Delivery Of Agents Research Articles

Anti-TNFR2 Antibody-Conjugated PLGA Nanoparticles for Targeted Delivery of Adriamycin in Mouse Colon Cancer.

High levels of tumor necrosis factor receptor type II (TNFR2) are preferentially expressed by immunosuppressive CD4+Foxp3+ regulatory T cells (Tregs), especially those present in the tumor microenvironment, as initially reported by us. There is compelling evidence that targeting TNFR2 markedly enhances antitumor immune responses. Furthermore, a broad spectrum of human cancers also expresses TNFR2, while its expression by normal tissue is very limited. We thus hypothesized that TNFR2 may be harnessed for tumor-targeted delivery of chemotherapeutic agents. In this study, we performed a proof-of-concept study by constructing a TNFR2-targeted PEGylated poly(dl-lactic-co-glycolic acid) (PLGA-PEG) nanodrug delivery system [designated as TNFR2-PLGA-ADR (Adriamycin)]. The results of invitro study showed that this TNFR2-targeted delivery system had the properties in cellular binding and cytotoxicity toward mouse colon cancer cells. Further, upon intravenous injection, TNFR2-PLGA-ADR could efficiently accumulate in MC38 and CT26 mouse colon tumor tissues and preferentially bind with tumor-infiltrating Tregs. Compared with ADR and ISO-PLGA-ADR, the invivo antitumor effect of TNFR2-PLGA-ADR was markedly enhanced, which was associated with a decrease of TNFR2+ Tregs and an increase of IFNγ+CD8+ cytotoxic T lymphocytes in the tumor tissue. Therefore, our results clearly show that targeting TNFR2 is a promising strategy for designing tumor-specific chemoimmunotherapeutic agent delivery system.

Curcumin-shellac nanoparticle-loaded GelMA/SilMA hydrogel for colorectal cancer therapy

In this study, a novel approach was employed to develop a therapeutic system for colorectal cancer treatment. Specifically, a GelMA/SilMA hydrogel loaded with curcumin-shellac nanoparticles (Cur@Lac NPs) was created. A microfluidic swirl mixer was utilized to formulate stable Cur@Lac NPs, ensuring their consistent and effective encapsulation. The pH-specific release of curcumin from the NPs demonstrated their potential for colon cancer treatment. By carefully regulating the ratio of GelMA (gelatin methacrylate) and SilMA (silk fibroin methacrylate), a GelMA/SilMA dual network hydrogel was generated, offering controlled release and degradation capabilities. The incorporation of SilMA notably enhanced the mechanical properties of the dual network matrix, improving compression resistance and mitigating deformation. This mechanical improvement is crucial for maintaining the structural integrity of the hydrogel during in vivo applications. In comparison to the direct incubation of curcumin, the strategy of encapsulating curcumin into NPs and embedding them within the GelMA/SilMA hydrogel resulted in more controlled release mechanisms. This controlled release was achieved through the disintegration of the NPs and the swelling and degradation of the hydrogel matrix. The encapsulating strategy also demonstrated enhanced cellular uptake of curcumin, leveraging the advantages of both NPs and in-situ hydrogel injection. This combination ensures a more efficient and sustained delivery of the therapeutic agent directly to the tumor site. Overall, this approach holds significant promise as a smart drug delivery system, potentially improving the efficacy of colorectal cancer treatments by providing targeted, controlled, and sustained drug release with enhanced mechanical stability and biocompatibility.

Copper toxicity and deficiency: the vicious cycle at the core of protein aggregation in ALS.

