Colon-specific Delivery Research Articles

An updated landscape on nanopharmaceutical delivery for mitigation of colon cancer.

Globally, colorectal cancer (CRC) continues to rank among the leading causes of cancer-related death. Systemic toxicity, multidrug resistance, and nonspecific targeting often pose challenges to conventional therapy for CRC. Because it is a complex disease with a complex genetic and environmental pathophysiology, advanced therapeutic strategies are needed. Nanotechnology presents a potential solution that may maximize therapeutic efficacy while minimizing negative effects by enabling personalized delivery of anticancer drugs. This review focuses on recent developments in colorectal drug delivery systems based on nanotechnology. Numerous nanomaterials, including liposomes, dendrimers, micelles, exosomes, and gold nanoparticles, are developed and used. Distinctive characteristics of mentioned nanocarriers are discussed along with strategies that can be employed for enhancing the delivery of drugs to colorectal cancer cells. The review also quotes the most relevant preclinical and clinical studies that show how these nanomaterials improve drug solubility, stability, and targeted delivery while overcoming the shortcomings of conventional therapies. Nanotechnology has made CRC treatment very efficient and advanced, which has opened up new possibilities for targeted drug delivery. Preclinical and clinical studies have also proved that the use of nano-formulations in colon-specific delivery systems have significant results, indicating potential for better patient outcomes. Future research can be done in order to overcome the hurdles regarding biocompatibility, expansion, and regulatory challenges. Large-scale clinical trials and nanomaterial formulation optimization should be the main goals of future research to confirm the efficacy and safety of these novel treatments.

Colon-Specific Delivery of Naproxen Pellets for Rheumatoid Arthritis: Development, Optimization, and Evaluation Using a 3-Level Randomized Full Factorial Design

Rheumatoid arthritis (RA) is characterized by increased joint pain and stiffness, particularly in the morning, which requires medication for treatment. Our research described here was aimed to develop, evaluate, and optimize coated naproxen pellets for colon-specific delivery using the carboxymethyl Leucaena leucocephala gum for the chronotherapy of RA. The extrusion-spheronization process was used for the preparation of the pellets followed by coating in a fluidized bed processor with materials such as Eudragit® S 100 and L 100. An 11-run, 2-factor, 3-level, randomized full factorial design was used to analyze the impact on the responses by varying the levels of independent factors to obtain the optimized formulation. The drug release of all the formulation batches at the 4th hour varied from 1.24 to 17.22% in the upper gastrointestinal (GI) tract; while the release of the drug at the 10th hour varied from 76.87 to 98.39% at the colonic pH. Furthermore, it was observed that the optimized formulation exhibited an increased release of naproxen in the presence of cecal matter collected from rats. We suggest that the prepared optimized formulation of the coated pellets of naproxen shows promise for the chronotherapeutic treatment of early morning symptoms associated with RA.

Characterization and optimization of colon specific nanosponges immobilized polymeric microbeads formulation for the combined delivery of 5-fluorouracil and curcumin

Introductionand purpose: Site-specific delivery systems are highly advantageous for local cancer treatment as they allow a more significant delivery of the drug to the tumor with minimal systemic side effects. Furthermore, combination therapy is a promising approach that attracts more attention in cancer treatment due to its synergistic effects. In this work, nanosponges immobilized polymeric microbeads for colon-specific delivery systems were developed for a drug combination of 5-fluorouracil and curcumin to treat colorectal cancer. MethodsSodium alginate and low molecular chitosan polymers were used to create microbead-based formulations containing curcumin-encapsulated nanosponges and 5-fluorouracil. To improve curcumin's low solubility, Diphynylacarbonate (DPC) hyper cross-linking of β-CD was used to create curcumin-loaded β-CD nanosponges that further incorporated in the polymeric microbeads along with free 5-fluorouracil. ResultsThe optimized microbeads were spherical with a mean particle size of 1.1 ± 0.05 mm. The produced beads were subsequently coated with a multilayer coating of ethyl cellulose and Eudragit S100 polymers, which functioned as pH-dependent and time-dependent coatings to ensure drug delivery to the colon. The developed formulation (Coated MB5) showed controlled release of the drug and sustained cytotoxic effect. The release profiles of 5-fluorouracil and curcumin from Coated MB5 were best described by zero-order followed by first-order release functions. About 66.4 % of 5-FU and 73.1 % of curcumin were released for 24 h. In vivo roentgenographic evaluation in a rabbit model indicated that the optimized coated microbeads successfully reached the colon 7–9 h after administration. ConclusionsAs a prospective colon-specific drug delivery system, a successful formulation (Coated MB5) was developed for the combined delivery of 5-fluorouracil and curcumin. More in vivo studies are needed to demonstrate the therapeutic efficacy of optimized formulations and their potential to improve colorectal cancer therapy by providing a more targeted administration of combination medicines with fewer undesirable side effects.

