Mixed-Micelle in Situ Gel as a Candidate for Oral Inflammatory Ulcerative Diseases.

The current treatment for oral inflammatory ulcerative diseases has limitations. In situ forming hydrogels have shown great potential to deliver therapeutic substances for drug delivery to the buccal cavity. This study aimed to prepare and characterize lipid- and surfactant-based mixed micelle in situ gel (MIG) and evaluate whether it can offer more favorable properties than the in situ gel for effective treatment of the disease. Dexamethasone was incorporated into the MIGs particles, based on Poloxamer 407 and chitosan. The lower gelation time at 37 ℃ was considered a criterion to select superior formulations among the different lipid- and surfactant-based candidates. Further characterization was performed to evaluate the opted formulations regarding morphology, physical stability, rheology, texture, and release profile. All formulations were thermoresponsive and had a shorter gelation time as the temperature increased. Dexamethasone was released in a highly controlled manner, and morphological evaluation revealed that the mixed micelle in situ gels had spherical nanoparticles. Thixotropic behavior was observed in all MIGs, indicating a prolonged retention time of the formulation after oral administration. This study has shown that among different MIGs, the one with oleic acid is a more promising candidate than the in situ gel and other MIGs for drug delivery to the buccal cavity.

Platelets and platelet-derived vesicles as an innovative cellular and subcellular platform for managing multiple sclerosis.

INTRODUCTION: Multiple sclerosis (MS) is a progressive inflammatory autoimmune disease that involves young individuals. The drug delivery systems now are available for this disease have chronic and non-targeted effects on the patients. Because of the presence of BBB (blood-brain-barrier), their concentration in the CNS (central nervous system) is low. Because of this flaw, it is critical to use innovative active targeted drug delivery methods. RESULT: Platelets are blood cells that circulate freely and play an important role in blood hemostasis. In this review, we emphasize the various roles of activated platelets in the inflammatory condition to recruit other cells to the injured area and limit inflammation. Besides, the activated platelets in the different stages of the MS disease play a significant role in limiting the progression of inflammation in the peripheral area and CNS. DISCUSSION: This evidence indicates that a platelet-based drug delivery system can be an efficient biomimetic candidate for drug targeting to the CNS and limiting the inflammation in the peripheral and central areas for MS therapy.

Vesicles of yeast cell wall-sitagliptin to alleviate neuroinflammation in Alzheimer's disease.

A cell-based drug delivery system based on yeast-cell wall loaded with sitagliptin, a drug with an anti-inflammatory effect, was developed to control neuroinflammation associated with Alzheimer's disease. The optimized nanoparticles had a spherical shape with a negative surface charge, and were shown to be less toxic than the carrier and sitagliptin. Moreover, the nanoparticles caused anti-inflammatory effects against tumor necrosis factor-alpha in mice model of neuroinflammation. The pharmacokinetics study showed the brain concentration of drug in the nanoparticles group was much higher than in the control group. To evaluate the effect of P-glycoprotein on brain entry of sitagliptin, the experiment was repeated with verapamil, as a P-glycoprotein inhibitor. Brain concentration of the nanoparticles group remained approximately unchanged, proving the "Trojan Horse" effect of the developed nanocarriers. The results are promising for using yeast-cell wall as a carrier for targeted delivery to immune cells for the management of inflammation.

Formulation and evaluation of antioxidant and antibacterial activity of a peel-off facial masks moisturizer containing curcumin and Rosa Damascena extract.

BACKGROUND: Acne is a common skin issue that typically occurs during adolescence. It causes long-lasting redness and swelling in the skin. An alternative approach to treating acne could involve using a cosmetic facial mask containing herbal ingredients such as Curcumin and Rosa Damascena extract for its antibacterial properties. AIMS: This study aims to create and try out a peel-off mask gel made from Curcumin and R. Damascena extract. This gel is intended to have the ability to kill bacteria such as Staphylococcus aureus, Escherichia coli, and Propionibacterium acnes and remove dead cells from the skin surface. METHODS: The peel-off mask was made using polyvinyl alcohol (PVA) in 8% and 10% as solidifier. The evaluation of peel-off masks comprises the examination of physiochemical and mechanical aspects. Furthermore, their longevity, effectiveness, and antibacterial properties are also considered. RESULTS: The white color, pleasant smell, and soft texture were the defining features of the peel-off gel mask. The changes in PVA affect the pH level, thickness, and how quickly the peel-off mask dries. The stability test found that the peel-off mask had no significant physical changes when exposed to freezing and thawing. However, there were some differences in color and separation when using the real-time method. A prepared peel-off mask containing 10% PVA and curcumin works best against P. acne. The amount of PVA in the formula affected the physical and chemical qualities, but it did not impact on the antibacterial abilities of the peel-off mask gel. The best formula that gives the best results uses 10% PVA + curcumin. CONCLUSIONS: Using the Curcumin and R. Damascena extract in the creation of the peel-off mask gel ensures its efficacy and safety for skin application.