The pathophysiology of ALS involves many signs of a disruption in copper homeostasis, with both excess free levels and functional deficiency likely occurring simultaneously. This is crucial, as many important physiological functions are performed by cuproenzymes. While it is unsurprising that many ALS symptoms are related to signs of copper deficiency, resulting in vascular, antioxidant system and mitochondrial oxidative respiration deficiencies, there are also signs of copper toxicity such as ROS generation and enhanced protein aggregation. We discuss how copper also plays a key role in proteostasis and interacts either directly or indirectly with many of the key aggregate-prone proteins implicated in ALS, such as TDP-43, C9ORF72, SOD1 and FUS as well as the effect of their aggregation on copper homeostasis. We suggest that loss of cuproprotein function is at the core of ALS pathology, a condition that is driven by a combination of unbound copper and ROS that can either initiate and/or accelerate protein aggregation. This could trigger a positive feedback cycle whereby protein aggregates trigger the aggregation of other proteins in a chain reaction that eventually captures elements of the proteostatic mechanisms in place to counteract them. The end result is an abundance of aggregated non-functional cuproproteins and chaperones alongside depleted intracellular copper stores, resulting in a general lack of cuproenzyme function. We then discuss the possible aetiology of ALS and illustrate how strong risk factors including environmental toxins such as BMAA and heavy metals can functionally behave to promote protein aggregation and disturb copper metabolism that likely drives this vicious cycle in sporadic ALS. From this synthesis, we propose restoration of copper balance using copper delivery agents in combination with chaperones/chaperone mimetics, perhaps in conjunction with the neuroprotective amino acid serine, as a promising strategy in the treatment of this incurable disease.

Antimalarial Delivery with a Ferritin-Based Protein Cage: A Step toward Developing Smart Therapeutics against Malaria.

Over the past two decades, the utilization of protein cages has witnessed exponential growth driven by their extensive applications in biotechnology and therapeutics. In the context of the recent Covid-19 pandemic, protein-cage-based scaffolds played a pivotal role in vaccine development. Beyond vaccines, these protein cages have proven valuable in diverse drug delivery applications thanks to their distinctive architecture and structural stability. Among the various types of protein cages, ferritin-based cages have taken the lead in drug delivery applications. This is primarily attributed to their ease of production, exceptional thermal stability, and nontoxic nature. While ferritin-based cages are commonly employed in anticancer drug delivery and contrast agent delivery, their efficacy in malarial drug delivery had not been explored until this study. In this investigation, several antimalarial drugs were encapsulated within horse spleen ferritin, and the binding and loading processes were validated through both experimental and computational techniques. The data unequivocally demonstrate the facile incorporation of antimalarial drugs into ferritin without disrupting its three-dimensional structure. Computational docking and molecular dynamics simulations were employed to pinpoint the precise location of the drug binding site within ferritin. Subsequent efficacy testing on Plasmodium revealed that the developed nanoconjugate, comprising the drug-ferritin conjugate, exhibited significant effectiveness in eradicating the parasite. In conclusion, the findings strongly indicate that ferritin-based carrier systems hold tremendous promise for the future of antimalarial drug delivery, offering high selectivity and limited side effects.

Evaluation of sodium borocaptate (BSH) and boronophenylalanine (BPA) as boron delivery agents for neutron capture therapy (NCT) of cancer: an update and a guide for the future clinical evaluation of new boron delivery agents for NCT.

Boron neutron capture therapy (BNCT) is a cancer treatment modality based on the nuclear capture and fission reactions that occur when boron-10, a stable isotope, is irradiated with neutrons of the appropriate energy to produce boron-11 in an unstable form, which undergoes instantaneous nuclear fission to produce high-energy, tumoricidal alpha particles. The primary purpose of this review is to provide an update on the first drug used clinically, sodium borocaptate (BSH), by the Japanese neurosurgeon Hiroshi Hatanaka to treat patients with brain tumors and the second drug, boronophenylalanine (BPA), which first was used clinically by the Japanese dermatologist Yutaka Mishima to treat patients with cutaneous melanomas. Subsequently, BPA has become the primary drug used as a boron delivery agent to treat patients with several types of cancers, specifically brain tumors and recurrent tumors of the head and neck region. The focus of this review will be on the initial studies that were carried out to define the pharmacokinetics and pharmacodynamics of BSH and BPA and their biodistribution in tumor and normal tissues following administration to patients with high-grade gliomas and their subsequent clinical use to treat patients with high-grade gliomas. First, we will summarize the studies that were carried out in Japan with BSH and subsequently at our own institution, The Ohio State University, and those of several other groups. Second, we will describe studies carried out in Japan with BPA and then in the United States that have led to its use as the primary drug that is being used clinically for BNCT. Third, although there have been intense efforts to develop new and better boron delivery agents for BNCT, none of these have yet been evaluated clinically. The present report will provide a guide to the future clinical evaluation of new boron delivery agents prior to their clinical use for BNCT.

