The Impact of Improving Dermal Permeation on the Efficacy and Targeting of Liposome Nanoparticles as a Potential Treatment for Breast Cancer

In Vitro and in vivo characterization of nasal pH-Responsive in-situ hydrogel of Candesartan-loaded invasomes as a potential stroke treatment

Candesartan (CDN) is a useful anti-stroke medication because it lowers blood pressure, inflammation, oxidative stress, angiogenesis and apoptosis. However, CDN has limited efficacy due to its low solubility and poor bioavailability. This study set out to develop nasal pH-responsive in situ hydrogel of CDN-loaded invasomes a (PRHCLI) for enhancing CDN's release, penetration, bioavailability, and effectiveness as a possible treatment for stroke. Based on the results of the pre-formulation investigation, the optimum CLI formulation for intravasomal delivery of CDN was determined to be 3% of phospholipid, 0.16% of cholesterol, 3% of ethanol, and 1% of cineole. The optimum formulation significantly enhanced CDN permeation and release by 2.06-fold and 59.06%, respectively. The CLI formulation was added to a mixture of chitosan (0.67%w/v) and glyceryl monooleate (0.27%v/v) to develop PRHCLI. The PRHCLI formulation enhanced the release and permeation of CDN relative to free CDN by 2.15 and 2.76 folds, respectively. An experimental rat stroke model was utilized for in vivo studies to evaluate the bioavailability, effectiveness, and toxicity of the PRHCLI formulation. The nasal PRHCLI drops increased the CDN's bioavailability by 3.20-fold compared to oral free CDN. Increased grip strength and decreased flexion, spontaneous motor activity, and Morris Water Maze scores in comparison to oral free CDN showed that nasal PRHCLI drops have better anti-stroke activity. The toxicity evaluation revealed the safety of nasal PRHCLI. Hence, nasal PRHCLI drops may represent a promising avenue as a stroke therapy.

Tailoring moxifloxacin hydrochloride loaded oleic acid liposomes for the topical management of Methicillin-Resistant Staphylococcus aureus (MRSA)- Induced skin infection: In-vitro characterization and in-vivo assessment

Oleic acid liposomes (OALs) are novel vesicular carriers ofunsaturated fatty acids and their corresponding ionized species, arranged within an enclosed lipid bilayer. This study aimed to encapsulate moxifloxacin HCl (MOX), a broad-spectrum antibacterial drug into OALs for effective treatment of Methicillin-resistant Staphylococcus aureus (MRSA) infection through topical application. Various OALs were formulatedby combining varied quantities of phosphatidylcholine (PC), oleic acid (OA), and cholesterol (CH) with 50 mg of MOX. The OALs were produced utilizing varying sonication durations. MOX-loaded OALs were formulated using the thin film hydration method by applying (24) a full factorial design utilizing the Design-Expert® software. The formula for MOX-loaded OALs was OAL13, which consisted of 200 mg of PC and 20 mg of OA. The mixture was sonicated for 5 min. The OAL13 exhibited spherical vesicles with a small diameter and a smooth outer surface. Additionally, the entrapment efficiency was measured to be 75.00 ± 1.41 %, the particle size was 234.65 ± 4.74 nm, the polydispersity index was 0.53 ± 0.01, and the zeta potential was -38.50 ± 0.42 mV. The OAL13 formula exhibited an extended release profile. Moreover, the antibiofilm activity of OAL13 gel and MOX-loaded liposomes gel against MRSA infection demonstrates greater activity than the MOX gel at the maximum concentration used (MIC/2). Furthermore, the in-vivo study showed that OAL13 improved MOX's antimicrobial and immunomodulatory effects against MRSA infection by increasing TLR-2 and IL-1β, as well as their downstream molecules NF-κB and TNF-α. Moreover, the histopathological examination conducted by a skin irritation test has verified the safety of OAL13. Overall, the results demonstrated the significant efficacy of MOX-loaded OALs in the treatment of MRSA infected wounds when applied topically.

Development and optimization of raloxifene hydrochloride loaded lipid nanocapsule based hydrogel for transdermal delivery

AIM

Development and optimization of raloxifene hydrochloride loaded lipid nanocapsule hydrogel for transdermal delivery.