Advances and optimization strategies in bacteriophage therapy for treating inflammatory bowel disease.

In the advancement of Inflammatory Bowel Disease (IBD) treatment, existing therapeutic methods exhibit limitations; they do not offer a complete cure for IBD and can trigger adverse side effects. Consequently, the exploration of novel therapies and multifaceted treatment strategies provides patients with a broader range of options. Within the framework of IBD, gut microbiota plays a pivotal role in disease onset through diverse mechanisms. Bacteriophages, as natural microbial regulators, demonstrate remarkable specificity by accurately identifying and eliminating specific pathogens, thus holding therapeutic promise. Although clinical trials have affirmed the safety of phage therapy, its efficacy is prone to external influences during storage and transport, which may affect its infectivity and regulatory roles within the microbiota. Improving the stability and precise dosage control of bacteriophages-ensuring robustness in storage and transport, consistent dosing, and targeted delivery to infection sites-is crucial. This review thoroughly explores the latest developments in IBD treatment and its inherent challenges, focusing on the interaction between the microbiota and bacteriophages. It highlights bacteriophages' potential as microbiome modulators in IBD treatment, offering detailed insights into research on bacteriophage encapsulation and targeted delivery mechanisms. Particular attention is paid to the functionality of various carrier systems, especially regarding their protective properties and ability for colon-specific delivery. This review aims to provide a theoretical foundation for using bacteriophages as microbiome modulators in IBD treatment, paving the way for enhanced regulation of the intestinal microbiota.

Advancements and challenges in pharmacokinetic and pharmacodynamic research on the traditional Chinese medicine saponins: a comprehensive review.

Recent research on traditional Chinese medicine (TCM) saponin pharmacokinetics has revealed transformative breakthroughs and challenges. The multicomponent nature of TCM makes it difficult to select representative indicators for pharmacokinetic studies. The clinical application of saponins is limited by their low bioavailability and short half-life, resulting in fluctuating plasma concentrations. Future directions should focus on novel saponin compounds utilizing colon-specific delivery and osmotic pump systems to enhance oral bioavailability. Optimizing drug combinations, such as ginsenosides with aspirin, shows therapeutic potential. Rigorous clinical validation is essential for practical applications. This review emphasizes a transformative era in saponin research, highlighting the need for clinical validation. TCM saponin pharmacokinetics, guided by traditional principles, are in development, utilizing multidisciplinary approaches for a comprehensive understanding. This research provides a theoretical basis for new clinical drugs and supports rational clinical medication.

Aldosterone applied mucosally or serosally is equally effective in stimulating ENaC activity in rat distal colon

