Emerging Applications of Nanotechnology in Healthcare and Medicine

Bioinspired sustainable development of Ag-CuO/MWCNT nanocomposites for antibacterial applications

This study explores the bioinspired and sustainable synthesis of Ag-CuO/MWCNT nanocomposites for enhanced antibacterial applications. Utilizing a green synthesis approach, Rivina humilis plant extract served as a natural reducing and stabilizing agent during the co-precipitation method to fabricate the nanocomposites. The integration of silver (Ag) and copper oxide (CuO) nanoparticles with multi-walled carbon nanotubes (MWCNT) resulted in a synergistic antibacterial effect. The Ag nanoparticles disrupt bacterial membranes by releasing Ag+ ions, while CuO generates reactive oxygen species (ROS), leading to oxidative stress and bacterial cell death. The MWCNT enhances structural stability and provides additional mechanical damage to the bacterial cells. This multi-mechanistic approach ensures superior antibacterial performance against both Gram-positive and Gram-negative bacteria. The eco-friendly synthesis process aligns with principles of sustainability, offering a promising alternative for developing advanced antimicrobial materials while reducing environmental impact, whereas S. agalactiae showing the largest zone of inhibition (15 mm). These findings highlight the potential of bioinspired nanocomposites in combating bacterial infections effectively.

Role of advanced cleaning and sanitation techniques in biofilm prevention on dairy equipment

Biofilm formation on dairy equipment is a persistent challenge in the dairy industry, contributing to product contamination, equipment inefficiency, and economic losses. Traditional methods such as manual cleaning and basic chemical sanitation are discussed as foundational approaches, followed by an in-depth investigation of cutting-edge technologies, including clean-in-place systems, high-pressure cleaning, foam cleaning, ultrasonic and electrochemical cleaning, dry ice blasting, robotics, nanotechnology-based agents, enzymatic cleaners, and oxidizing agents. Enhanced sanitation techniques, such as dry steam, pulsed light, acidic and alkaline electrolyzed water, hydrogen peroxide vapor, microbubble technology, and biodegradable biocides, are highlighted for their potential to achieve superior sanitation while promoting sustainability. The effectiveness, feasibility, and limitations of these methods are evaluated, emphasizing their role in maintaining dairy equipment hygiene and reducing biofilm-associated risks. Additionally, challenges, such as equipment compatibility, cost, and regulatory compliance, are addressed, along with insights into future directions and innovations, including automation, smart cleaning systems, and green cleaning solutions. This review provides a comprehensive resource for researchers, industry professionals, and policymakers aiming to tackle biofilm formation in dairy production systems and enhance food safety, operational efficiency, and sustainability.

Noncovalent binding phenomena in the adsorption of amino acids on Ag/Au surfaces: a theoretical approach

Adsorption of amino acids (AAs) onto Ag and Au surfaces has attracted much interest in the past years, owing to their ability to control and tune the structure of Ag and Au nanoparticles (NPs) during the synthetic procedure and to enhance their stability under various conditions. Despite this, the molecular recognition events that are responsible for such stabilization as well as the role of the AA residue moieties is still not completely understood. To tackle this point, we computationally evaluated the weak interactions involved in the AA⋯Ag/AuNP recognition process from a theoretical perspective. In more detail, we analysed the strength and physical nature of the interactions established between twenty essential AAs and Ag/AuNPs at the PBE0-D3/def2-TZVP level of theory. The structural and energetic studies were complemented by the use of the quantum theory of atoms in molecules (QTAIM), non-covalent interaction plot (NCIplot) and energy decomposition analysis (EDA) techniques, providing new insights into the nature and spatial extension of the interactions studied herein. We believe that the results reported in this exploratory study will be useful for researchers working in the fields of bioinorganic chemistry, biotechnology and supramolecular chemistry by shedding light on the weak binding phenomena that are crucial for achieving AA⋯Ag/AuNP recognition.

Enzyme-immobilized graphene oxide-based electrochemical biosensor for glutathione detection

Glutathione acts as a natural antioxidant in the human body and the reduction of its content is a sign of oxidative stress. In this study, a sensitive electrochemical sensor was developed using laccase enzyme immobilized onto graphene oxide (GO) for detection of glutathione. The surface of the indium tin oxide (ITO) was modified with GO via a drop casting method. Subsequently, laccase was immobilized onto the modified ITO decorated with GO. The modified electrode was characterized using field-emission scanning electron microscopy (FESEM), X-ray photoelectron spectroscopy (XPS), Fourier transform infrared spectroscopy (FTIR), cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS). The FTIR spectra of laccase/GO confirmed the successful immobilization of laccase onto GO sheets. FESEM analysis revealed the transformation from a layered, wrinkled structure to a compact, smooth surface with spherical laccase, confirming successful enzyme integration. Raman analysis confirmed successful laccase immobilization onto GO, as evidenced by structural changes in the D and G bands, highlighting the modification of the material. The cyclic voltammetry measurements revealed that laccase/GO/ITO exhibited better electrocatalytic activity toward oxidation of GSH in acetate buffer solution than the bare ITO electrode. This newly developed electrode exhibited a good response to glutathione with a wide linear range from 1 μM to 100 μM, a limit of detection of 0.89 μM and high sensitivity (6.51 μA μM-1). Furthermore, it exhibited excellent selectivity, repeatability, and long-term stability. The modified electrode was successfully used for the detection of GSH in a real sample, offering satisfactory results.