METHOD

A 33 Box-Behnken Design and numerical optimization was performed to obtain the optimized formulation. Subsequently, the optimized raloxifene hydrochloride loaded lipid nanocapsule was developed using phase inversion temperature and characterized for physicochemical properties. Furthermore, the optimized lipid nanocapsule was loaded into a hydrogel and evaluated for rheology, spreadability, ex-vivo skin permeation, deposition and irritation.

RESULTS

The numerical optimization suggested an optimal formula with desirability value of 0.852 and low prediction errors. The optimized formulation showed good % drug entrapment efficiency (79.56 ± 2.34%), nanometer size (56.68 ± 1.2 nm), monodisperse nature (PDI = 0.176 ± 0.2), spherical morphology and good drug-excipient compatibility. The raloxifene hydrochloride loaded lipid nanocapsule hydrogel showed shear thinning properties, sustained drug delivery, dermal compatibility and significantly higher permeability (2-fold), retention (3.37) for raloxifene hydrochloride compared to the control.

CONCLUSION

The present study showed a successful development of raloxifene hydrochloride loaded lipid nanocapsule hydrogel with improved skin permeation, retention, and good topical compatibility. This formulation may overcome the challenges associated with raloxifene hydrochloride oral delivery including low bioavailability.

A Comprehensive Review on Current Knowledge and Future Potential of Topical Therapies in Breast Cancer Treatment

Breast cancer remains one of the most prevalent malignancies among women globally. Despite advances in therapeutic options, the prognosis often remains challenging. Breast cancer typically originates in the epithelial lining of glandular tissue ducts (85%) or lobules (15%). Initially confined to these areas (in situ), it generally remains asymptomatic and poses little risk of metastasis. The primary treatments for breast cancer include surgery, radiation therapy, chemotherapy, hormone therapy, and targeted therapy. Although these interventions have advanced significantly and have improved patient survival rates, they are connected with numerous im mediate and long-term side effects. Effective breast cancer treatment aims to maximize efficacy while minimizing adverse effects. Given that many breast cancers are specific to the breast, developing safe and targeted therapeutic strategies will be of benefit. This review examined the current literature on the effectiveness of topical therapies for breast cancer. Studies and clinical trials were evaluated that have investigated these treatments, focusing on their safety, ease of application, and patient acceptance. Recently, topical drug delivery is transforming breast cancer therapy, offering precision and reduced systemic toxicity. Emu oil-enhanced tamoxifen showed superior transdermal effectiveness, while raloxifene gel achieved 2.77 times greater bioavailability than oral forms. Tamoxifen nanoemulgels and microneedle arrays with resveratrol further enhanced localized delivery, These therapies have gained patient acceptance due to their non-invasive nature, lack of gastrointestinal side effects, ease of application, and favourable safety and therapeutic profiles and setting a new benchmark for innovative and patient-friendly treatments. This review summarizes the findings from various studies, highlighting the benefits and limitations of topical therapies. Topical therapies offer a promising noninvasive option for breast cancer treatment with fewer side effects. These treatments have shown favorable therapeutic and safety profiles, making them an attractive option for patients.

Fabrication and In Vivo Evaluation of In Situ pH-Sensitive Hydrogel of Sonidegib-Invasomes via Intratumoral Delivery for Basal Cell Skin Cancer Management

BACKGROUND/OBJECTIVES

Basal cell skin cancer (BCSC) develops when skin cells proliferate uncontrollably. Sonidegib (SDB) is a therapeutic option for the treatment of BCSC by inhibiting hedgehog signaling. The problems with SDB's low solubility, poor bioavailability, resistance, poor targeting, and first-pass action make it less effective when taken orally. This investigation set out to design an intratumoral in situ pH-sensitive hydrogel of SDB-invasomes (IPHS-INV) that can effectively treat BCSC by improving SDB's bioavailability, sustainability, targeting, and efficacy while also reducing its resistance and undesirable side effects.