Background: Aldosterone (ALDO), a mineralocorticoid hormone, is essential for regulating blood volume and electrolyte homeostasis. ALDO acts via intracellular mineralocorticoid receptors to stimulate epithelial Na+ channel (ENaC)-mediated Na+ absorption and large conductance K+ (BK) channel-mediated K+ secretion in both kidney and distal colon. We recently showed that ALDO stimulates iron absorption in rat distal colon and SK-CO15 cells (human colon cancer cell line), raising the prospect that ALDO might be used as adjuvant therapy in iron-deficient patients refractory to oral iron. Since, parenteral ALDO (or Fludrocortisone, a synthetic mineralocorticoid agonist) would adversely affect cardiovascular function, an alternative route of administration is required. Parenteral ALDO gains access to target epithelial cells via their serosal (basolateral) membranes, and in vitro studies have always employed serosally applied ALDO to determine its effects on colonic ion transport, but it is not known if mucosally (apically) applied ALDO has similar effects. Hypothesis: We hypothesized that like serosal ALDO, mucosal ALDO would diffuse across apical cell membranes and induce ENaC activity in normal rat distal colon. Aim: To determine whether mucosally applied ALDO stimulates amiloride-sensitive electrogenic Na+ transport in rat distal colon. Methods: Muscularis stripped normal rat (Sprague-Dawley; 126 – 150 g) distal colon was mounted under voltage clamp condition in Ussing chambers. ALDO (10 mM) was added to either the mucosal or serosal bath. ENaC activity was measured as the change in short-circuit current (Isc) following the mucosal addition of amiloride (10 mM). ALDO in mucosal and serosal bath solutions was measured using mass-spectroscopy. Results: With serosal addition of ALDO, transcriptionally induced ENaC activity began to increase after 4 hr and reached maximum/plateau by 5 hr. By contrast, with mucosal addition of ALDO, ENaC activity began to increase after 8 hr and slowly reached maximum/plateau by 9.5 hr. Maximal amiloride-sensitive ENaC activities were similar irrespective of whether ALDO was applied mucosally or serosally. Following addition of ALDO to the mucosal or serosal bath, a similar amount (40%) of ALDO had moved from mucosa to serosa or serosa to mucosa after 24 hr. Conclusions: We conclude that: (1) ALDO induces ENaC activity to the same extent, whether applied mucosally or serosally, and (2) the delayed effect of mucosally applied ALDO may reflect slower diffusion across apical membranes than across basolateral membranes. We speculate that developing a colon-specific delivery system may avoid the adverse cardiovascular effects of oral mineralocorticoid agonists (e.g. Fludrocortisone) if used to enhance colonic iron absorption in iron-deficient patients refractory to oral iron. Transition GrantSupport; Offce of Research and Graduate Education, WVU Health Sciences Center. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Characterization of high-internal-phase emulsions based on soy protein isolate with varying concentrations of soy hull polysaccharide and their capabilities for probiotic delivery: In vivo and in vitro release and thermal stability

In this study, the impact of soy hull polysaccharide (SHP) concentration on high-internal-phase emulsions (HIPEs) formation and the gastrointestinal viability of Lactobacillus plantarum within HIPEs were demonstrated. Following the addition of SHP, competitive adsorption with soy protein isolate (SPI) occurred, leading to increased protein adhesion to the oil–water interface and subsequent coating of oil droplets. This process augmented viscosity and enhanced HIPEs stability. Specifically, 1.8 % SHP had the best encapsulation efficiency and delivery efficiency, reaching 99.3 % and 71.1 %, respectively. After 14 d of continuous zebrafishs feeding, viable counts of Lactobacillus plantarum and complex probiotics in the intestinal tract was 1.1 × 107, 1.3 × 107, respectively. In vitro experiments further proved that HIPEs’ ability to significantly enhance probiotics’ intestinal colonization and provided targeted release for colon-specific delivery. These results provided a promising strategy for HIPEs-encapsulated probiotic delivery systems in oral food applications.

Engineering 5-flourouracil and leucovorin-loaded vesicular systems for possible colon specific delivery: In vitro evaluation and real time cell assay against HCT-116 colon cell lines