Pullulan as a sustained release carrier for ocular drug delivery: a review

Pullulan, an exopolysaccharide, obtained from the fungus Aureobasidium pullulans, is a non-ionic, hydrophilic, biodegradable, biocompatible, and tolerogenic polymers that is used for the formulation of bioconjugates in the therapeutic delivery to target different cells and tissues. It is known to possess outstanding film-casting qualities and can produce a clear and biodegradable film. Furthermore, appropriate derivatizing pullulan provides active surfaces that facilitate binding with active pharmaceutical ingredients to the polymer backbone to produce micro/nanoparticulate systems for controlled or sustained drug release. Ophthalmic problems like glaucoma, age-related macular degeneration, and cataracts are very prevalent across the globe, and their treatment options mainly include conventional topical solutions and gels, which possess very low drug-contact time and poor bioavailability, leading to frequent dosing and patient incompliance. Sustained release dosage forms like ocuserts, ocular films, and in-situ gels can help in achieving the intended therapeutic outcomes for an extended duration by minimizing the number of doses. Here, we present a comprehensive critical review of the utilization and application of pullulan, together with its derivatives, to combat problems with ocular medication administration. This article also provides insight for further research on this topic to utilize its advantages to the fullest in the future for improved delivery of therapeutics in the treatment of ocular disorders.

Vertically Aligned Nanowires for Longitudinal Intracellular Sampling

Cells are diverse systems with unique molecular profiles that support vital functions, such as energy production and nutrient absorption. Advances in omics have provided valuable insights into these cellular processes, but many of these tools rely on cell lysis, limiting the ability to track dynamic changes over time. To overcome this, methods for longitudinal profiling of living cells have emerged; however, challenges such as low throughput and genetic manipulation still need to be addressed. Nanomaterials, particularly nanowires, offer a promising solution due to their size, high aspect ratios, low cost, simplicity, and potential for high-throughput manufacturing. Here, we present a nanowire-based platform for longitudinal mRNA profiling in living cells using vertically aligned nickel nanowire arrays for efficient mRNA extraction with minimal cellular disruption. We demonstrate its ability to track enhanced green fluorescent protein expression and transcriptomic changes from drug responses in the same cells over time, showcasing the platform's potential for dynamic cellular analysis.

Alleviation of mycobacterial infection by impairing motility and biofilm formation via natural and synthetic molecules

Mycobacterium species show distinctive characteristics with significant medical implications. Mycobacteria, including Mycobacterium tuberculosis and non-tuberculous mycobacteria, can form biofilms that facilitate their survival in hostile environments and contribute to development of antibiotic resistance and responses by the host immune system. Mycobacterial biofilm development is a complex process involving multiple genetic determinants, notably mmpL genes, which regulate lipid transport and support cell wall integrity, and the groEL gene, which is essential for biofilm maturation. Sliding motility, a passive form of surface movement observed across various mycobacterial species, is closely associated with biofilm formation and colony morphology. The unique sliding motility and biofilm-forming capabilities of Mycobacterium spp. are pivotal for their pathogenicity and persistence in diverse environments. A comprehensive understanding of the regulatory mechanisms governing these processes is crucial for the development of novel therapeutic strategies against mycobacterial infections. This review provides a detailed examination of our current knowledge regarding mycobacterial biofilm formation and motility, with a focus on regulation of these processes, their impact on pathogenicity, and potential avenues for therapeutic intervention. To this end, the potential of natural and synthetic compounds, including nanomaterials, in combating mycobacterial biofilms and inhibiting sliding motility are discussed as well. These compounds offer new avenues for the treatment of drug-resistant mycobacterial infections.

Dual Biopolymer Layer Using Nanoparticles with Active Substance Enclosed in Microcapsules: Innovative Solution for Slow Release of Ginkgo biloba L. Extract for Potential Therapies

The dynamic development of various branches of medicine and pharmacy, along with the emergence of new preventive and alternative therapies for various diseases, creates opportunities for new solutions utilizing carriers of active substances. Their therapeutic effect may occur through direct contact with skin lesions or indirectly, where medicinal substances penetrate the capillary network in the deeper layers of the skin and reach the bloodstream. The aim of the research was to obtain carriers with a matrix consisting of two renewable-source polymers (chitosan and ethylcellulose) and a core material derived from Ginkgo biloba green leaf extract (GBE). The obtained ethylcellulose microcapsules with encapsulated chitosan nanoparticles with extract {Et[Ch(GB)NP]} were characterized with respect to size, shape, surface morphology (SEM microscopy), and active substance release kinetics (UV-VIS and mathematical release models). The kinetics of active substance release were analyzed using UV-VIS spectroscopy and mathematical release models. The released active components were assessed microbiologically for activity against six bacterial strains and two fungal strains, as well as chromatographically using HPLC-ESI-QTOF-MS/MS fingerprinting. The microcapsules with a dual polymer layer exhibited a slow release of the core material, which demonstrated microbiological activity. The strongest antimicrobial effects were observed against Klebsiella pneumoniae and Salmonella enteritidis, with a minimum inhibitory concentration (MIC) of 410 µg/mL. The release of the core material from the double-layer polymer structures was more efficient in a physiological saline environment, with the best fit for the extract release kinetics following a zero-order model (regression coefficient R2 = 0.9939). The obtained microcapsules with a dual polymer layer show great potential for therapeutic applications in the medical industry. Their controlled release properties and antibacterial effectiveness make them a promising carrier for active substances in modern therapies.