METHODS

Numerous S-INV formulations were developed using Box-Behnken Design Expert and tested before settling on the optimum S-INV formulation. An experimental 7, 12-dimethylbenzanthracene (DMBA) carcinoma rat model was used for in vivo studies of the IPHS-INV formulation after it was combined with chitosan.

RESULTS

Phospholipids (1.72% w/w), cholesterol (0.15% w/w), ethanol (1% v/v), and cineole (1.5% v/v) were shown to be the optimal components in the SDB-invasome formulation. The IPHS-INV formulation outperformed the permeation and bioavailability of free SDB by 7.14 and 6 times, respectively, and sustained its release by 57.41%. The IPHS-INV formulation showed a decrease in tumor volume of 99.05% and a reduction of hypercellular tumors, indicating its anti-cancer activity. The intratumoral IPHS-INV formulation maintained a higher concentration of SDB in tumors, indicating its targeting activity.

CONCLUSIONS

These findings support the use of the intratumoral IPHS-INV formulation as an effective strategy for the treatment of BCSC.

Improving the targeting and therapeutic efficacy of anastrazole for the control of breast cancer: In vitro and in vivo characterization

Anastrazole (ASZ) is an effective aromatase inhibitor that is used for breast cancer treatment. Nevertheless, ASZ's effectiveness is diminished due to its low water solubility, unregulated release, absence of targeting, and inadequate patient compliance. The goal of the research was to create a hydrogel formulation of ASZ-loaded invasomes (ALI) to enhance the solubility, permeability, targeting, and efficacy of ASZ while also sustaining its release for treatment of breast cancer. The optimized ALI formulation was determined to be 3%w/v phospholipid, 0.15%w/v cholesterol, 3%v/v ethanol, and 1 %v/v cineole based on the results of the pre-formulation study. After conducting in vitro characterization of the optimum formulation, it was combined with carbopol for in vivo examination of its anti-tumor efficacy in a rat model of 7, 12-dimethylbenzanthracene. Compared to free ASZ, ALI hydrogel increased its penetration by 10.67 times and prolonged its release by 64.02%. Compared to the control positive group, ALI hydrogel reduced tumor volume by 99.19% and mortality by 10.93%. The anti-tumor effect of the ALI hydrogel was demonstrated by its ability to accumulate more ASZ in tumors and reduce hypercellular tumors. Overall, transdermal ALI hydrogel shows potential as a promising approach for treating breast cancer.

Fabrication of an In Situ pH-Responsive Raloxifene-Loaded Invasome Hydrogel for Breast Cancer Management: In Vitro and In Vivo Evaluation

BACKGROUND/OBJECTIVES

Raloxifene (RLF) is a therapeutic option for invasive breast cancer because it blocks estrogen receptors selectively. Low solubility, limited targeting, first-pass action, and poor absorption are some of the challenges that make RLF in oral form less effective. This study aimed to create an intra-tumoral in situ pH-responsive formulation of RLF-invasome (IPHRLI) for breast cancer treatment, with the goals of sustaining RLF release, minimizing adverse effects, and enhancing solubility, bioavailability, targeting, and effectiveness.

METHODS

Numerous RLF-invasome formulations were optimized using design expert software (version 12.0.6.0, StatEase Inc., Minneapolis, MN, USA). Integrating an optimal formulation with an amalgam of chitosan and glyceryl monooleate resulted in the IPHRLI formulation. In vivo testing of the IPHRLI formulation was conducted utilizing the Ehrlich cancer model.

RESULTS

Requirements for an optimum RLF-invasome formulation were met by a mixture of phospholipids (2.46%), ethanol (2.84%), and cineole (0.5%). The IPHRLI formulation substantially sustained its release by 75.41% after 8 h relative to free RLF. The bioavailability of intra-tumoral IPHRLI was substantially raised by 4.07-fold compared to oral free RLF. Histopathological and tumor volume analyses of intra-tumoral IPHRLI confirmed its efficacy and targeting effect.

CONCLUSIONS

the intra-tumoral administration of the IPHRLI formulation may provide a potential strategy for breast cancer management.