Recent Biomaterial-Assisted Approaches for Immunotherapeutic Inhibition of Cancer Recurrence.

Biomaterials possess distinctive properties, notably their ability to encapsulate active biological products while providing biocompatible support. The immune system plays a vital role in preventing cancer recurrence, and there is considerable demand for an effective strategy to prevent cancer recurrence, necessitating effective strategies to address this concern. This review elucidates crucial cellular signaling pathways in cancer recurrence. Furthermore, it underscores the potential of biomaterial-based tools in averting or inhibiting cancer recurrence by modulating the immune system. Diverse biomaterials, including hydrogels, particles, films, microneedles, etc., exhibit promising capabilities in mitigating cancer recurrence. These materials are compelling candidates for cancer immunotherapy, offering in situ immunostimulatory activity through transdermal, implantable, and injectable devices. They function by reshaping the tumor microenvironment and impeding tumor growth by reducing immunosuppression. Biomaterials facilitate alterations in biodistribution, release kinetics, and colocalization of immunostimulatory agents, enhancing the safety and efficacy of therapy. Additionally, how the method addresses the limitations of other therapeutic approaches is discussed.

Metformin-loaded nanoerythrosomes: An erythrocyte-based drug delivery system as a therapeutic tool for glioma.

Glioma is an intra-cranial malignancy with the origin of neural stem cells or precursor cells, the most prevalent brain tumor worldwide. Glioblastoma, the fourth-grade glioma, is a common brain tumor whose incidence rate is 5-7 people per 100,000 populations annually. Despite their high mortality rate, all efforts for treatment have yet to achieve any desirable clinical outcome. The Wnt signaling pathway is a conserved pathway among species that seems to be a candidate for cancer therapy by its inhibition. Metformin is a known inhibitor of the Wnt signaling pathway. Its effects on glioma treatment have been observed in cellular, animal, and clinical experiments. Nanoerythrosomes are drug carriers obtained from the cellular membrane of red blood cells in nano size which can offer several characteristics to deliver metformin to brain tumors. They are good at loading and carrying hydrophilic drugs, they can protect metformin from its metabolizing enzymes, which are present in the blood-brain barrier, and they can extend the period of metformin presence in circulation. In this study, nanoerythrosomes were prepared by using the hypotonic buffer. They had particle sizes in the range of 97.1 ± 34.2 nm, and their loading efficiency and loading capacity were 72.6% and 1.66%, respectively. Nanoerythrosomes could reserve metformin in their structure for a long time, and only 50% of metformin was released after 30 h. Moreover, they released metformin at a low and approximately constant rate. Besides, nanoerythrosomes could tolerate various kinds of stress and maintain most of the drug in their structure. Altogether, nanoerythrosome can be a suitable drug delivery system to deliver therapeutic amounts of metformin to various tissues.

Ultrasound-responsive hyaluronic acid hydrogel of hydrocortisone to treat osteoarthritis.

One of the practical ways to manage the disease flares of arthritis is using an intra-articular depot formulation of glucocorticoids. Hydrogels, as controllable drug delivery systems, are hydrophilic polymers with distinctive properties, such as remarkable water capacity and biocompatibility. This study aimed to design an injectable thermo-ultrasound-triggered drug carrier based on Pluronic® F-127, hyaluronic acid, and gelatin. The in situ hydrogel loaded by hydrocortison was developed and D-optimal design was used to formulate the process. The optimized hydrogel was combined with four different surfactants to better regulate the release rate. In situ gels composed of the hydrocortisone-loaded hydrogel and hydrocortisone-loaded mixed-micelle hydrogel were characterized. The hydrocortisone-loaded hydrogel and selected hydrocortisone-loaded mixed-micelle hydrogel showed a spherical shape and were nano-sized with a unique thermo-responsive nature able to prolong drug release. The ultrasound-triggered release study showed that drug release was time-dependent. By inducing osteoarthritis in a rat model, behavioral tests and histopathological analyses were carried out on the hydrocortisone-loaded hydrogel and a particular hydrocortisone-loaded mixed-micelle hydrogel. In vivo results showed that the selected hydrocortisone-loaded mixed-micelle hydrogel improved the status of the disease. Results highlighted the potential of ultrasound-responsive in situ-forming hydrogels as hopeful formulas for efficient treatment of arthritis.