Nanobiotechnology: traditional re-interpreting personalized medicine through targeted therapies and regenerative solutions

Nanobiotechnology is transforming personalized medicine by leveraging the unique properties of nanomaterials to address key challenges in targeted drug delivery, regenerative medicine, and diagnostics. The development of nanocarriers, such as liposomes, polymeric nanoparticles, dendrimers, and metallic nanoparticles, has enabled precise drug delivery with enhanced bioavailability and reduced systemic toxicity. Concurrently, nanostructured scaffolds have advanced regenerative medicine by supporting stem cell differentiation, modulating cellular microenvironments, and enhancing tissue repair. These nanoscale innovations have also led to highly sensitive biosensors and imaging agents, significantly improving early disease detection and biomarker monitoring. Despite these advancements, challenges persist, including nanoparticle-induced cytotoxicity, immunogenicity, scalability issues, and regulatory hurdles requiring extensive evaluation of long-term biocompatibility and pharmacokinetics. Addressing these limitations, recent breakthroughs in AI-assisted nanotechnology and CRISPR-Cas9-mediated gene editing are driving next-generation precision medicine, integrating nanoscale therapeutics with computational approaches to enhance efficacy. Future directions focus on nanorobotics, bioengineered nanovaccines, and theranostic platforms capable of simultaneous diagnosis and treatment, paving the way for real-time, patient-specific interventions. The successful translation of nanomedicine into clinical practice will require interdisciplinary collaboration across nanoscience, bioengineering, and translational medicine to refine nanoparticle functionalization, optimize safety profiles, and ensure equitable access to nanotherapeutics. This review provides a comprehensive overview of these advancements, challenges, and emerging opportunities in nanobiotechnology-driven precision medicine.

Advancement of Nanomaterials- and Biomaterials-Based Technologies for Wound Healing and Tissue Regenerative Applications

Patients and healthcare systems face significant social and financial challenges due to the increasing number of individuals with chronic external and internal wounds that fail to heal. The complexity of the healing process remains a serious health concern, despite the effectiveness of conventional wound dressings in promoting healing. Recent advancements in materials science and fabrication techniques have led to the development of innovative dressings that enhance wound healing. To further expedite the healing process, novel approaches such as nanoparticles, 3D-printed wound dressings, and biomolecule-infused dressings have emerged, along with cell-based methods. Additionally, gene therapy technologies are being harnessed to generate stem cell derivatives that are more functional, selective, and responsive than their natural counterparts. This review highlights the significant potential of biomaterials, nanoparticles, 3D bioprinting, and gene- and cell-based therapies in wound healing. However, it also underscores the necessity for further research to address the existing challenges and integrate these strategies into standard clinical practice.

Therapeutic Potential of Green Synthesized Polyherbal Formulated Silver Nanoparticles in Alloxan-Induced Diabetes Mellitus-An In Vivo Strategy

Diabetes mellitus (DM) is a non-communicable, life-threatening syndrome prevalent worldwide. One effective treatment for DM is the medicinal use of green synthesized silver nanoparticles (AgNPs), which are eco-friendly and cost-effective. This study investigates the antidiabetic potential of greensynthesizedAgNPs derived from a polyherbal formulation (PHF). Characterization of PHF-AgNPs included UV-Vis spectroscopy, FTIR, XRD, SEM, and EDX. Diabetes was induced in albino Wistar rats (N = 30, n = 6/group, 150-200 g, 8 weeks old) via intraperitoneal alloxan injection (150 mg). Groups are as follows: 1) untreated control, 2) diabetic control (150 mg/kg b.w. alloxan), 3) glibenclamide (0.5 mg/kg), 4) PHF-AgNPs (10 mg/kg), and 5) PHF-AgNPs (20 mg/kg). Blood glucose levels (BGL) were monitored on days 0, 7, 14, and 21. Blood samples were collected for the liver, kidney, and lipid profile analysis before euthanization. The results showed that PHF-AgNPs had an average size of 20 nm and exhibited significant reductions in BGL, with PHF-AgNPs at both 10 mg/kg and 20 mg/kg demonstrating superior effects compared to glibenclamide. Histopathological analysis revealed tissue regeneration in the liver, kidney, and pancreas, indicating healing of alloxan-induced damage. Additionally, treatment improved liver and kidney function markers, and lipid profiles, with reductions in cholesterol, triglycerides, ALT, AST, and creatinine levels compared to the diabetic control group. These findings suggest that green synthesized PHF-AgNPs effectively improved blood glucose control, body weight, and organ health, positioning them as a promising antidiabetic agent with potential for further clinical development.

Women's perceptions of medicalised pregnancy and childbirth: an exploratory sequential mixed-method protocol study

INTRODUCTION

The present study aimed to develop and assess psychometric properties of an instrument to measure the perception of women regarding the medicalisation of pregnancy and childbirth.

METHOD

This is a sequential exploratory mixed-method protocol study and will be conducted in three phases. In the first phase of the study, the hybrid conceptual model will define and explain the components of medicalisation. The hybrid approach includes a theoretical review (literature review) and a qualitative study. Using the results of the first phase, in the second phase of the study, the primary dimensions and items of the instrument will be developed. In the third phase, the psychometric properties of the designed instrument will be evaluated. Psychometric steps include face validity, content validity and construct validity. The research environment will be Al-Zahra and Taleghani educational centres, as well as health centres of Tabriz city and private offices of midwives and gynaecologists.

ETHICS AND DISSEMINATION

Informed consent has been obtained from all subjects. This protocol has been approved by the ethics committee of Tabriz University of Medical Sciences (IR.TBZMED.REC.1403.352). The findings will be disseminated through peer-reviewed manuscripts, reports and presentations.