Improving the bioavailability and therapeutic efficacy of felodipine for the control of diabetes-associated atherosclerosis: In vitro and in vivo characterization

Felodipine has proven to be effective as an atherosclerosis therapy because it increases blood flow to the vessel wall. However, the poor solubility, low bioavailability, and hepatic first-pass metabolism of oral felodipine compromise its therapeutic effectiveness. The study's goal is to create a nasal pH-sensitive hydrogel of felodipine-loaded invasomes (IPHFI) that will improve felodipine's release, permeation, bioavailability, and efficacy as a potential diabetes-associated atherosclerosis therapy. According to the pre-formulation study, the felodipine-loaded invasomes formulation composed of phospholipid (3%w/v), cholesterol (0.16%w/v), ethanol (3%v/v) and cineole (1%v/v) was chosen as the optimum formulation. The optimum formulation was characterized in vitro and then mixed with a mixture of chitosan and glyceryl monooleate to make the IPHFI formulation. The IPHFI formulation enhanced the release and permeation of felodipine by 2.99 and 3-fold, respectively. To assess the efficacy and bioavailability of the IPHFI formulation, it was studied in vivo using an experimental atherosclerosis rat model. Compared to oral free felodipine, the nasal administration of the IPHFI formulation increased the bioavailability by 3.37-fold and decreased the serum cholesterol, triglycerides, LDL, and calcification score by 1.56, 1.53, 1.80, and 1.18 ratios, respectively. Thus, nasal IPHFI formulation may represent a promising diabetes-associated atherosclerosis therapy.

Functional candesartan loaded lipid nanoparticles for the control of diabetes-associated stroke: In vitro and in vivo studies

Diabetes mellitus is a metabolic disease that raises the odds of developing stroke. Candesartan has been used to prevent stroke due to its inhibitory effects on blood pressure, angiogenesis, oxidative damage, and apoptosis. However, oral candesartan has very limited bioavailability and efficacy due to its weak solubility and slow release. The study aimed to develop a nasal formulation of candesartan-loaded liposomes containing ethanol and propylene glycol (CLEP) to improve candesartan's delivery, release, permeation, and efficacy as a potential diabetes-associated stroke treatment. Using design expert software, different CLEP formulations were prepared and evaluated in vitro to identify the optimum formulation, which. The selected optimum formulation composed of 3.3% phospholipid, 10% ethanol, and 15% propylene glycol significantly increased the release and permeation of candesartan relative to free candesartan by a factor of 1.52 and 1.47, respectively. The optimum formulation significantly reduced the infarction after stroke in rats; decreased flexion, spontaneous motor activity, and time spent in the target quadrant by 70%, 64.71%, and 92.31%, respectively, and enhanced grip strength by a ratio of 2.3. Therefore, nasal administration of the CLEP formulation could be a potential diabetes-associated stroke treatment.

Assembly of In-Situ Gel Containing Nano-Spanlastics of an Angiotensin II Inhibitor as a Novel Epitome for Hypertension Management: Factorial Design Optimization, In-vitro Gauging, Pharmacokinetics, and Pharmacodynamics Appraisal

More than 1 billion people worldwide suffer from hypertension; therefore, hypertension management has been categorized as a global health priority. Losartan potassium (LP) is an antihypertensive drug with a limited oral bioavailability of about 33% since it undergoes the initial metabolic cycle. Thus, nasal administration is a unique route to overcome first-pass metabolism. The investigation focused on the potential effects of LP-loaded spanlastic vesicles (SNVs) on LP pharmacodynamics and pharmacokinetic parameters, utilizing a thin-film hydration methodology established on a 3122 full factorial design. Entrapment efficiency (EE%) ranged from 39.8 ± 3.87.8 to 83.8 ± 2.92% for LP-SNVs. Vesicle size (VS) varied from 205.5 ± 6.5.10 to 445.1 ± 13.52 nm, and the percentage of LP released after 8 h (Q8h) ranged from 30.8 ± 3.10 to 68.8 ± 1.45%. LP permeated through the nasal mucosa during 24 h and flocculated from 194.1 ± 4.90 to 435.3 ± 13.53 µg/cm2. After twenty-four hours, the optimal LP-SNVs in-situ gel showed 2.35 times more permeation through the nasal mucosa than the LP solution. It also lowered systolic blood pressure, so it is thought to be better than the reference formulation in terms of pharmacodynamics. The pharmacokinetics studies demonstrated that the intranasal LP-SNVs gel boosted its bioavailability approximately 6.36 times compared to the oral LP solution. Our research showed that intranasal LP-SNVs could be a good nanoplatform because they are well-tolerated and have possible pharmacokinetics and pharmacodynamics.