Preparation and evaluation of niosomal chitosan-based in situ gel formulation for direct nose-to-brain methotrexate delivery.

Achieving effective treatments for various brain disorders due to the blood-brain barrier existence and the brain's complex structure has become a challenging goal. To overcome these challenges, one of the non-invasive strategies aimed at direct brain drug delivery is the use of the intranasal route. Novel drug delivery systems can be used to overcome the limitations in this administration route. This study suggested niosomal methotrexate (MTX) in situ gel formulation, which could be a suitable candidate for drug delivery to the brain. Here, niosomal MTX was prepared by a modified reverse-phase evaporation method, optimized with the aid of the design expert® software, and characterized. Optimum niosomal MTX with particle size, zeta potential, and entrapment efficiency (EE%), equal to 130.5 nm, -38.5 mV, and 91.39 %, respectively, were added into the temperature-sensitive in situ gel formulation composed of chitosan and Poloxamer 407. This study demonstrates that the simultaneous use of niosome and in situ gel formulations causes long-term persistence in the nasal cavity and helps us to have a more controlled drug release system with higher brain concentration, lower plasma concentration, higher Kp, and lower side effects compared to the free drug (MTX solution), MTX-gel (MTX-loaded in situ gel), and niosomal MTX formulations.

A cell-mimicking platelet-based drug delivery system as a potential carrier of dimethyl fumarate for multiple sclerosis.

Dimethyl fumarate (DMF), is one of the lately approved therapeutic agents for the multiple sclerosis (MS) treatment. Despite the beneficial effects, DMF also suffers from low penetration into brain. In this study, we designed a precise drug delivery system of DMF to cross BBB for MS management. The novelty of this study is developing a cell based biomimetic vehicle for specific drug delivery to the inflamed area in peripheral and CNS. DMF-loaded platelet-based nanoparticle as a cell-based drug delivery system was developed and compared with chitosan nanogel and platelet membrane coated chitosan nanogel. Prepared nanoparticles were characterized for particle size, morphology, release characteristics, and drug loading parameters. In the optimum condition, all nanoparticles were prepared in desirable nano-size and showed appropriate loading parameters. The neuropharmacokinetic evaluation was performed by determining the brain uptake of DMF, and brain uptake clearance for passage from BBB. Results from in vivo study demonstrated that the brain concentration of nanoparticles was higher than the free drug solution. The brain uptake clearance and AUC (0-∞) brain of DMF-loaded platelet nanoparticle were higher than platelet membrane coated chitosan nanogel and chitosan nanogel. The results demonstrated that platelet nanoparticles can be proposed as a potential biomimetic carrier for MS management.

A comparison of models for the analysis of the kinetics of drug release from PLGA-based nanoparticles.

PURPOSE: Poly (lactic-co-glycolic acid) has received much academic attention for developing nanotherapeutics and FDA has approved it for several applications. An important parameter that dictates the bioavailability and hence the biological effect of the drug is drug release from its delivering system. This study offers a comparative mathematical analysis of drug release from Poly (lactic-co-glycolic acid)-based nanoparticles to suggest a general model explaining multi-mechanistic release they provide. METHODS: Eight release models, zero order, first order, Higuchi, Hixson-Crowell, the square root of mass, the three-second root of mass, Weibull and Korsmeyer-Peppas, as well as the second degree polynomial equation were applied to 60 data sets. The models analysed regarding several types of errors, regression parameters and average Akaike information criterion. RESULTS AND DISCUSSION: Most of the data sets present the highest R2, the lowest overall error and AIC for the Weibull model. Weibull model with the mean AIC = -36.37 and mean OE = 7.24 and the highest NE less than 5, 10, 15 and 20 % in most of the cases best fits the release data from various PLGA-based drug delivery systems that are studied. Weibull model seems to show enough flexibility to describe various release patterns PLGA provides.

Statins as the Controlling Agents for Non-Hodgkin's Lymphomas via Increasing the Casein Kinase 2 Interacting Protein-1: A Hypothesis.