Role of Nanomedicine in Transforming Pharmacotherapy for Substance Use Disorder (SUD)

The field of nanomedicine offers revolutionary potential to reshape the discovery and development of therapeutics for diverse human diseases. However, its application has been limited in improving Substance Use Disorders (SUDs), which represent a profound public health crisis, including major types such as opioid, alcohol, stimulant, and cannabis use disorders. Pharmacotherapy, a cornerstone of SUD management, has reduced morbidity, mortality, and the societal impact of addiction, though its efficacy has ranged from none to moderate. Thus, there is a major unmet need to transform SUD pharmacotherapy to curb the epidemic of addiction. This article explores the potential roles of nanomedicine-inspired precision-targeted drug delivery, sustained release, and combination therapies to increase therapeutic efficacy and minimize side effects. Additionally, it discusses innovative mechanisms that align with the neurobiological complexities of addiction and synergistic approaches that integrate nanomedicine with behavioral interventions, device-based therapies, and emerging modalities such as immunotherapy and neurostimulation. Despite these advancements, barriers such as treatment accessibility, adherence challenges, and inequitable resource distribution persist, particularly in underserved populations. By harnessing the transformative capabilities of nanomedicine and integrating it into holistic, equitable, and personalized care frameworks, this review highlights a path forward to revolutionize the SUD pharmacotherapy landscape. The article underscores the need for continued nano-SUD pharmacotherapy research and the development of strategies to alleviate the substantial burden of addiction on individuals, families, and society.

The Anti-proliferative Effect, Apoptotic Induction, and Cell Cycle Arrest of Tetra Halo Ruthenate Nanocomposites in Different Human Cancer Cell Lines

Chemotherapy is the most common cancer treatment, and metallic anticancer compounds have generated increasing amounts of interest since the discovery of cisplatin. More recently, scientists have focused on ruthenium-based compounds as alternatives for platinum compounds, which seem like ideal therapeutic anticancer alternatives to platinum derivatives. The present study aims to assess whether one or more of three Ruthenium-based nanocomposites, namely Ru+Lysine+CTAB (RCTL), Ru+CTAB (RCT), and Ru+Lysine (RL) exhibit pronounced anti-proliferative properties against different cancer cells. Three Ruthenium nanocomposites have been synthesized by standard chemical methods and characterized by Dynamic light scattering (DLS) and Transmission electron microscopy (TEM). The cytotoxic effect of the three composites has been evaluated by MTT in-vitro assay for different human cancer cell lines, namely MCF7, HepG2, A549, and PC3 versus normal human skin cell line (BJ1). The molecular underlying mechanisms of cytotoxicity have been assessed via qRT-PCR for pro-apoptotic makers P53 and Casp-3, and anti-apoptotic marker Bcl-2 as well as flow cytometric analysis of the cell cycle. Among the 3 nanocomposites, RCTL gave the best sensitivity and cytotoxicity especially on HepG2 with IC50 0.55 µg/ml but was still toxic on normal cell line with dose <12.5 µg/ml. RCTL and RCT nanocomposites have demonstrated a significant increase in the expression of P53 and Casp-3 markers versus untreated controls, but a significant reduction in the expression of Bcl-2. There was a direct correlation between the cytotoxic effect and the degree of apoptosis in the different cancer cell lines. The present study has also proved cell cycle arrest at G2-M and pre-G1 phases under the effect of IC50 of RCTL and RCT nanocomposites in different cancer lines with the best effect being achieved in HepG2 cells. Ruthenium nanocomposites seem to open a new avenue in cancer therapy.

Use of Quantum Dots as Nanotheranostic Agents: Emerging Applications in Rare Genetic Diseases

Rare genetic diseases (RGDs) affect a small percentage of the global population but collectively have a substantial impact due to their diverse manifestations. Although the precise reasons behind these diseases remain unclear, roughly 80% of cases are genetically linked. Recent efforts focus on understanding pathology and developing new diagnostic and therapeutic approaches for RGDs. However, there persists a gap between fundamental research and clinical therapeutic approaches, where advancements in nanotechnology offer promising improvements. In this context, nanosized light-emitting quantum dots (QDs), ranging from 2-10 nm, are promising materials for diverse applications. Their size-tunable light emission, high quantum yield, and photostability allow for precise tracking of cargo. Additionally, QDs can be functionalized with therapeutic agents, antibodies, or peptides to target specific cellular pathways, enhancing treatment efficacy while minimizing side effects. By combining diagnostic and therapeutic capabilities in a single platform, QDs thus offer a versatile and powerful approach to tackle rare genetic disorders. Despite several reviews on various therapeutic applications of QDs, their utilization in the specific domain of RGDs is not well documented. This review highlight QDs' potential in diagnosing and treating certain RGDs and addresses the challenges limiting their application.

Bio-fabricated silver nanoparticles: therapeutic evaluation as a potential nanodrug against cervical and liver cancer cells

Nanobiotechnology has grown rapidly and is now widely used in the diagnosis and treatment of modern diseases. Biosynthesized silver nanoparticles (AgNPs) are eco-friendly, cost-effective, biocompatible route, and have biomedical properties at minimal concentrations. In the present study extract of cyanobacterium (Anabaena variabilis) was utilized to synthesize facile, reliable AgNPs, further biosynthesized AgNPs were characterized by physicochemical techniques. The atomic force microscope study confirmed the shape of AgNPs while the scanning electron microscopy study revealed 17 to 35 nm in the size range. The zeta potential value of -19.5 mV demonstrated the repulsion effect between the particles, which prevents their aggregations while the heating stability of AgNPs was confirmed by Thermogravimetry differential thermal analysis. Another important characteristic, such as elemental constituent of AgNPs was determined by inductively coupled plasma mass spectrometry and was observed 94.24, 95.19, 97.06, and 99.34% of silver present in their respective concentrations of AgNPs. In vitro cytotoxicity of AgNPs was screened on HeLa, SiHa, (Cervical carcinoma), and HepG2 (Human hepatocellular carcinoma), cell lines. To evaluate the biocompatibility of AgNPs immortalized human embryonic kidney (HEK-293) cell line was used. The IC50 values of AgNPs are were observed as 23.76 ± 2.4 µg/mL, 11.21 ± 1.7 µg/mL, and 22.27 ± 1.8 µg/mL against HeLa, SiHa and HepG2 cell lines respectively. AgNPs demonstrated the biocompatible nature against HEK-293 cells, Normal cell line (HEK-293) cytotoxicity results showed exhibited ≥ 95% cell viability at all the concentrations. During the DAPI (4',6-diamidino-2-phenylindole) staining study IC50 dose of AgNPs on cancer cell lines (HeLa, SiHa, and HepG2) showed nuclear morphological alterations which indicate the DNA damage and apoptosis in cancer cells. AgNPs treated cancer cells increased the cells number in the S phase while decreased the number of cells in the G0-G1 and G2/M phases of the cell cycle in all three cancer cells compared to the control.

