Improving Dissolution Rate of Piperine by Multicomponent Crystal Formation with Saccharin

Zaini, Erizal; Riska, Delfi; Oktavia, Maria Dona; Ismed, Friardi; Fitriani, Lili

doi:10.5958/0974-360x.2020.00347.9

Cited by 13 publications

(22 citation statements)

References 10 publications

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“…The most commonly used technique for preparing phytochemical MCCs using the solution-based method is solvent evaporation (Katherine et al, 2018;Setyawan et al, 2018;Zaini et al, 2020b), in which the API and coformer are dissolved with a suitable solvent and the solvent is then allowed to evaporate slowly at room temperature (Kumar, 2018) . The second technique is spray drying, which is carried out by spraying a dissolved mixture of an API and a coformer into a hot stream; the solvent thus evaporates and MCCs form.…”

Section: Solution-based MCC Preparation Methodsmentioning

confidence: 99%

Crystal Engineering Approach in Physicochemical Properties Modifications of Phytochemical

Lutfiyah

Fitriani

Taher

et al. 2022

Sci. Technol. Indones

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Phytochemicals have been used to reduce the risk of diseases and maintain good health and well-being. However, most phytochemicals have a limitation in their physicochemical properties, which can be modified by reforming the shape of the crystals. Therefore, crystal engineering is a promising approach to optimize physicochemical characteristics of the active pharmaceutical ingredients (APIs) in a phytochemical without altering its pharmacological efficacy. Hence, this paper reviews current strategies for the use of crystal engineering to optimize physicochemical properties of phytochemicals, which is followed by the design of the synthesis and characterization of particular phytochemicals, including piperine (PIP), quercetin (QUE), curcumin (CUR), genistein (GEN), and myricetin (MYR). The literature indicates that crystal engineering of multicomponent crystals (MCCs) enhances phytochemical physicochemical properties, including solubility, dissolution rate, stability, and permeability. The MCCs provide a lower lattice energy and noncovalent bonding, which translate into lower melting points and weak intermolecular interactions that generate greater solubility, higher dissolution rate, and better stability of the APIs. Nevertheless, the absence of reported studies of phytochemical crystal engineering leads to a lack of variation in the selection of coformers, methods of preparation, and improvement of physicochemical properties. Therefore, more extensive evaluation of the design and physicochemical characteristics of phytochemicals using MCCs is necessary and manifests the opportunity to enhance the application of phytochemicals in the pharmaceutical industry.

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Section: Solution-based MCC Preparation Methodsmentioning

confidence: 99%

Crystal Engineering Approach in Physicochemical Properties Modifications of Phytochemical

Lutfiyah

Fitriani

Taher

et al. 2022

Sci. Technol. Indones

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“…In another study, piperine cocrystal formation with succinic acid as coformer has been reported, with solubility and dissolution four and two times higher than that of intact piperine, respectively [17]. In general, improved solubility in salt and/or cocrystal were due to decreased crystallinity and intramolecular interactions in the crystal lattice, resulting in a decrease in crystal lattice energy and its enthalpy [14,17]. Particularly in the formation of piperine-succinic acid cocrystal, a channel motive structure is thought to be the main mechanism underlying the increase in piperine's solubility and dissolution [17].…”

Section: Derivatives and Analogue Synthesismentioning

confidence: 96%

“…Thermodynamic studies showed that the formed polymorph is a monotropic metastable crystalline form, which accounted for its increased solubility. Salt formation of piperine with saccharin has been reported, resulting in dissolution rate improvement [14]. The difference between pKa value of piperine (weak base pKa = 13.2) and saccharin (weak acid pKa = 1.6) allows the formation of salttype multicomponent crystals [15,16].…”