BACKGROUND: Non-Hodgkin's lymphomas (NHL), derived from B- or T-cell, consist of a heterogeneous group of malignant lymphoproliferative disorders. Knockdown of Casein kinase 2 interacting protein-1 (CKIP-1) in NHL promoted cell proliferation and inhibited apoptosis via enhancing phosphorylated Protein Kinase B (PKB or AKT) expression. Statins are the class of drugs that inhibit the ratelimiting step of the mevalonate pathway, which is essential for the biosynthesis of various compounds, including cholesterol. Also, statins have anticancer properties being mediated by different mechanisms. METHODS: A search on databases like Scopus and PubMed with keywords such as statin and non- Hodgkin's lymphomas was performed and Kyoto Encyclopedia of Genes and Genomes (KEGG) website was used to evaluate and reconfirm the involved cellular signaling pathway. RESULTS: CKIP-1 is involved in the regulation of cell proliferation and apoptosis while plays an important role in many cancers. We can hypothesize that statins may increase the expression levels of CKIP-1 which could contribute to the reductions in phospho-AKT level. Hence, they may ameliorate the NHL patients via suppressing AKT phosphorylation and increasing CKIP- expression. CONCLUSION: Present review confirms the positive effect of statins on NHL by increasing CKIP-1 and reducing cell proliferation, subsequently.

Inflammation: A bridge between diabetes and COVID-19, and possible management with sitagliptin.

Patients with SARS-CoV-2 infections experience lymphopenia and inflammatory cytokine storms in the severe stage of the disease, leading to multi-organ damage. The exact pattern of immune system changes and their condition during the disease process is unclear. The available knowledge has indicated that the NF-kappa-B pathway, which is induced by several mediators, has a significant role in cytokine storm through the various mechanisms. Therefore, identifying the state of the immune cells and the dominant mechanisms for the production of cytokines incorporated in the cytokine storm can be a critical step in the therapeutic approach. On the other hand, some studies identified a higher risk for diabetic patients. Diabetes mellitus exhibits a close association with inflammation and increases the chance of developing COVID-19. Patients with diabetes mellitus have shown to have more virus entry, impaired immunity response, less viral elimination, and dysregulated inflammatory cytokines. The parallel analysis of COVID-19 and diabetes mellitus pathogenesis has proposed that the control of the inflammation through the interfering with the critical points of major signaling pathways may provide the new therapeutic approaches. In recent years, the role of Dipeptidyl Peptidase 4 (DPP4) in chronic inflammation has been proved. Numerous immune cells express the DPP4 protein. DPP4 regulates antibody production, cytokine secretion, and immunoglobulin class switching. DPP4 inhibitors like sitagliptin reduce inflammation intensity in different states. Following the accumulating data, we hypothesize that sitagliptin might reduce COVID-19 severity. Sitagliptin, an available DPP4 inhibitor drug, showed multidimensional anti-inflammatory effects among diabetic patients. It reduces the inflammation mostly by affecting on NF-kappa-B signaling pathway. Under the fact that inflammatory mediators are active in individuals with COVID-19, blocking the predominant pathway could be helpful.

Apolipoprotein J in Alzheimer's Disease: Shedding Light on Its Role with Cell Signaling Pathway Perspective and Possible Therapeutic Approaches.

Apolipoprotein J (ApoJ), or clusterin, is one of the main apolipoproteins in the brain. It is synthesized and released from astrocytes in a healthy brain, and its expression increases in neurodegenerative disorders. Genetic evidence has suggested an association between ApoJ polymorphism and the risk of Alzheimer's disease (AD)-it is now considered the third main genetic risk factor for late-onset AD. However, the role of ApoJ overexpression in the state of disorder, toxicity, or protection is not yet clear. Since ApoJ plays different roles in AD, we review the function of ApoJ using different cell signaling pathways in AD and outline its paradoxical roles in AD. ApoJ helps in amyloid-beta (Aß) clearance. Vice versa, ApoJ gene knock-out causes fibrillary Aß reduction and prevents Aß-induced neuron cell death. Understanding ApoJ, through various cellular signaling pathways, creates a new perspective on AD's cellular principles. The overall message is that ApoJ can be a valuable tool in controlling AD.

A mechanistic investigation on methotrexate-loaded chitosan-based hydrogel nanoparticles intended for CNS drug delivery: Trojan horse effect or not?