A mechanistic overview on green assisted formulation of nanocomposites and their multifunctional role in biomedical applications

The importance of nanocomposites constantly attains attention because of their unique properties all across the fields especially in medical perspectives. The study of green-synthesized nanocomposites has grown to be extremely fascinating in the field of research. Nanocomposites are more promising than mono-metallic nanoparticles because they exhibit synergistic effects. This review encapsulates the current development in the formulation of plant-mediated nanocomposites by using several plant species and the impact of secondary metabolites on their biocompatible functioning. Phyto-synthesis produces diverse nanomaterials with biocompatibility, environment-friendliness, and in vivo actions, characterized by varying sizes, shapes, and biochemical nature. This process is advantageous to conventional physical and chemical procedures. New studies have been conducted to determine the biomedical efficacy of nanocomposites against various diseases. Unfortunately, there has been inadequate investigation into green-assisted nanocomposites. Incorporating phytosynthesized nanocomposites in therapeutic interventions not only enhances healing processes but also augments the host's immune defenses against infections. This review highlights the phytosynthesis of nanocomposites and their various biomedical applications, including antibacterial, antidiabetic, antiviral, antioxidant, antifungal, anti-cancer, and other applications, as well as their toxicity. This review also explores the mechanistic action of nanocomposites to achieve their designated tasks. Biogenic nanocomposites for multimodal imaging have the potential to exchange the conventional methods and materials in biomedical research. Well-designed nanocomposites have the potential to be utilized in various biomedical fields as innovative theranostic agents with the subsequent objective of efficiently diagnosing and treating a variety of human disorders.

Drug Repurposing and Nanotechnology for Topical Skin Cancer Treatment: Redirecting toward Targeted and Synergistic Antitumor Effects

Skin cancer represents a major health concern due to its rising incidence and limited treatment options. Current treatments (surgery, chemotherapy, radiotherapy, immunotherapy, and targeted therapy) often entail high costs, patient inconvenience, significant adverse effects, and limited therapeutic efficacy. The search for novel treatment options is also marked by the high capital investment and extensive development involved in the drug discovery process. In response to these challenges, repurposing existing drugs for topical application and optimizing their delivery through nanotechnology could be the answer. This innovative strategy aims to combine the advantages of the known pharmacological background of commonly used drugs to expedite therapeutic development, with nanosystem-based formulations, which among other advantages allow for improved skin permeation and retention and overall higher therapeutic efficacy and safety. The present review provides a critical analysis of repurposed drugs such as doxycycline, itraconazole, niclosamide, simvastatin, leflunomide, metformin, and celecoxib, formulated into different nanosystems, namely, nanoemulsions and nanoemulgels, nanodispersions, solid lipid nanoparticles, nanostructured lipid carriers, polymeric nanoparticles, hybrid lipid-polymer nanoparticles, hybrid electrospun nanofibrous scaffolds, liposomes and liposomal gels, ethosomes and ethosomal gels, and aspasomes, for improved outcomes in the battle against skin cancer. Enhanced antitumor effects on melanoma and nonmelanoma research models are highlighted, with some nanoparticles even showing intrinsic anticancer properties, leading to synergistic effects. The explored research findings highly evidence the potential of these approaches to complement the currently available therapeutic strategies in the hope that these treatments might one day reach the pharmaceutical market.

Magnetic-Plasmonic Core-Shell Nanoparticles: Properties, Synthesis and Applications for Cancer Detection and Treatment

Nanoparticles have been widely used in cancer diagnostics and treatment research due to their unique properties. Magnetic nanoparticles are popular in imaging techniques due to their ability to alter the magnetization field around them. Plasmonic nanoparticles are mainly applied in cancer treatments like photothermal therapy due to their ability to convert light into heat. While these nanoparticles are popular among their respective fields, magnetic-plasmonic core-shell nanoparticles (MPNPs) have gained popularity in recent years due to the combined magnetic and optical properties from the core and shell. MPNPs have stood out in cancer theranostics as a multimodal platform capable of serving as a contrast agent for imaging, a guidable drug carrier, and causing cellular ablation through photothermal energy conversion. In this review, we summarize the different properties of MPNPs and the most common synthesis approaches. We particularly discuss applications of MPNPs in cancer diagnosis and treatment based on different mechanisms using the magnetic and optical properties of the particles. Lastly, we look into current challenges they face for clinical applications and future perspectives using MPNPs for cancer detection and therapy.

Copper(II)-Complexed Polyethylenimine-Entrapped Gold Nanoparticles Enable Targeted CT/MR Imaging and Chemodynamic Therapy of Tumors