5-flourouracil (5-FU) is typically modulated with leucovorin (LEU) in clinical practice to improve clinical efficacy and patient survival rates. However, this combination has undesirable side effects and makes 5-FU more toxic. Hence, integrating a vesicular system (proniosomes) with another delivery vehicle may improve drug targeting, while resolving the aforementioned drawbacks. This study aimed to engineer 5-FU/LEU proniosomes for possible delivery to the colon. The modified slurry approach was used to create drug-loaded proniosomes (150 mg/9 g of carrier) using both water-soluble (dextrin (DEX) and lactose (LAC)) and insoluble (Neusilin FH2 (NEU)) carriers. The powdered formulations were filled into Eudragit S100 (10 %)-coated capsules or Eudragit FS 30D capsules for enteric- or colon-specific delivery. In vitro evaluations (flow properties, powder X-ray diffractometry (XRD) analysis, particle size analysis, entrapment efficiency, drug release, scanning electron microscopy (SEM), polydispersity index, Fourier transform infrared spectroscopy (FTIR), and stability studies) were performed on the formulations. An in vitro cytotoxicity test [real-time cell assay (RTCA)] against HCT-116 colon cancer cell lines was performed using the optimized formulation. In vitro evaluations showed that the nanoparticles had good physicochemical properties. RTCA studies showed sustained cell death with the formulations compared to the pure drug and placebo. The sequential drug release of the colon-targeted capsules containing 5-FU and LEU- loaded proniosomes showed negligible drug release in SGF (pH 1.2) and phosphate buffer solution (pH 6.8) (approximately 11 %) but profound drug release (>80 %) at pH 7.4. Drug-loaded proniosomes engineered for colon targeting (Eudragit S100 (10 %) capsules or Eudragit FS 30D capsules) showed good colon-specific targeting and favorable in vitro cytotoxicity profiles.

Design of Colon Specific Delivery of Sulfasalazine Loaded Nanoparticles for Inflammatory Bowel Syndrome: Application of Experimental Design

Sulfasalazine is the first line treatment for Inflammatory Bowel syndrome. Conventional formulation have poor targeting properties for colon site.Therefore designof colon specific nanoparticles (NP) is an ideal for better therapeutic outcome. The study aims to formulate and evaluate polymeric Nanoparticles loaded with Sulfasalazine to target the colon. The nanoparticles were prepared by Nano-precipitation method using pH dependent polymer and the prepared nanoparticles were evaluated for FTIR, morphology, pH, Viscosity, Entrapment efficiency, particle size and zeta potential etc. The nanoparticles were used to formulate core tablet and core tablets were coated with Eudragit S100. The tablets were evaluated for hardness, friability, thickness, weight variation and In vitro release study. Totally six formulations were developed for preliminary trial with varying concentration of polymers. From the preliminary trial, code F2batch was found to be best formulation. The F2batch was fitted to central composite design with two independent factors i.e. Concentration of Eudragit S100 (X1) and polyvinyl alcohol (X2) with four dependent variables i.e. Entrapment efficiency -Y1; Hardness- Y2; Friability-Y3 and In-vitro drug release- Y4. The formulation (code R6) was found to be the optimizedformulation. The optimized colon targeted tablets provide satisfactory release and might be suitable for colon targeting of sulfasalazine with better therapeutic effect.

Effects of microgels fabricated by microfluidic on the stability, antioxidant, and immunoenhancing activities of aquatic protein

Aquatic products are considered a potential source of novel bioactive proteins, which are used as therapeutic drugs for the treatment of different diseases (such as oxidative stress, immunocompromised, and inflammation), as well as nutraceuticals and cosmetics. However, the physical and chemical properties of proteins are unstable, and they are easily denatured by the influence of external high temperature and polar pH during processing, resulting in the loss of their functional activity. Herein, Fenneropenaeus chinensis water-soluble protein (FCWP) and Lateolabrax japonicus water-soluble protein (LJWP) were encapsulated within spherical biopolymer microgels composed of pectin and chitosan produced by the microfluidic device. The encapsulated samples remained inside the microgels when they were exposed to upper gastrointestinal but were released when they were exposed to simulated colonic fluid due to the hydrolysis effect by enzymes secreted by the colonic microflora. The results showed that microgels improve the thermal stability of FCWP and LJWP due to the interaction between polysaccharides and proteins in the microgels. In addition, microgels encapsulation did not affect the antioxidant and immunoenhancing activities of FCWP and LJWP. In summary, these microgels are suitable for oral colon-specific delivery in functional foods and supplements.

Preparation and Characterization of Novel Polyelectrolyte Liposomes Using Chitosan Succinate Layered over Chitosomes: A Potential Strategy for Colon Cancer Treatment.