Formation of Zwitterionic and Self-Healable Hydrogels via Amino-yne Click Chemistry for Development of Cellular Scaffold and Tumor Spheroid Phantom for MRI.

In situ-forming biocompatible hydrogels have great potential in various medical applications. Here, we introduce a pH-responsive, self-healable, and biocompatible hydrogel for cell scaffolds and the development of a tumor spheroid phantom for magnetic resonance imaging. The hydrogel (pMAD) was synthesized via amino-yne click chemistry between poly(2-methacryloyloxyethyl phosphorylcholine-co-2-aminoethylmethacrylamide) and dialkyne polyethylene glycol. Rheology analysis, compressive mechanical testing, and gravimetric analysis were employed to investigate the gelation time, mechanical properties, equilibrium swelling, and degradability of pMAD hydrogels. The reversible enamine and imine bond mechanisms leading to the sol-to-gel transition in acidic conditions (pH ≤ 5) were observed. The pMAD hydrogel demonstrated potential as a cellular scaffold, exhibiting high viability and NIH-3T3 fibroblast cell encapsulation under mild conditions (37 °C, pH 7.4). Additionally, the pMAD hydrogel also demonstrated the capability for in vitro magnetic resonance imaging of glioblastoma tumor spheroids based on the chemical exchange saturation transfer effect. Given its advantages, the pMAD hydrogel emerges as a promising material for diverse biomedical applications, including cell carriers, bioimaging, and therapeutic agent delivery.

Affimer reagents enable targeted delivery of therapeutic agents and RNA via virus-like particles

Monoclonal antibodies have revolutionized therapies, but non-immunoglobulin scaffolds are becoming compelling alternatives owing to their adaptability. Their ability to be labeled with imaging or cytotoxic compounds and to create multimeric proteins is an attractive strategy for therapeutics. Focusing on HER2, a frequently overexpressed receptor in breast cancer, this study addresses some limitations of conventional targeting moieties by harnessing the potential of these scaffolds. HER2-binding Affimers were isolated and characterized, demonstrating potency as binding reagents and efficient internalization by HER2-overexpressing cells. Affimers conjugated with cytotoxic agent achieved dose-dependent reductions in cell viability within HER2-overexpressing cell lines. Bispecific Affimers, targeting HER2 and virus-like particles, facilitated efficient internalization of virus-like particles carrying enhanced green fluorescent protein (eGFP)-encoding RNA, leading to protein expression. Anti-HER2 affibody or designed ankyrin repeat protein (DARPin) fusion constructs with the anti-VLP Affimer further underscore the adaptability of this approach. This study demonstrates the versatility of scaffolds for precise delivery of cargos into cells, advancing biotechnology and therapeutic research.

Fabrication and characterization of an electrospun chitosan-based nanofibrous scaffold coated with hyaluronic acid, resveratrol and adipose derived stem cell for wound healing application

Nano-delivery systems represent an astoundingly approach to the controlled delivery of therapeutic agents to promote wound regeneration. Chitosan (CS) and hyaluronic acid (HA), two oppositely charged polysaccharides, hold great promise for tissue engineering applications. In this study, we developed a polyelectrolyte complex by electrospinning CS and subsequent coating by HA, resveratrol (RS) and adipose derived stem cell (AD-MSC). The physicochemical properties of the developed nanofibrous mats were investigated. The CS/HA/RS scaffold with AD-MSC was used as a wound dressings in male rat skin wound model. Human dermal fibroblasts showed over 80% viability on the CS/HA/RS scaffold and also all scaffolds demonstrated cytocompatibility with fibroblasts. The coated nanofibers presented controlled release of HA and RS for up to 72 hours. The in vivo results revealed that CS/HA/RS with AD-MSC had a profound effect on the healing progress by augmenting wound tissue granulation and promoting wound proliferation and re-epithelialization. Thus, the current study reveals that the electrospun CS/HA/RS with AD-MSC scaffold could be proposed as an appropriate wound dressing in the in vivo wound healing.