Transition-metal ion copper(II) (Cu(II)) has drawn increasing attention as a small-molecular cancer theranostic agent. However, delivering a sufficient dosage of Cu(II) to the tumor site and integrating multiple imaging modalities to achieve precise and effective cancer theranostics remains a critical challenge. Herein, an emerging Cu(II)-based nanocomposite has been synthesized for targeted tumor computed tomography (CT)/magnetic resonance (MR) dual-mode imaging and chemodynamic therapy (CDT). Briefly, 2-picolinic acid (PA-COOH), polyethylene glycol (PEG)-linked folic acid (FA), and fluorescein isothiocyanate (FI) were sequentially conjugated with polyethylenimine (PEI.NH2) and then in situ fabrication of gold nanoparticles (Au NPs) occurred within the PEI.NH2 internal cavity. After acetylation of PEI.NH2 terminal amines and Cu(II) complexation, the Cu(II)-based nanocomposites FA-Au/Cu(II) PENPs with a mean diameter of 2.87 nm were generated. The synthesized FA-Au/Cu(II) PENPs showed favorable stability of colloidal dispersion, sustainable Cu(II) release properties in a pH-dependent manner, and Fenton-like catalytic activity specifically. With the FA-mediated targeting pathway, FA-Au/Cu(II) PENPs can specifically accumulate in cancer cells with high expression of FA receptors. Meanwhile, the complementary CT/MR dual-mode imaging in vitro and in vivo can be afforded by FA-Au/Cu(II) PENPs based on the excellent X-ray attenuation properties of Au NPs and the applicable r1 relaxivity (0.7378 mM-1s-1) of Cu(II). Notably, the Cu(II)-mediated CDT mechanism enables FA-Au/Cu(II) PENPs to elicit the generation of toxic hydroxyl radicals (·OH), depletion of glutathione (GSH), promotion of lipid peroxidation (LPO), and induction of cancer cell apoptosis in vitro, and further demonstrates remarkable anti-tumor efficacy in a xenograft tumor model. With the illustrated targeted theranostic capacity of FA-Au/Cu(II) PENPs towards tumors, this Cu(II)-based nanocomposite paradigm inspires the construction of advanced theranostic nanoplatforms incorporating alternative transition metal ions.

Ag-Ag2O nanocomposite biosynthesis by mixed bacterial cultivation and effect of the ph on size and optical properties of the nanocomposite

This study examines the influence of pH on the energy band gap and crystallite size during the synthesis of a novel Ag-Ag2O nanocomposites through the mixed cultivation of Lactobacillus sp. and Bacillus sp. A range of analytical techniques, including X-ray Diffraction (XRD), UV-visible Spectroscopy (UV-vis), Fourier Transform Infrared Spectroscopy (FTIR), and Transmission Electron Microscopy (TEM), were employed to investigate the structural and optical characteristics of the nanocomposites. XRD analysis confirmed the presence of cubic phases of Ag and Ag2O, with crystallite sizes varying from 8 to 44 nm; notably, smaller crystallites were observed at a pH of 6.5. UV-vis spectroscopy indicated an energy band gap ranging from 1.83 to 1.897 eV, suggesting promising applications for the material. The optimal pH for synthesis, which yielded the smallest particle size as verified by TEM, was identified as 6.5. FTIR analysis revealed the presence of biologically derived coating agents that may enhance the immutability and bioactivity of the nanocomposite. Antibacterial assays demonstrated significant efficacy against Enterococcus faecalis(E. faecalis) and Escherichia coli, particularly highlighting its effectiveness against E. faecalis. Hemolytic assays confirmed the biocompatibility of the nanocomposite at lower concentrations. These findings indicate the potential applications of the biogenic Ag-Ag2O nanocomposites in medical and environmental fields, offering a sustainable solution to challenges associated with bacterial contamination. Future research may focus on integrating these biologically synthesized nanoparticles into advanced materials and coatings to improve their performance.

Transforming Medicine: Cutting-Edge Applications of Nanoscale Materials in Drug Delivery

Since their inception in the early 1960s, the development and use of nanoscale materials have progressed tremendously, and their roles in diverse fields ranging from human health to energy and electronics are undeniable. The application of nanotechnology inventions has revolutionized many aspects of everyday life including various medical applications and specifically drug delivery systems, maximizing the therapeutic efficacy of the contained drugs by means of bioavailability enhancement or minimization of adverse effects. In this review, we utilize the CAS Content Collection, a vast repository of scientific information extracted from journal and patent publications, to analyze trends in nanoscience research relevant to drug delivery in an effort to provide a comprehensive and detailed picture of the use of nanotechnology in this field. We examine the publication landscape in the area to provide insights into current knowledge advances and developments. We review the major classes of nanosized drug delivery systems, their delivery routes, and targeted diseases. We outline the most discussed concepts and assess the advantages of various nanocarriers. The objective of this review is to provide a broad overview of the evolving landscape of current knowledge regarding nanosized drug delivery systems, to outline challenges, and to evaluate growth opportunities. The merit of the review stems from the extensive, wide-ranging coverage of the most up-to-date scientific information, allowing unmatched breadth of landscape analysis and in-depth insights.

A comprehensive review on recent advancements in drug delivery via selenium nanoparticles

Nanotechnology has significantly impacted drug discovery and development over the past three decades, offering novel insights and expanded treatment options. Key to this field is nanoparticles, ranging from 1 to 100 nanometres, with unique properties distinct from larger materials. Selenium nanoparticles (SeNPs) are particularly promising due to their low toxicity and selective cytotoxicity against cancer cells. They have shown efficacy in reducing various cancers types and mitigating conditions like diabetic nephropathy and neurological disorders, such as Alzheimer's disease. This review highlights SeNPs' role in enhancing drug delivery systems, improving the absorption of water-soluble compounds, proteins, peptides, vaccines, and other biological therapies. By modifying nanoparticle surfaces with targeting ligands, drug delivery can achieve precise site-specific delivery, increasing effectiveness. SeNPs can be synthesised through physical, chemical, and biological methods, each offering advantages in stability, size, and application potential. Additionally, SeNPs enhance immune responses and reduce oxidative stress, validating their role in biotherapy and nanomedicine. Their ability to target macrophages and regulate polarisation underscores their potential in antimicrobial therapies. Recent advancements, such as mannosylated SeNPs for targeted delivery, exemplify innovative nanotechnology applications in medicine. Overall, SeNPs represent a promising frontier in nanomedicine, offering new avenues for treating and managing various diseases.