Chitosan succinate is distinguished by its ability to shield the loaded drug from the acidic environment, localize and keep the drug at the colon site, and release the drug over an extended time at basic pH. The current study attempts to develop polyelectrolyte liposomes (PEL), using chitosan and chitosan succinate (CSSC), as a carrier for liposomal-assisted colon target delivery of 5 fluorouracil (5FU). The central composite design was used to obtain an optimized formulation of 5FU-chitosomes. The chitosan-coated liposomes (chitosomes) were prepared by thin lipid film hydration technique. After that, the optimized formulation was coated with CSSC, which has several carboxylic (COOH) groups that produce an anionic charge that interacts with the cation NH2 in chitosan. The prepared 5FU-chitosomes formulations were evaluated for entrapment efficiency % (EE%), particle size, and in vitro drug release. The optimized 5FU-chitosomes formulation was examined for particle size, zeta potential, in vitro release, and mucoadhesive properties in comparison with the equivalent 5FU-liposomes and 5FU-PEL. The prepared 5FU-chitosomes exhibited high EE%, small particle size, low polydispersity index, and prolonged drug release. PEL significantly limited the drug release at acidic pH due to the deprotonation of carboxylate ions in CSSC, which resulted in strong repulsive forces, significant swelling, and prolonged drug release. According to a 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) assay, PEL treatment significantly decreased the viability of HT-29 cells. When compared to 5FU-liposome and 5FU-chitosome, the in vivo pharmacokinetics characteristics of 5FU-PEL significantly (p < 0.05) improved. The findings show that PEL enhances 5FU permeability, which permits high drug concentrations to enter cells and inhibits the growth of colon cancer cells. Based on the current research, PEL may be used as a liposomal-assisted colon-specific delivery.

Preparation and in-vitro evaluation of single and bi-layered beeswax-based microparticles for colon-specific delivery of mesalamine

Beeswax is selected as a natural coating material for the development of new colon specific drug delivery systems charged by mesalamine. In a first step, beeswax microparticles are prepared using hot-melt process of microencapsulation where drug:beeswax ratio, stirring speed, emulsifier concentration and pH of external phase are varied for the optimization of the drug entrapment and microparticles? morphology. The effect of the nature of the emulsifier is also discussed by studying the hydrophilic?lipophilic balance (HLB) value. In a second step, to obtain delayed delivery systems, bi-layered microspheres are elaborated by the process of emulsion?solvent evaporation using ethylcellulose or cellulose acetate butyrate as outer enteric coating layer. All formulations are characterized by infrared spectroscopy, X-ray diffraction, scanning electron microscopy and optical microscopy. The drug release is established in simulated gastric, small bowel and colon liquids and the release mechanism is discussed by applying the Korsmeyer?Peppas model.

Design, Optimization and In vitro Evaluation of Mesalazine 400 mg Delayed Release Tablet for Colon Specific Delivery

Ulcerative colitis is a chronic inflammatory disease, and patients would get benefit more if the drug is given directly to the colon. Mesalazine is intended to deliver to the colon for treating ulcerative colitis. Here, we aimed to design and optimize mesalazine 400 mg delayed release tablet for colon-specific delivery using a quality by design (QbD) approach. The tablet was first formulated as an optimized core tablet and then coated with Eudragit S 12.5 for ensuring colonic delivery. The experimental design for the core tablet was constructed using a 32 full factorial design, where the percentages of sodium starch glycolate (SSG) and polyvinylpyrrolidone (PVP K-30) were independent variables and the tablet hardness (kg/cm2) and cumulative percentage of drug release at pH 7.2 phosphate buffer after 1.5 hours were treated as responses. Responses obtained from the initial exploratory formulations were evaluated to develop an optimized formulation to have a hardness value of 7-8 kg/cm2 and the maximum amount of drug release at pH 7.2 buffer. The optimized formulation involved the use of SSG and PVP K-30 at 3.05% and 1.69%, respectively. Hardness and cumulative percent of drug release obtained for the optimized core tablet were 7.8 kg/cm2 and 91.76%, respectively. The compatibility of drug and excipients was studied utilizing XRD, FTIR and TGA. The optimized core tablet was then coated with Eudragit S 12.5 to deliver the drug selectively to the colon and further assessed for its in vitro dissolution. Dissolution studies indicated that coated tablets with a weight gain of 7.4% exhibited the maximum cumulative percent of drug release (91.19 ± 0.11%), with a zero-order drug release profile (R2 = 0.943). A stability study performed according to ICH Q1A (R2) guidelines at accelerated storage conditions identified that there was no significant change in drug content over the storage period, indicating the stability of the formulated tablet batches. Together, these data suggest that the mesalazine tablet developed through the QbD approach offers excellent physical properties and drug release profile and, therefore, could be recommended for commercial manufacturing. Dhaka Univ. J. Pharm. Sci. 22(2): 189-201, 2023 (December)

Colon-targeted S100A8/A9-specific peptide systems ameliorate colitis and colitis-associated colorectal cancer in mouse models.