Design, optimization, and in vivo evaluation of invasome-mediated candesartan for the control of diabetes-associated atherosclerosis

Atherosclerosis is an inflammatory disease characterized by the accumulation of arterial plaque. Diabetes mellitus stands out as a major risk factor for atherosclerosis. Candesartan is a potent angiotensin II receptor antagonist that enhances arterial blood flow and reduces insulin resistance. However, oral candesartan has limited activity because of its low bioavailability, water solubility, hepatic first-pass degradation, and efficacy. The current study aims to develop nasal candesartan-loaded invasome (CLI) drops to improve candesartan's permeation, release, and bioavailability as a potential treatment for diabetes-associated atherosclerosis. Design expert software was used to prepare various CLI formulations to determine the impact of the concentrations of ethanol, cineole, and phospholipid. The desirability index was used to estimate the optimized formulation composition to maximize entrapment efficiency and minimize vesicle size. The optimized formulation had a 1% ethanol concentration, a 1.5% cineole concentration, and a 2.32% phospholipid concentration. The selected optimized formulation was then tested in a rat model of diabetes and atherosclerosis to evaluate its activity. The results showed that nasal CLI drops significantly raised serum HDL levels by a ratio of 1.42 and lowered serum glucose, cholesterol, triglycerides, LDL, and VLDL levels by 69.70%, 72.22%, 36.52%, 58.0%, and 65.31%, respectively, compared with diabetic atherosclerotic rats, throwing an insight on the potential for promising anti-diabetic and anti-atherosclerotic activities. Additionally, atherosclerotic lesions were improved in rats treated with CLI, as shown in histopathology. In conclusion, the results of this investigation showed that treatment with nasal CSN-loaded invasome formulation drops prevented the initiation and progression of diabetes-associated atherosclerosis.

Formulation and Therapeutic Evaluation of Isoxsuprine-Loaded Nanoparticles against Diabetes-Associated Stroke

Ischemic stroke is the second-leading cause of death. Hyperglycemia, which is characteristic of diabetes mellitus, contributes to the development of endothelial dysfunction and increases the risk of stroke. Isoxsuprine is an efficient beta-adrenergic agonist that improves blood flow to the ischemic aria and stops the infarct core from growing. However, low bioavailability, a short biological half-life, and first-pass hepatic metabolism reduce the therapeutic efficacy of oral isoxsuprine. Therefore, the authors focused on developing isoxsuprine-loaded liposomes containing ethanol and propylene glycol (ILEP) formulation as nasal drops for the treatment of ischemic stroke in diabetic patients. Different ILEP formulations were optimized using Design Expert software, and the selected formulation was examined in vivo for its anti-stroke effect using a rat model of diabetes and stroke. The optimized ILEP, composed of 15% propylene glycol, 0.16% cholesterol, 10% ethanol, and 3.29% phospholipid, improved the sustainability, permeation, and targeting of isoxsuprine. Furthermore, the in vivo studies verified the improved neurological behavior and decreased dead shrunken neurons and vascular congestion of the rats treated with the optimized ILEP formulation, demonstrating its anti-stroke activity. In conclusion, our study found that treatment with an optimized ILEP formulation prevented the initiation and severity of stroke, especially in diabetic patients.