The role of metal nanocarriers, liposomes and chitosan-based nanoparticles in diabetic retinopathy treatment: A review study

Diabetic Retinopathy (DR) is a significant and progressive eye complication associated with diabetes mellitus, leading to potential vision loss. The pathophysiology of DR involves complex neurovascular changes due to prolonged hyperglycemia, resulting in microangiopathy and neurodegeneration. Current treatment modalities come with limitations such as low bioavailability of therapeutic agents, risk of side effects, and surgical complications. Consequently, the prevention and management of DR, particularly in its advanced stages, present ongoing challenges. This review investigates recent advancements in nanotechnology as a novel approach to enhance the treatment of DR. A comprehensive literature review of recent studies focusing on nanocarriers for drug delivery in DR treatment and an analysis of their efficacy compared to traditional methods was conducted for this study. The findings indicate that nanotechnology can significantly enhance the bioavailability of therapeutic agents while minimizing systemic exposure and associated side effects. The novelty of this study lies in its focus on the intersection of nanotechnology and ophthalmology, exploring innovative solutions that extend beyond existing literature on DR treatments. By highlighting recent advancements in this field, the study paves the way for future research aimed at developing more effective therapeutic strategies for managing DR.

GC/MS analysis and green-synthesis of silver nanoparticles using Senna auriculata flower extract: Antibacterial, antioxidant effects and anticancer effects

In the present state of nano drug research, the production of herbal nutritionally aided nanoparticles has a broad variety of applications of new non side effect medical medications, as long as they are founded with environmentally acceptable methods. Silver nanoparticles in the form of phytochemicals from traditional herbal remedies, specifically the flower of senna auriculata, have been produced. The green synthesized silver nanoparticles were subsequently characterized by UV-Visible spectroscopy, Transmission electron microscopy, Fourier transform infrared spectroscopy, X-ray diffraction and Thermo gravity analysis. In the current study on the green synthesis approach, one of the best candidates, Ag nanoparticles act as a potential agent to investigate the antibacterial activity by a well diffusion method. The green synthesized AgNPs had the highest significant antibacterial activity against Gram-negative bacteria E. coli at 100 μg/mL, as well as, the AgNPs exhibited great inhibitory effects on DPPH radicals and their antioxidant properties were favorably comparable to the antioxidant outcomes of ascorbic acid. Furthermore, at 100 μg/mL concentration, the S. auriculata silver nanoparticles showed substantial cytotoxic effects against human breast cancer MCF-7 cell lines when compared to their effect on the normal cell line tested. The GC-MS analysis of the S. auriculata extract showed that 55 bioactive phytochemical compounds, which may be of use to the synthesis of AgNPs. Hence, the green synthesized silver nanoparticles from flower extract S. auriculata can be employed for biomedical applications.

Assessment of the In Vitro Biological Activities of Schiff Base-Synthesized Copper Oxide Nanoparticles as an Anti-Diabetic, Anti-Alzheimer, and Anti-Cancer Agent

Background/Objectives: Numerous diseases such as diabetes, Alzheimer's disease, and cancer have spread in the whole world, especially in the Arab world. Also, various applications of Schiff-base functionalized nanoparticles and copper oxide nanoparticles (CuO-NPs) such as therapeutic applications have been discovered. Thus, the current research highlights (i) the synthesis of copper oxide nanoparticles (CuO-NPs) produced with a Schiff base (SB) serving as a capping agent during their synthesis and (ii) assessment of the in vitro biological activities of Schiff base-synthesized copper oxide nanoparticles (SB-CuO-NPs) and a Schiff base (SB). Methods: SB-CuO-NPs were characterized using ultraviolet-visible (UV-Vis) spectroscopy, zeta potential, DLS analysis, and transmission electron microscope (TEM). It also focuses on assessing the in vitro biological applications and activities, including antioxidant, scavenging, anti-diabetic, anti-Alzheimer, anti-arthritic, anti-inflammatory, cytotoxic activities, and enzymes inhibitory potential, of Schiff base-synthesized copper oxide nanoparticles (SB-CuO-NPs) and a Schiff base (SB) using methods described in the literature. Results: The results of the biological activities of the SB-CuO-NPs were compared with those of the SB. The SB-CuO-NPs demonstrated superior in vitro biological activities when compared to the SB from which they were produced. Conclusions: The results of this investigation concluded that the CuO-NPs, synthesized with the SB serving as an alternative capping agent, exhibited enhanced biological efficacy relative to the original SB. In the future, the biological efficiency of SB-CuO-NPs against diabetes, Alzheimer's, and cancer diseases will be assessed in experimental animals (in vivo).

Nanomedicine and Its Role in Surgical Wound Infections: A Practical Approach

Surgical wound infections are a major cause of postoperative complications, contributing to surgical morbidity and mortality. With the rise of antibiotic-resistant pathogens, it is crucial to develop new innovative wound materials to manage surgical wound infections using methods that facilitate drug delivery agents and rely on materials other than antimicrobials. Nanoparticles, in particular, have captured researchers' interest in recent years due to their effectiveness in wound care. They can be classified into three main types: inorganic nanoparticles, lipid-based nanoparticles, and polymeric nanoparticles. Several studies have demonstrated the effectiveness of these new technologies in enhancing wound-healing times and reducing bacterial burden. However, further research is essential to thoroughly evaluate the safety and toxicity of these materials before they can be integrated into routine surgical practice.