Tumor Redox‐Responsive Minimalist B/Fe Nano‐Chains for Chemodynamically Enhanced Ferroptosis and Synergistic Boron Neutron Capture Therapy

AbstractBoron neutron capture therapy (BNCT) as a binary targeted particle radiotherapy strategy has shown potent anti‐cancer potential. However, biological barriers and restricted blood supply pose challenges in achieving adequate boron concentration within deep‐seated tumor lesions. BNCT with other anti‐cancer therapies, such as X‐ray radiotherapy and photothermal therapy, is devised to address the limitations of BNCT efficiency. However, the potential risk of organ‐accumulating toxicity and treatment complexity of dual exogenous activation hinders its development. To address this problem, newly redox‐responsive boron nano‐chains (RBNC) are reported that combine BNCT and endogenous chemodynamic therapy (CDT)‐enhanced ferroptosis. RBNC specifically activates nanoparticle size conversion (large‐to‐small) in response to GSH/H2O2 in the tumor microenvironment, releasing boron delivery agents boron quantum dots (BQD) and Fe3+. RBNC exhibits negligible systemic toxicity while demonstrating high boron accumulation at tumor. Meanwhile, the introduction of Fe3+ not only produces ·OH through reaction with H2O2, but also depletes GSH and reduces GPX4 activity in tumors, resulting in amplified intracellular oxidative stress and chemodynamically enhanced ferroptosis. Thus, the work provides a strategy to solve the problem of insufficient boron concentration and poor targeting of boron delivery agents and fill the gaps of BNCT combined with CDT and ferroptosis.

Prostate tissue ablation and drug delivery by an image-guided injectable ionic liquid in ex vivo and in vivo models.

Benign prostatic hyperplasia and prostate cancer are often associated with lower urinary tract symptoms, which can severely affect patient quality of life. To address this challenge, we developed and optimized an injectable compound, prostate ablation and drug delivery agent (PADA), for percutaneous prostate tissue ablation and concurrently delivered therapeutic agents. PADA is an ionic liquid composed of choline and geranic acid mixed with anticancer therapeutics and a contrast agent. The PADA formulation was optimized for mechanical properties compatible with hand injection, diffusion capability, cytotoxicity against prostate cells, and visibility of an x-ray contrast agent. PADA also exhibited antibacterial properties against highly resistant clinically isolated bacteria in vitro. Ultrasound-guided injection, dispersion of PADA in the tissue, and tissue ablation were tested ex vivo in healthy porcine, canine, and human prostates and in freshly resected human tumors. In vivo testing was conducted in a murine subcutaneous tumor model and in the canine prostate. In all models, PADA decreased the number of viable cells in the region of dispersion and supported the delivery of nivolumab throughout a portion of the tissue. In canine survival experiments, there were no adverse events and no impact on urination. The injection approach was easy to perform under ultrasound guidance and produced a localized effect with a favorable safety profile. These findings suggest that PADA is a promising therapeutic prostate ablation strategy to treat lower urinary tract symptoms.

Fabrication and Characterization of Electrospun Ocimum sanctum and Curcumin-Loaded Nanofiber Membrane for the Management of Periodontal Disease: An In Vitro Study.

Background Periodontal disease is a chronic inflammatory condition that gradually deteriorates the supportive tissues of teeth, eventually leading to tooth loss. Mechanical debridement stands as the gold standard method for treating periodontitis. However, antimicrobial therapy is recommended for optimal results when used alongside mechanical debridement. Numerous studies have investigated local drug delivery as an adjunct to mechanical debridement of affected tooth surfaces. Ocimum sanctum exhibits anti-inflammatory, antioxidant, and antimicrobial properties. Similarly, curcumin, as documented in the literature, demonstrates a broad spectrum of anti-inflammatory and antimicrobial effects. Electrospinning has demonstrated itself to be a highly effective method for fabricating drug-loaded fibers. Electrospun nanofibers containing Ocimum sanctum and curcumin are expected to exhibit greater efficacy due to their increased surface area, facilitating the dispersion of larger quantities of drugs, and their ability to control drug release when employed as a local drug delivery system. This study aims to fabricate and characterize the properties of nanofiber membranes loaded with Ocimum sanctum and curcumin using the electrospinning technique. Methods About 50 mg each of Ocimum sanctum and curcumin were blended with 15% polyvinyl alcohol and 2% chitosan polymer in a 4:1 ratio and left to stir overnight. A 10 mL syringe was filled with this solution, and an 18 G blunt-end needle charged at 15.9 kV was used for extrusion. Continuous fibers were collected onto a collector plate positioned 12 cm from the center of the needle tip, at a flow rate of 0.005 mL/min. The morphology of the fabricated membrane was assessed through scanning electron microscopy (SEM), the strength of the material was assessed through tensile strength analysis using INSTRON, an Electropuls E3000 Universal Testing Machine(INSTRON, Norwood, MA), and the drug release pattern was analyzed using Jasco V-730 UV-visible spectrophotometer(Jasco, Easton, MD). Results The morphology of this nanofiber showed a random distribution of fibers with no bead formation. The average diameter of the membrane was 383±102 nm, and the tensile strength of this material was 1.87 MPa. The drug release pattern showed an initial burst release of Ocimum sanctum, followed by a controlled release in subsequent hours. However, curcumin showed very little drug release because of its solubility. Conclusion In summary, the Ocimum sanctum and curcumin-loaded nanofibers exhibited robust tensile strength, a controlled drug release profile, and uniform drug distribution within the nanofiber membrane. Consequently, it can be concluded that curcumin nanofibers and electrospun Ocimum sanctum serve as valuable agents for local drug delivery in the treatment of periodontitis.