Synthesis of Carvacrol-Loaded Invasomes Nanoparticles Improved Acaricide Efficacy, Cuticle Invasion and Inhibition of Acetylcholinestrase against Hard Ticks

Carvacrol is a monoterpenoid phenol found in many essential oils that has antibacterial, antifungal and antiparasitic activities. Drug loaded-invasome systems are used to deliver drugs utilizing nanoparticles to improve bioavailability, efficacy, and drug release duration. As a result, the present study developed carvacrol-loaded invasomes and evaluated their acaricidal effect against Rhipicephalus annulatus (cattle tick) and Rhipicephalus sanguineus (dog tick). Carvacrol loaded-invasome (CLI) was prepared and characterized using UV/Vis spectrophotometer, zeta potential measurements, Scanning Transmission Electron Microscopy (STEM), Fourier Transform Infrared (FT-IR) Spectroscopy, and Differential Scanning Calorimetry Analysis. CLI (5%) induced significant mortality (100%) in R. annulatus adult ticks with LC50 of 2.60%, whereas the LC50 of pure carvacrol was 4.30%. Carvacrol and CLI were shown to have a significant larvicidal action on both tick species, with LC50s of 0.24 and 0.21% against R. annulatus and 0.27 and 0.23% against R. sanguineus, respectively. Carvacrol and CLI (5%) induced significant repellent activities for 24 h against R. annulatus and R. sanguineus, as evidenced by the rod method and the petri-dish selective area choice method, respectively. High-performance liquid chromatography (HPLC) demonstrated that the CLI form had 3.86 times the permeability of pure carvacrol. Moreover, carvacrol and CLI inhibited acetylcholinesterase activity and decreased glutathione and malonedealdehyde levels in the treated ticks. In conclusion, invasomes significantly improved adulticidal and repellency activities of carvacrol against both tick species.

The deleterious effect of xylene-induced ear edema in rats: Protective role of dexketoprofen trometamol transdermal invasomes via inhibiting the oxidative stress/NF-κB/COX-2 pathway

Pain and inflammation could have a negative impact on a patient's quality of life and performance, causing them to sleep less. Dexketoprofen trometamol (DKT) is a water-soluble, nonselective NSAIDs. Because DKT is quickly eliminated in the urine after oral delivery, its efficacy is limited and must be taken repeatedly throughout the day. The main ambition of this work is to develop and characterize the potential of invasomes to enhance the transdermal transport of DKT to achieve efficient anti-inflammatory and pain management. The optimum formulation (C1) showed the least %RE (53.29 ± 2.68 %), the highest %EE (86.51 ± 1.05 %), and spherical nanosized vesicles (211.9 ± 0.57 nm) with (PDI) of 0.353 ± 0.01 and (ZP) of -19.15 ± 2.45 mV. DKT flux and deposition in stratum corneum, epidermal, and dermal skin layers were significantly augmented by 2.6 and 3.51 folds, respectively, from the optimum invasomal gel formulation (C1-G) compared to DKT conventional gel (DKT-G). The anti-inflammatory activity of C1-G was evaluated using a model of xylene-induced ear edema in rats. Xylene exposure upregulated the ear expression of COX-2 level and MPO activity. Xylene also significantly increased the ear NF-κB p65, TNF-α, IL-Iβ, and MDA levels. Furthermore, xylene induced oxidative stress, as evidenced by a significant decrease in ear GSH and serum TAC levels. These impacts were drastically improved by applying C1-G compared to rats that received DKT-G and plain invasomal gel formulation (plain C1-G). The histopathological findings imparted substantiation to the biochemical and molecular investigations. Thereby, C1-G could be a promising transdermal drug delivery system to improve the anti-inflammatory and pain management of DKT.

Exploring the Synergistic Effect of Bergamot Essential Oil with Spironolactone Loaded Nano-Phytosomes for Treatment of Acne Vulgaris: In Vitro Optimization, In Silico Studies, and Clinical Evaluation

The foremost target of the current work was to formulate and optimize a novel bergamot essential oil (BEO) loaded nano-phytosomes (NPs) and then combine it with spironolactone (SP) in order to clinically compare the efficiency of both formulations against acne vulgaris. The BEO-loaded NPs formulations were fabricated by the thin-film hydration and optimized by 3² factorial design. NPs' assessments were conducted by measuring entrapment efficiency percent (EE%), particle size (PS), polydispersity index (PDI), and zeta potential (ZP). In addition, the selected BEO-NPs formulation was further combined with SP and then examined for morphology employing transmission electron microscopy and three months storage stability. Both BEO-loaded NPs selected formula and its combination with SP (BEO-NPs-SP) were investigated clinically for their effect against acne vulgaris after an appropriate in silico study. The optimum BEO-NPs-SP showed PS of 300.40 ± 22.56 nm, PDI of 0.571 ± 0.16, EE% of 87.89 ± 4.14%, and an acceptable ZP value of -29.7 ± 1.54 mV. Molecular modeling simulations showed the beneficial role of BEO constituents as supportive/connecting platforms for favored anchoring of SP on the Phosphatidylcholine (PC) interface. Clinical studies revealed significant improvement in the therapeutic response of BEO-loaded NPs that were combined with SP over BEO-NPs alone. In conclusion, the results proved the ability to utilize NPs as a successful nanovesicle for topical BEO delivery as well as the superior synergistic effect when combined with SP in combating acne vulgaris.