The link between chronic inflammation and cancer development is well acknowledged. Inflammatory bowel disease including ulcerative colitis and Crohn's disease frequently promotes colon cancer development. Thus, control of intestinal inflammation is a therapeutic strategy to prevent and manage colitis-associated colorectal cancer (CRC). Recently, gut mucosal damage-associated molecular patterns S100A8 and S100A9, acting via interactions with their pattern recognition receptors (PRRs), especially TLR4 and RAGE, have emerged as key players in the pathogenesis of colonic inflammation. We found elevated serum levels of S100A8 and S100A9 in both colitis and colitis-associated CRC mouse models along with significant increases in their binding with PRR, TLR4, and RAGE. In this study we developed a dual PRR-inhibiting peptide system (rCT-S100A8/A9) that consisted of TLR4- and RAGE-inhibiting motifs derived from S100A8 and S100A9, and conjugated with a CT peptide (TWYKIAFQRNRK) for colon-specific delivery. In human monocyte THP-1 and mouse BMDMs, S100A8/A9-derived peptide comprising TLR4- and RAGE-interacting motif (0.01, 0.1, 1 μM) dose-dependently inhibited the binding of S100 to TLR4 or RAGE, and effectively inhibited NLRP3 inflammasome activation. We demonstrated that rCT-S100A8/A9 had appropriate drug-like properties including in vitro stabilities and PK properties as well as pharmacological activities. In mouse models of DSS-induced acute and chronic colitis, injection of rCT-S100A8/A9 (50 μg·kg-1·d-1, i.p. for certain consecutive days) significantly increased the survival rates and alleviated the pathological injuries of the colon. In AOM/DSS-induced colitis-associated colorectal cancer (CAC) mouse model, injection of rCT-S100A8/A9 (50 μg·kg-1·d-1, i.p.) increased the body weight, decreased tumor burden in the distal colon, and significantly alleviated histological colonic damage. In mice bearing oxaliplatin-resistant CRC xenografts, injection of rCT-S100A8/A9 (20 μg/kg, i.p., every 3 days for 24-30 days) significantly inhibited the tumor growth with reduced EMT-associated markers in tumor tissues. Our results demonstrate that targeting the S100-PRR axis improves colonic inflammation and thus highlight this axis as a potential therapeutic target for colitis and CRC.

PH Sensitive Quercetin Nanoparticles Ameliorate DSS-Induced Colitis in Mice by Colon-Specific Delivery.

Ulcerative colitis (UC) is a classic inflammatory bowel disease (IBD) that represents a serious threat to human health. As a natural flavonoid with multiple biological activities, quercetin (QCT) suffers from low bioavailability through limitations in chemical stability. Here, the study investigates the regulatory effects of quercetin nanoparticles (QCT NPs) on dextran sulfate sodium (DSS) induced colitis mice. Chitosan is modified to obtain N-succinyl chitosan (NSC) with superior water solubility. Nanoparticles composed of sodium alginate (SA) and NSC can encapsulate QCT after cross-linking, forming QCT NPs. In vitro drug release assays demonstrate the pH sensitivity of QCT NPs. Compared with free quercetin, QCT NPs have better therapeutic efficacy in modulating gut microbiota and its metabolites short chain fatty acid (SCFAs) to relieve DSS-induced colitis in mice, thereby alleviating colon inflammatory infiltration, increasing goblet cells density and mucus protein, ameliorating TNF-α, IL-1β, IL-6, IL-10, and Myeloperoxidase (MPO) levels, and recovering intestinal barrier integrity. pH sensitive QCT nanoparticles can reduce inflammatory reaction, improve gut microbiota, and repair intestinal barrier by targeting colon, thus improving DSS induced colitis in mice, providing reference for the treatment of colitis.