Design and characterization of Glypican-3 targeted liposomes with cantharidin encapsulation for hepatocellular carcinoma treatment

Targeted delivery of chemotherapeutic agents to the cancerous cells is of fundamental importance and the key step of the targeted delivery system design is to choice a specific receptor. Glypican-3 (GPC3) is a known cell membrane-associated oncofetal proteoglycan that is specifically up-regulated in the fast-growing hepatocarcinoma cells but rarely expressed in the normal healthy liver. Therefore, GPC3 may be a perfect targeting receptor for delivery treatment of hepatocellular carcinoma (HCC). In the present study, a GPC3 specific-targeting nanoliposomal drug delivery system was constructed with GPC3 targeting peptide (named as L5 peptide) modification and anticancer drug cantharidin encapsulation, which aims to realize cantharidin targeted treatment of liver cancer. In our study, nanoliposome specifically targeting GPC3 receptor was successfully constructed with particle size of 127.9 nm and a spherical shape. The targeted liposomes were stable under 4 °C or room temperature for almost 15 days. The drug release from L5-modified liposomes was controlled and delayed. Their targeted delivery properties were characterized by relatively more accumulation in the GPC3 highly expressed HepG2 cells than that of GPC3 lowly expressed Huh-7 cells. The competition results also indicated that the liposomes with L5 peptide modification could competitively bind to GPC3 receptor. Moreover, the liposomes showed colocalization with the lysosome after 3 h incubation. The L5-modified liposomal CTD had an augmented cell growth inhibition and tumor inhibition than that of the free CTD on HepG2 cells and GPC3 highly expressed tumor mice. Our study establishes a new strategy for improving HCC treatment and chemotherapeutic agent targeting delivery.

Therapeutic potential of boron-based nanoparticles for enhanced glioblastoma treatment

Glioblastoma multiforme (GBM) is the most common type of brain tumor and its treatment is difficult due to its infiltrative nature into normal brain tissue, heterogeneity, and presence of the blood-brain barrier (BBB), which restricts the penetration of chemotherapy drugs into the brain tissue and also the tumor site. Nanoparticles have emerged as a potential solution to improve the stability and delivery of the therapeutic agents directly to the tumor site. In this paper, we developed boron-based nanocarrier systems for providing the anticancer drug doxorubicin (DOX) to T98G human glioblastoma cells. Three types of nanoparticles, calcium tetraborate (CBO), magnesium tetraborate (MBO), and strontium tetraborate (SBO) were prepared with sizes ranging approximately from 200 to 350 nm. DOX was effectively incorporated into the nanoparticles with ∼95 % loading capacity. As a result of cytotoxicity studies, the IC50 of free DOX was determined as ∼25 μg/mL (0.046 mM) for the glioblastoma cells. In contrast to blank borate nanoparticles, which had no harmful effect on the cells except SBO at high concentrations, DOX-containing borate nanoparticles increased toxicity in a way that was dependent on both time and concentration. Also, the nanoparticles were successively taken by the glioblastoma cells and therefore exhibited more cytotoxic effect than free DOX. As a result, these DOX-loaded boron-based nanoparticles are promising carrier systems for further research in glioblastoma treatment such as combined therapy with boron neutron capture therapy (BNCT).