Nano Methotrexate versus Methotrexate in Targeting Rheumatoid Arthritis

Nanomedicine has emerged as an important approach for targeting RA medication. Rheumatoid arthritis (RA) is a widespread autoimmune disorder marked by multiple inflamed joints. Gold nanoparticles (GNPs) have been demonstrated as efficacious nanocarriers due to their unique characteristics and the relative simplicity of their synthesis in varied sizes; moreover, they have the capability to alleviate several inflammatory markers. The current objective was to combine methotrexate (MTX) with GNPs to overcome MTX restrictions. GNPs were fabricated by a chemical reduction technique, utilizing sodium citrate and tween 20. The MTX-GNPs formulations were characterized in vitro by % entrapment efficiency (%EE), particle size, polydispersity index (PDI) zeta potential, and % release. The MTX-GNPs formulation was administrated as an intra-articular solution, and additionally, incorporated into a Carbopol gel to investigate its anti-arthritic effectiveness and bioavailability in vivo. The results indicated that a %EE of 87.53 ± 1.10%, and a particle size of 60.62 ± 2.41 nm with a PDI of 0.31 ± 0.03, and a zeta potential of −27.80 ± 0.36 mV were optimal. The in vitro release of MTX from the MTX-GNPs formulation demonstrated that the MTX-GNPs formulation’s release was 34.91 ± 1.96% and considerably (p < 0.05) lower than that of free MTX, showing a significant difference in dissolution patterns (p < 0.05). In vivo, MTX-GNPs formulations inhibited IL-6 by 36.52%, ACCP (63.25 %), COMP (28.16%), and RANKL (63.67%), as well as elevated IL-10 by 190.18%. Transdermal MTX-GNPs decreased IL-6 by 22.52%, ACCP (56.63%), COMP (52.64%), and RANKL (79.5%), as well as increased IL-10 by 168.37%. Histological investigation supported these recent findings. Conclusions: Marked improvements in MTX anti-arthritic effects are seen when it is conjugated to GNPs.

Enhancing the Bioavailability and Efficacy of Vismodegib for the Control of Skin Cancer: In Vitro and In Vivo Studies

Skin cancer is the most frequent cancer throughout the world. Vismodegib (VSD) is a hedgehog blocker approved for the prevention and treatment of skin cancer. VSD, however, is poorly bioavailable and has been linked to side effects. This work focused on designing a nano-invasome gel as a vehicle for enhancing the permeation, bioavailability, and efficacy of VSD. Additionally, the combined effect of terpenes and ethanol was studied on the permeation of VSD compared with liposomes. The prepared VSD-loaded invasomes (VLI) formulation included cineole (1%v/v), cholesterol (0.15%w/w), phospholipid (2%w/w), and ethanol (3%v/v) and displayed an entrapment efficiency of 87.73 ± 3.82%, a vesicle size of 188.27 ± 3.25 nm, and a steady-state flux of 9.83 ± 0.11 µg/cm²/h. The VLI formulation was vigorously stirred into a carbopol base before being characterized in vivo to investigate the permeation, bioavailability, and efficacy of VSD. The VLI gel enhanced the dermal permeation of VSD and, as a result, had 3.59 times higher bioavailability with excellent antitumor action as compared to oral VSD. In summary, as an alternative to oral administration for skin cancer treatment, invasomes are efficient carriers for delivering VSD and enhancing its transdermal flux into deep skin layers.