Chitosan-based hydrogel nanoparticles provide a higher brain concentration of methotrexate (MTX) following IV administration in comparison with the drug's simple solution. The present study investigates the mechanism of this phenomenon, focusing on the possible role of P-gp. A previously developed MTX containing chitosan nanogel was fabricated and characterised. Then 48 rats were divided into four groups: two receiving nanogels and two receiving solution of MTX, while 1 of each two had received a verapamil dose 30 min before MTX. Then, rats were sacrificed in four time points in triplicate, and MTX concentration in their plasma and brains were quantified and were compared statistically. Following IV injection, spherical nanogels with a mean diameter of <200 nm, zeta potential of 22.8 ±â€¯6.55 mv, Loading efficiency of 72.03 ±â€¯0.85, and loading capacity of 1.41 ±â€¯0.02 produce a significantly higher brain concentration compared with the simple solution. Furthermore, those receiving verapamil presented a higher brain concentration. It seems that in the short term after drug administration (<1 h) nanogels facilitate MTX passage by providing a higher concentration of drug in contact with BBB, but in a more extended period nanogels pass the BBB and release their content beyond that.

A Hopeful Prospect of Riociguat as a Soluble Guanylate Cyclase Stimulator for Management of Pressure Ulcers.

BACKGROUND: Pressure ulcer remains as a common problem, especially developed in disabled patients and hence, subjected to continuous pressure for prolonged periods of time. Most of the studies investigating the preventive and therapeutic approaches have focused on wound cleansing, dressing and supportive strategies, as well as pharmacological therapy including zinc sulphate, vitamin A or phenytoin. Despite such efforts, pressure ulcer continues to impair the life quality and expectancy. Thus involving in the paradigm shift in biomedical studies, the recent ones focus on biological signaling pathways involving nitric oxide (NO)- soluble guanylatecyclase (sGC)- cyclic guanosine monophosphate (cGMP) contributing in vasodilation, reperfusion and oxygen delivery. METHODS: Literatures review focusing on NO/sGC/cGMP pathway was performed as well as seeking themolecular biology aspects inKyoto Encyclopedia of genes and genomes (KEGG). RESULTS: NO is an important signaling molecule activating sGC and cGMP production, which is a mediator of vasodilation and platelet inhibition. Considering the subject, it could be hypothesized that the application of sGC stimulators and activators is a very curious strategy for pressure ulcer healing. It is well known that pressure and shear forces usually produce the blood vessel obstruction, inducing ischemia and tissue necrosis and in pathologic states, damaged endothelium leads to a reduced synthesis of NO and inadequate oxygen supply contributing to delayed wound healing. Riociguat is the first FDA approved agent of new class of sGC stimulators, involving in activation of sGC both in presence and absence of NO. CONCLUSION: The findings of this review confirm that Riociguat could start a new therapeutic approach for pressure ulcer treatment even with dysfunctional endothelium.

Controlled-release in-situ gel forming formulation of tramadol containing chitosan-based pro-nanogels.

Chronic pain is one of the most prevalent health problems worldwide. Tramadol is a synthetic semi-opioid analgesic, interacting with serotonergic, adrenergic and opioid receptors to reduce the pain but its short half-life in vivo may reduce patient compliance in case of chronic pains. To overcome this problem, novel drug delivery systems have been investigated. This study focuses on a chitosan based thermoresponsive in-situ gel forming formulation intended to subcutaneous injection. To evaluate further drug release, a reversed phase high performance liquid chromatography method was developed. Then two formulations (with and without TPP) were optimized by D-optimal plan using Design-Expert statistical software and were characterized in terms of morphology, release phenomenon, texture, swelling and stability as well as in vivo response. AFM images show approximately spherical nanocavities in the homogenous TPP containing gel structure, which explain the different patterns of drug release between the two formulations. This implies that changing TPP concentration can control formation of these cavities and hence drug release rate and kinetics. Not present in the sol state, nanostructures lead to emerge of a new concept: pro-nanogels. Finally, the formulations with proper texture qualities, stability and rapid sol-gel transition in vivo could be a candidate for controlled release of therapeutic agents following subcutaneous injection.

A novel approach to the application of hexagonal mesoporous silica in solid-phase extraction of drugs.

Mesoporous silica with hexagonal type structure containing amine functional group was introduced. Firstly, aminopropyl hexagonal mesoporous silica was synthetized in a co-condensation process, via templating route of n-dodecylamine. Then synthesized mesoporous material were characterized, and FT-IR spectrum confirmed the presence of amine group and CHN analysis determined the amount of organic layer. The high surface area (750 m2/g) was determined by applying nitrogen adsorption-desorption technique. The morphology was examined by scanning electron microscopy which proved hexagonal structure. The crystallinity of mesoporous material was observed in XRD pattern of this material. According to previous background of such material in adsorbing drug, herein, the efficiency of this material in adsorbing of 5-fluorouracil was evaluated through solid phase extraction method in aqueous and plasma media with high performance liquid chromatography. The extraction efficiency was evaluated for drug concentrations of 500-2000 ng/ml by means of 5-20 mg/ml hexagonal mesoporous silica in both media. The results showed good to excellent recovery rate of in both aqueous and plasma medium which confirmed that the aminopropyl functionalized hexagonal mesoporous silica could be considered as promising device for drug bioanalysis.