Biotin-modified mesoporous silica nanoparticles as a delivery system for quercetin and gallic acid for bacterial biofilm eradication

The effective management of biofilm-associated infections remains a pressing concern in clinical practice, necessitating the development of efficient eradication strategies. This study introduces biotin-modified mesoporous silica nanoparticles (MSN-Biotin) designed to facilitate the delivery of phytochemical agents, including gallic acid and quercetin, for biofilm disruption. We elucidate the synthesis, characterization, and biofilm penetration ability of MSN-Biotin towards gram-negative E. coli biofilm and gram-positive S. mutans biofilms, emphasizing their potential in anti-biofilm drug delivery. Importantly, in vitro experiments demonstrate that MSN-Biotin loaded with phytochemicals achieved significantly better penetration into E. coli and S. mutans biofilms than traditional mesoporous silica nanoparticles and better biofilm eradication ability than free phytochemical molecules. These findings underscore the promise of MSN-Biotin as a potential efficient platform for delivering antimicrobial agents. This study introduces a novel surface modification approach for the development of antibiofilm nanoparticle systems and establishes their significant potential in biofilm infection management.

Theranostic nanoparticles for detection and treatment of pancreatic cancer.

Pancreatic ductal adenocarcinoma (PDAC) is one of the most recalcitrant cancers due to its late diagnosis, poor therapeutic response, and highly heterogeneous microenvironment. Nanotechnology has the potential to overcome some of the challenges to improve diagnostics and tumor-specific drug delivery but they have not been plausibly viable in clinical settings. The review focuses on active targeting strategies to enhance pancreatic tumor-specific uptake for nanoparticles. Additionally, this review highlights using actively targeted liposomes, micelles, gold nanoparticles, silica nanoparticles, and iron oxide nanoparticles to improve pancreatic tumor targeting. Active targeting of nanoparticles toward either differentially expressed receptors or PDAC tumor microenvironment (TME) using peptides, antibodies, small molecules, polysaccharides, and hormones has been presented. We focus on microenvironment-based hallmarks of PDAC and the potential for actively targeted nanoparticles to overcome the challenges presented in PDAC. It describes the use of nanoparticles as contrast agents for improved diagnosis and the delivery of chemotherapeutic agents that target various aspects within the TME of PDAC. Additionally, we review emerging nano-contrast agents detected using imaging-based technologies and the role of nanoparticles in energy-based treatments of PDAC. This article is categorized under: Implantable Materials and Surgical Technologies > Nanoscale Tools and Techniques in Surgery Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Diagnostic Tools > In Vivo Nanodiagnostics and Imaging.

Achieving Endo/Lysosomal Escape Using Smart Nanosystems for Efficient Cellular Delivery.

The delivery of therapeutic agents faces significant hurdles posed by the endo-lysosomal pathway, a bottleneck that hampers clinical effectiveness. This comprehensive review addresses the urgent need to enhance cellular delivery mechanisms to overcome these obstacles. It focuses on the potential of smart nanomaterials, delving into their unique characteristics and mechanisms in detail. Special attention is given to their ability to strategically evade endosomal entrapment, thereby enhancing therapeutic efficacy. The manuscript thoroughly examines assays crucial for understanding endosomal escape and cellular uptake dynamics. By analyzing various assessment methods, we offer nuanced insights into these investigative approaches' multifaceted aspects. We meticulously analyze the use of smart nanocarriers, exploring diverse mechanisms such as pore formation, proton sponge effects, membrane destabilization, photochemical disruption, and the strategic use of endosomal escape agents. Each mechanism's effectiveness and potential application in mitigating endosomal entrapment are scrutinized. This paper provides a critical overview of the current landscape, emphasizing the need for advanced delivery systems to navigate the complexities of cellular uptake. Importantly, it underscores the transformative role of smart nanomaterials in revolutionizing cellular delivery strategies, leading to a paradigm shift towards improved therapeutic outcomes.

Nanostructure-Mediated Transport of Therapeutics through Epithelial Barriers.

