly improved glucose tolerance and insulin sensitivity via inhibiting NF-κB and JNK pathways: the levels of phospho-insulin receptor PPARs could be activated by a ligand, heterodimerize with retinoid X receptor, binding to a peroxisome proliferator responsive element (PPRE), and promote transcription of target genes participating in lipid catabolism. Therefore, PPARs play important roles in regulating lipid and glucose homeostasis through genomic action [88]. The 9c,11t,13t-CLN, isolated from wild M. charantia fruit, could significantly induce ACO activity in a peroxisome proliferator-responsive murine hepatoma cell line (H4IIEC3) [28]. As a PPARα activator, 9c,11t,13t-CLN regulated lipid and glucose homeostasis through PPARα signaling pathways in vivo [28]. In obese and diabetic OLETF rats, treatment with M. charantia edible portion (3%) significantly improved glucose tolerance and insulin sensitivity via inhibiting NF-κB and JNK pathways: the levels of phospho-insulin receptor substrate-1 (Tyr612) and phospho-Akt (Ser473) were increased; the activation of NF-κB in liver and muscle was decreased [73].

Challenges and Perspectives
M. charantia has received considerable attention in biological and biomedical research due to its remarkable biological activities, especially its antidiabetic/hypoglycemic effects. M. charantia is usually served in one of four dosage forms (fruit juice, entire fruit, freeze-dried powder, or capsule), the preparations are mainly crude extracts (extracted with water, ethanol, or methanol) and the effective monomer components are extracted from fruit, seeds, and leaves [89]. In particular, the typical hypoglycemic activities are mainly attributed to proteins/peptides, polysaccharides, phenolic compounds, triterpenoids, alkaloids, and charantins [90,91]. As one of the most important global health problems, diabetes mellitus could be treated with several M. charantia-derived bioactive compounds, mainly through inhibiting α-glucosidase and α-amylase, activating AMPK, JNK, and Akt signal pathways, activating PTP1B activities, and inhibiting the formation of advanced glycation end-products (AGE). The modulation of gut microbiota is essential for the hypoglycemic and anti-hyperlipidemic activities of M. charantia. M. charantia fruit juice has multiple influences on glucose and lipid metabolism, strongly counteracting the untoward effects of high-fat diets. Furthermore, antioxidant and anti-inflammatory activities also greatly contribute to its anti-hyperglycemic properties. Long-term oral administration of M. charantia fruit extracts at appropriate dosages may be benefit in improving diabetes. Identification of potential mechanism(s) by which M. charantia improves insulin sensitivity and insulin signaling may supply new therapeutic targets for the treatment of obesity/dyslipidemia-induced insulin resistance.
Traditional M. charantia remedies have supplied sources of useful hypoglycemic agents, but should continue to be investigated for possible drug alternatives. In vitro and animal studies have suggested the remarkable hypoglycemic activity of M. charantia, but limited human research is available to support its usage. M. charantia has traditionally been used for treating diabetes, but some clinical trials show conflicting results. In addition, very limited-quality evidence has shown that M. charantia adjunct preparations could improve glycemic control in T2DM patients [92]. Moreover, no large clinical trial has been performed on the efficacy and safety of M. charantia preparation. Therefore, rigorous research focusing on standardizing M. charantia formulation is greatly needed, as well as clinical trials with adequate sample size to determine its efficacy and safety. Diabetes mellitus is also associated with an increase in sialic acid concentration, but ingestion of M. charantia fruit juice (55 mL/24 h) showed no effect on levels of serum sialic acid in NIDDM patients [93][94][95]. Moreover, diabetes mellitus is also associated with disruption of biorhythms, but no related research was available for active components of M. charantia [8]. Dysfunction of bone marrow-derived endothelial progenitor cells contributes to poor vasculogenesis in diabetes mellitus [96]. However, the effect of M. charnatia active components on bone marrowderived endothelial progenitor cells is not well understood and needs to be studied in more depth. Moreover, the effect of M. charantia active components on protein kinase C is not well understood, and is vital when considering diabetic vascular complications [97].
Due to the interaction of drugs with in vivo systems, rational drug use should consider medical, biological, and pharmaceutical factors to ensure high bioavailability and efficacy. In particular, the most active candidates against diabetes mellitus will be determined through measuring many biochemical parameters, including fasting blood glucose, lipid profile, insulin, glycosylated hemoglobin, serum urea and creatinine, plasma alanine and aspartate transaminases, as well as microscopical examinations of pancreatic sections. Moreover, the gastrointestinal resistance of M. charantia bioactive compounds and their thermal tolerance in vivo also need to be better understood. Therefore, further study is greatly needed to investigate the detailed hypoglycemic mechanism and possible linkage to unexpected side effects, aiming to establish a safety guideline for the consumption of M. charantia-derived products.