Traditional neurotherapeutics approach intended for direct nose to brain delivery.

ETHNOPHARMACOLOGICAL RELEVANCE: Nasal delivery systems have a significant role in Persian traditional medicine. Most of them were utilized for central nervous system (CNS)-related disorders. In modern medicine, nasal drug delivery systems for brain delivery are highly regarded. AIM OF THE STUDY: Despite recent advances in drug delivery to the (CNS), delivery of therapeutics to the brain remains a major challenge because of the blood brain barrier (BBB). There are several mechanisms which regulate the drug transfer across the BBB. Local administration methods of therapeutic agents are often associated with adverse events, while the intranasal pathway has been suggested as a non-invasive alternative route to deliver drugs to the brain. This route can bypass the BBB and deliver drug molecules directly to the CNS. There are different nasal formulations have been addressed in Persian traditional pharmacopeias. The present review attempt to explore the famous and practical Qarabadin to find ancient nasal dosage forms. MATERIALS AND METHODS: With an explore on traditional herbs in google scholar, scopus and science direct, we have found some original and review articles which have demonstrated our findings on the use of traditional herbs for CNS disorders. Four encyclopedia of multi-component formulations, including Qarabadin Salehi (1766), Qarabadin kabir (1781),Qarabadin Ghaderi (18th century), and Qarabadin Azam (1853), were searched for nasal formulations having CNS-related indications. Formulations were categorized based on dosage forms, and also, diseases which they were suggested for. While the names of illnesses were in ancient terminology of Traditional Medicine, they were translated to modern medical terminology by comparing their definitions, signs, and symptoms from two medical systems. Typical samples of each dosage form have been mentioned with details like amount of ingredients, scientific names of plants, and considerations pertaining to preparation or usage. RESULTS: Among all traditional nasal formulations, seven types were found that is used for sicknesses relating to CNS including Saoot, Nafookh, Atoos, Nashoogh, Shamoom, Lakhlakheh, and Bakhoor. CONCLUSIONS: The findings of this study reveal the physicochemical characteristics of each formulation, route of administration, and type of disease which they are suitable and also present some famous formulations.

Chitosan-based hydrogel nanoparticle amazing behaviors during transmission electron microscopy.

Nanogels are potential polymeric nanoparticulate systems of interest in biomedical applications, including time-controlled drug delivery and active drug targeting. With the aim of preparation of a nanocarrier for brain enhancement of the BBB-restricted hydrophilic drugs, nanogel loaded with the antineoplasm drug, methotrexate was prepared using an ionic gelation process. During transmission electron microscopy imaging, hydrogel nanoparticles were found as a polymeric matrix containing aqueous vacuoles. With emitting the electrons and increase in energy intake, the vacuoles were interconnected and form a large one. Then the volume of the new vacuole grew and subsequently decreased over the time. The behavior was in good agreement with drug release kinetic findings. These results provide important guidelines for designing top-down fabricated hydrogel nanoparticles with specific drug release kinetic mechanisms for enhancing and predicting the drug delivery efficacy.

A pharmacokinetic overview of nanotechnology-based drug delivery systems: an ADME-oriented approach.

With the extensive progress in nanotechnology-based drug delivery systems, pharmacokinetic evaluations have gained much attention from researchers as a central part of the study of these systems. Because the fulfillment of any therapeutic goal(s) by a novel drug delivery system requires that the absorption, distribution, metabolism, and excretion (ADME) be considered from the early stages of the system design to the final clinical evaluations, extensive knowledge of the pharmacokinetic aspects related to ADME is a crucial part of research in this field. The main objectives of the nanotechnology-based drug delivery systems from a pharmacokinetic viewpoint are (1) an improved drug-release profile in vivo, (2) enhanced drug absorption, (3) site-directed drug distribution, (4) a modified drug metabolism pattern, (5) prolonged drug residence time in body (e.g., in blood circulation), and (6) delayed and/or decreased renal excretion of the drug. Accordingly, the purpose of the current review is to present an insightful summary of pharmacokinetic analyses of nanotechnology-based drug delivery systems along with a critical review of recent findings.