The ability to precisely treat human disease is facilitated by the sophisticated design of pharmacologic agents. Nanotechnology has emerged as a valuable approach to creating vehicles that can specifically target organ systems, effectively traverse epithelial barriers, and protect agents from premature degradation. In this review, we discuss the molecular basis for epithelial barrier function, focusing on tight junctions, and describe different pathways that drugs can use to cross barrier-forming tissue, including the paracellular route and transcytosis. Unique features of drug delivery applied to different organ systems are addressed: transdermal, ocular, pulmonary, and oral delivery. We also discuss how design elements of different nanoscale systems, such as composition and nanostructured architecture, can be used to specifically enhance transepithelial delivery. The ability to tailor nanoscale drug delivery vehicles to leverage epithelial barrier biology is an emerging theme in the pursuit of facilitating the efficacious delivery of pharmacologic agents.

Magnetically Induced Thermal Effects on Tobacco Mosaic Virus-Based Nanocomposites for a Programmed Disassembly of Protein Cages.

Protein cages are promising tools for the controlled delivery of therapeutics and imaging agents when endowed with programmable disassembly strategies. Here, we produced hybrid nanocomposites made of tobacco mosaic virus (TMV) and magnetic iron oxide nanoparticles (IONPs), designed to disrupt the viral protein cages using magnetically induced release of heat. We studied the effects of this magnetic hyperthermia on the programmable viral protein capsid disassembly using (1) elongated nanocomposites of TMV coated heterogeneously with magnetic iron oxide nanoparticles (TMV@IONPs) and (2) spherical nanocomposites of polystyrene (PS) on which we deposited presynthesized IONPs and TMV via layer-by-layer self-assembly (PS@IONPs/TMV). Notably, we found that the extent of the disassembly of the protein cages is contingent upon the specific absorption rate (SAR) of the magnetic nanoparticles, that is, the heating efficiency, and the relative position of the protein cage within the nanocomposite concerning the heating sources. This implies that the spatial arrangement of components within the hybrid nanostructure has a significant impact on the disassembly process. Understanding and optimizing this relationship will contribute to the critical spatiotemporal control for targeted drug and gene delivery using protein cages.

Chitosan Potential as Delivery Agent for S1 Gene from SARS-CoV-2 with pEGFP-N1 as its Vectors

Coronavirus Disease-19 (COVID-19) merupakan penyakit yang disebabkan oleh severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2), penyakit ini mulai muncul pada akhir tahun 2019 dan menjadi pandemi hingga saat ini. Vaksinasi dapat berperan penting dalam prevensi penyebaran penyakit, sehingga banyak dilakukan pengembangan vaksin salah satunya ialah vaksin DNA. Sistem penghantaran seperti kitosan dapat meningkatkan efektifitas dari vaksin. Tujuan dari penelitian ini adalah untuk mengoptimasi dan mengevaluasi formula pEGFP-N1-S1 dengan sistem penghantaran kitosan sebagai kandidat vaksin DNA. Plasmid dilakukan kloning pada E.coli DH5α dan dilakukan ekstraksi untuk evaluasi selanjutnya dengan enzim restriksi dan sekuensing. Plasmid EGFP-N1-S1 kemudian diformulasikan dengan nanopartikel kitosan dengan rasio massa Plasmid DNA:kitosan sebesar 1:0,1; 1:0,2; 1:0,3; 1:0,4; 1:0,5; 1:0,6 dan 1:0,7. Hasil plasmid yang dilakukan isolasi memiliki konsentrasi 2182,32 ng/L dan kemurnian sebesar 1,911. Hasil restriksi menunjukkan bahwa gen S1 (684 bp) berhasil diinsersi pada plasmid pEGFP-N1 (4813 bp). Rasio massa DNA:kitosan sebesar 1:0,6 merupakan formulasi yang optimal untuk DNA berikatan dengan kitosan secara sempurna.

Magnetite-doped nanopowder boron nitride for 10B delivery agent in BNCT

Several chemical routes are proposed for the synthesis of hexagonal boron nitride h-BN nanopowders doped with magnetic nanoclusters – ferromagnetic iron Fe or ferrimagnetic magnetite Fe3O4. Nanocomposites obtained during our experiments reveal magnetic properties rendering them useful for an application in BNCT (Boron Neutron Capture Therapy) for external magnetic field controlled delivery of neutron-capturing boron 10B isotopes in target tumor cells.