A pH-sensitive silica nanoparticles for colon-specific delivery and controlled release of catechin: Optimization of loading efficiency and in vitro release kinetics

Catechin is a naturally occurring flavonoid of the flavan-3-ol subclass with numerous biological functions; however, these benefits are diminished due to several factors, including low water solubility and degradation in the stomach's harsh environment. So, this study aimed to develop an intelligent catechin colon-targeting delivery system with a high loading capacity. This was done by coating surface-decorated mesoporous silica nanoparticles with a pH-responsive enteric polymer called Eudragit®-S100. The pristine wormlike mesoporous silica nanoparticles (< 100 nm) with high surface area and large total pore volume were effectively synthesized and modified with the NH2 group using the post-grafting strategy. Various parameters, including solvent polarity, catechin-carrier mass ratio, and adsorption time, were studied to improve the loading of catechin into the aminated silica nanoparticles. Next, the negatively charged Eudragit®-S100 was electrostatically coated onto the positively charged aminated nanocarriers to shield the loaded catechin from the acidic environment of the stomach (pH 1.9) and to facilitate site-specific delivery in the acidic environment of the colon (pH 7.4). The prepared nanomaterials were evaluated using several methods, including The Brauner-Emmett-Teller, surface area analyzer, zeta sizer, Field Emission Scanning Electron Microscope, Powder X-Ray Diffraction, Fourier Transform Infrared Spectroscopy, Energy-Dispersive X-ray Spectroscopy, and Differential Scanning Calorimetry. In vitro dissolution studies revealed that Eudragit®-S100-coated aminated nanomaterials prevented the burst release of the loaded catechin in the acidic environment, with approximately 90% of the catechin only being released at colonic pH (pH > 7) with a supercase II transport mechanism. As a result, silica nanoparticles coated with Eudragit®-S100 would provide an innovative and promising approach in targeted nanomedicine for the oral delivery of catechin and related medicines for treating diseases related to the colon, such as colorectal cancer and irritable bowel syndrome.

Colon-Targeted Delivery of Indole Acetic Acid Helps Regulate Gut Motility by Activating the AHR Signaling Pathway.

Intestinal peristalsis is vital for gastrointestinal physiology and host homeostasis and is frequently dysregulated in intestinal disorders. Gut microbiota can regulate gut motility, especially through the tryptophan metabolism pathway. However, the role of indoles as microbial tryptophan metabolites in colonic function requires further exploration. Here, we show that the delivery of indole acetic acid (IAA) targeting the colon can improve gut motility by activating the aryl hydrocarbon receptor (AHR). To achieve colon-targeted delivery, Eudragit S-100 (ES) and chitosan (CS) were used as drug carriers. After optimisation, IAA-loaded ES-coated CS nanoparticles exhibited an encapsulation efficiency of 83% and a drug-loading capacity of 16%. These nanoparticles exhibited pH-dependent characteristics and remained stable in acidic conditions and the upper intestine. In simulated intestinal fluid (pH 7.4) and colonic lumen, considerable amounts of IAA were released after approximately 4 h. Compared with free IAA, the nanoparticles exerted enhanced therapeutic effects on gut movement disorders induced by loperamide. The efficacy of IAA treatment was attributable to the activation of the AHR signalling pathway and increased levels of AHR agonists. Furthermore, the oral administration of IAA-loaded nanoparticles promoted serotonin secretion and maintained the intestinal barrier function. The experimental outcomes demonstrate the efficiency of the proposed colon-specific delivery system and highlight the role of IAA, produced by gut microbiota metabolism, in regulating gut peristalsis through AHR activation.