Section: Derivatives and Analogue Synthesismentioning

confidence: 99%

Recent Strategies for Improving Solubility and Oral Bioavailability of Piperine

2021

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Piperine, the main bioactive compound found in black pepper (Piper nigrum L.), has long been used in Ayurveda and traditional Chinese medicine (TCM). This compound has remarkable potential pharmacological properties, including being anti-inflammatory, antimicrobial, anticancer, anticonvulsant, antidepressant, neuroprotective, and hepatoprotective. Recent studies have reported piperine activity as an antiviral against SARS-CoV-2, which caused COVID-19. Nevertheless, the clinical use of piperine is still limited, due to its poor water solubility and bioavailability; therefore, various approaches have been developed in order to solve these limitations. This review summarises recent studies (i.e. uploaded to electronic databases in the last 10 y) regarding strategies that have been investigated to improve piperine’s solubility and pharmacokinetic properties, using ‘piperine’, ‘solubility’, ‘bioavailability’, and ‘formulation’ as keywords. Articles that have focused on piperine as the main compound were selected and sorted based on their modification and formulation types. Studies reported various approaches: from derivatives and analogue synthesis, crystal engineering, complexation, particle size reduction (micro-and nanonisation), and lipid-and polymer-based drug delivery systems, to inorganic and hybrid nanoparticles. This review also highlights limitations and challenges for these approaches and encourages further studies to optimise piperine’s potential benefits.

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“…[16] Some efforts to increase the solubility and dissolution rate of piperine have been carried out, including the formation of a solid dispersion system, [17] inclusion complex formations, [18] nanosuspensions, [19] and the formation of multicomponent crystals with succinic acid, nicotinic acid, and saccharin. [20][21][22] One of the recent strategies for modifying the physicochemical properties of active pharmaceutical ingredients is the development of combined crystal engineering and nanotechnology techniques. Nano-cocrystal technology has emerged as an attractive strategy to further enhance the solubility and dissolution rate of poorly soluble drugs by reducing the crystal size to nanometer proportions (i. e., < 1000 nm).…”

Section: Introductionmentioning

confidence: 99%

“…To deal with problems related to the solubility and dissolution rate of active pharmaceutical ingredients, several methods have been developed to modify these active drug compounds, both physically and chemically [16] . Some efforts to increase the solubility and dissolution rate of piperine have been carried out, including the formation of a solid dispersion system, [17] inclusion complex formations, [18] nanosuspensions, [19] and the formation of multicomponent crystals with succinic acid, nicotinic acid, and saccharin [20–22] …”

Section: Introductionmentioning

confidence: 99%

Nano‐Cocrystals of Piperine‐Succinic Acid: Physicochemical Characterization and Dissolution Rate Studies

et al. 2022

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The aim of this study was to prepare and characterize piperinesuccinic acid nano-cocrystals in order to increase the solubility and dissolution rate of piperine. Nano-cocrystals were prepared using a wet-milling technique. Solid state characterization of the nano-cocrystals was performed by particle size analysis (PSA), powder X-ray diffraction (PXRD), differential scanning calorimetry (DSC), FT-IR spectroscopy, and scanning electron microscopy (SEM). Solubility and dissolution rate study were carried out in CO 2 -free distilled water medium. The PSA of the nano-cocrystal samples showed the mean of particle size was 344.4 � 26.25 nm, with a zeta potential value of À 2.2 mV. A decrease in the intensity of the diffraction peaks by PXRD analysis, as well as endothermic peaks and the fusion enthalpy value of piperine by DSC analysis were observed in the nanococrystals. Solubility tests with the nano-cocrystals showed an increase in solubility of 12.701-fold compared to that of intact piperine. The percentage of dissolved piperine in the nanococrystals after 60 minutes was 53.281 %. It can be concluded that the formation of piperine-succinic acid as a nano-cocrystal using a wet-milling technique resulted in an increase in both the solubility and dissolution rate of piperine.

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Improving Dissolution Rate of Piperine by Multicomponent Crystal Formation with Saccharin

Cited by 13 publications

References 10 publications

Crystal Engineering Approach in Physicochemical Properties Modifications of Phytochemical

Crystal Engineering Approach in Physicochemical Properties Modifications of Phytochemical

Recent Strategies for Improving Solubility and Oral Bioavailability of Piperine

Nano‐Cocrystals of Piperine‐Succinic Acid: Physicochemical Characterization and Dissolution Rate Studies

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