Nanosuspension encapsulated chitosan-pectin microbeads as a novel delivery platform for enhancing oral bioavailability

The current study aimed to overcome the poor solubility and colon-specific delivery of curcumin (CUR) by formulating a curcumin nanosuspension (CUR-NS) using the antisolvent precipitation method. Freeze-dried CUR-NS was encapsulated into microbeads (CUR-NS-MB) by the ionotropic gelation method using zinc chloride (as a cross-linking agent) with the help of rate-controlling polymers, pectin, and chitosan. Furthermore, cellulose acetate phthalate (CAP) is incorporated as an enteric polymer to protect against acidic medium degradation. Particle size, surface morphology, interaction studies, and entrapment studies were performed to optimize CUR-NSs. Nanosuspensions stabilized with hydroxypropyl methylcellulose (HPMC E-15; 1 % w/v) showed an average particle size of 193.5 ± 4.31 nm and a polydispersity index (PDI) of 0.261 ± 0.020. The optimized microbeads (CUR-NS-MB) showed 89.45 ± 3.11 % entrapment efficiency with a drug loading of 14.54 ± 1.02 %. The optimized formulation (CUR-NS-MB) showed colon-specific in vitro drug release bypassing acid pH degradation. In animal studies, a 2.5-fold increase in Cmax and a 4.4-fold increase in AUC048h were observed with CUR-NS-MB, which was more significant than that of plain CUR. Therefore, the developed CUR-NS-MB has the potential to be used as a colon-specific delivery system.

Preparation of core–shell hordein/pectin nanoparticles as quercetin delivery matrices: Physicochemical properties and colon-specific release analyses

Quercetin (Que) is a hydrophobic flavanol that has the potential to prevent colon diseases. This study aimed to design hordein/pectin nanoparticle as a colon-specific delivery system for quercetin. The encapsulation efficiency, physicochemical stability and release properties of the nanoparticles were estimated. The FTIR and secondary structure analysis indicated that hydrogen bonds, hydrophobic interactions and electrostatic attractions were formed in the quercetin-loaded hordein/pectin nanoparticles (Que-hordein/pectin NPs). In comparison to Que-hordein NPs, Que-hordein/pectin NPs exhibited better colloidal stability (physical, UV light, heating and salt). Furthermore, the release properties studies showed that pectin coating restrained the premature release of Que from hordein NPs in gastric fluid and intestinal fluid. In-vitro release, when the Que-hordein/pectin NPs were exposed to simulated colonic fluid (SCF) for 6 h, quercetin was greatly released from the hordein/pectin NPs (15.29 ± 1.17% – 80.60 ± 1.78%). In-vivo release, the concentration of Que (μg/g) in Que-hordein/pectin NPs was 2.18 times higher than Que-hordein NPs in colon tissue after 6 h of oral administration. This study suggests that Que-hordein/pectin NPs have promising applications in the specific delivery and release of quercetin to the colon.

Achillea wilhelmsii-Incorporated Chitosan@Eudragit Nanoparticles Intended for Enhanced Ulcerative Colitis Treatment.

Achillea wilhelmsii (A. wilhelmsii) contains several therapeutic phytochemicals, proposing a protective effect on inflammatory responses in autoimmune diseases such as ulcerative colitis (UC). However, its activities against UC encounter multiple obstacles. The current study aimed to formulate a colon-specific delivery of A. wilhelmsii for treating UC using chitosan nanoparticles (NPs) and Eudragit S100 as a mucoadhesive and pH-sensitive polymer, respectively. Core chitosan NP was loaded with A. wilhelmsii extract, followed by coating with Eudragit S100. Then, physicochemical characterizations of prepared NPs were conducted, and the anti-UC activity in the rat model was evaluated. The relevant physicochemical characterizations indicated the spherical NPs with an average particle size of 305 ± 34nm and high encapsulation efficiency (88.6 ± ‏7.3%). The FTIR (Fourier transform infrared) analysis revealed the Eudragit coating and the extract loading, as well as the high radical scavenging ability ofA. wilhelmsiiwas confirmed. The loaded NPs prevented the extract release in an acidic pH-mimicking medium and presented a complete release thereafter at a colonic pH. The loaded NPs markedly mitigated the induced UC lesions in rats, reflected by reducing inflammation, ulcer severity, and UC-related symptoms. Further, histopathological analysis exhibited reducing the extent of the inflammation and damage to colon tissue, and the determination of the involved pro-inflammatory cytokines in serum showed a significant reduction relative to free extract. The present results show that chitosan NPs containingA. wilhelmsiiextract coated with Eudragit having proper physicochemical properties and substantial anti-inflammatory activity can significantly improve colonic lesions caused by UC.