Present and future of cancer nano-immunotherapy: opportunities, obstacles and challenges

Clinically, multimodal therapies are adopted worldwide for the management of cancer, which continues to be a leading cause of death. In recent years, immunotherapy has firmly established itself as a new paradigm in cancer care that activates the body's immune defense to cope with cancer. Immunotherapy has resulted in significant breakthroughs in the treatment of stubborn tumors, dramatically improving the clinical outcome of cancer patients. Multiple forms of cancer immunotherapy, including immune checkpoint inhibitors (ICIs), adoptive cell therapy and cancer vaccines, have become widely available. However, the effectiveness of these immunotherapies is not much satisfying. Many cancer patients do not respond to immunotherapy, and disease recurrence appears to be unavoidable because of the rapidly evolving resistance. Moreover, immunotherapies can give rise to severe off-target immune-related adverse events. Strategies to remove these hindrances mainly focus on the development of combinatorial therapies or the exploitation of novel immunotherapeutic mediations. Nanomaterials carrying anticancer agents to the target site are considered as practical approaches for cancer treatment. Nanomedicine combined with immunotherapies offers the possibility to potentiate systemic antitumor immunity and to facilitate selective cytotoxicity against cancer cells in an effective and safe manner. A myriad of nano-enabled cancer immunotherapies are currently under clinical investigation. Owing to gaps between preclinical and clinical studies, nano-immunotherapy faces multiple challenges, including the biosafety of nanomaterials and clinical trial design. In this review, we provide an overview of cancer immunotherapy and summarize the evidence indicating how nanomedicine-based approaches increase the efficacy of immunotherapies. We also discuss the key challenges that have emerged in the era of nanotechnology-based cancer immunotherapy. Taken together, combination nano-immunotherapy is drawing increasing attention, and it is anticipated that the combined treatment will achieve the desired success in clinical cancer therapy.

Therapeutic potential of seaweeds and their biofabricated nanoparticles in treating urolithiasis: A review

Urolithiasis affects a significant portion of the global population, causing discomfort and pain. Unfortunately, effective drugs to treat this disorder are currently unavailable due to multiple mechanisms and an incomplete understanding of its causes. Consequently, drugs with multiple targets could be a safer and more effective remedy for treating urolithiasis. Moreover, the current treatment options are expensive and come with a risk of complications and stone recurrence. Therefore, an alternative treatment that can prevent stone recurrence and reduce associated symptoms is necessary. Seaweeds are a rich source of beneficial metabolites, like antioxidants, anti-inflammatory, analgesic, and enzyme-inhibitory properties. Advances in nanotechnology hold great promise for improving the therapeutic potential of these metabolites. However, the use of nanoparticles for treating urolithiasis has yet to be explored well, and only a few reports exist on the use of terrestrial plant-based nanoparticles. This review examines the therapeutic properties of seaweed bioactive compounds and their possible applications in treating urolithiasis. We propose that seaweeds could be an excellent source of essential dietary minerals and other bioactive compounds with multiple targets to treat renal calculus naturally. Additionally, the review highlights the potential of nanomedicine in treating urolithiasis, proposing seaweed-based nanoparticles as a promising treatment option.

Nanotechnology and nanobots unleashed: pioneering a new era in gynecological cancer management - a comprehensive review

INTRODUCTION

Gynecological cancers, such as ovarian, cervical, and endometrial malignancies, are notoriously challenging due to their intricate biology and the critical need for precise diagnostic and therapeutic approaches. In recent years, groundbreaking advances in nanotechnology and nanobots have emerged as game-changers in this arena, offering the promise of a new paradigm in cancer management. This comprehensive review delves into the revolutionary potential of these technologies, showcasing their ability to transform the landscape of gynecological oncology.

METHODOLOGY

A systematic literature search spanning from March 2005 to August 2024 was conducted using major databases such as PubMed, Google Scholar, and Scopus. Keywords included "nanotechnology," "nanobots," "gynecological cancers," "ovarian cancer," "cervical cancer," and "endometrial cancer." Relevant articles published in English were selected based on their focus on nanotechnology and nanobots in the diagnosis, treatment, and management of gynecological cancers. The findings were synthesized to present a coherent overview of how nanotechnology and nanobots are reshaping gynecological cancer management. The review highlights key innovations, current applications, and future directions for research and clinical implementation.

CONCLUSION

The integration of nanotechnology and nanobots in gynecological cancer management represents a groundbreaking shift in the field. Recent advancements in nanoscale materials and robotic technology offer unprecedented opportunities for precision diagnosis, targeted drug delivery, and innovative therapeutic approaches. Despite promising developments, challenges such as biocompatibility, safety, and regulatory issues remain. Continued research and clinical trials are essential to overcome these hurdles and fully realize the potential of nanotechnology and nanobots.

Natural polymer derivative-based pH-responsive nanoformulations with entrapped diketo-tautomers of 5-fluorouracil for enhanced cancer therapy

Background and purpose

Despite significant advancements in cancer therapies, chemotherapeutics continue to be the mainstay for treating cancer patients, with 5-fluorouracil (5-FU) being commonly used for various cancers. However, its limited ability to penetrate cell membranes and its short half-life, caused by rapid metabolism, necessitate frequent administration of high doses to maintain effective therapeutic levels. This study aimed to synthesize oxidized sodium alginate (OSA) derivatives to create OSA nanoparticles loaded with 5-FU (OSANP@ 5-FU), promoting diketo tautomers, and evaluate their photophysical properties, release profile, and anticancer activity with minimal toxicity.

Experimental approach

The investigation encompassed physicochemical characterization, encapsulation efficiency, 5-FU release kinetics at pH 2.2 and 7.4, cell viability assessment via MTT assay in V79 cells, and in vitro anticancer efficacy in the A375 cell line.

Key results

Steady-state absorption and emission confirmed the presence of advantageous diketone tautomers of 5-FU, indicating radiative transitions from the second singlet excited state to the ground state (S2→S0) and the drug's encapsulation within the polymeric nanostructure. Dynamic light scattering revealed that OSA nanoparticles, initially 177.8 nm, grew to 226.6 nm after encapsulating 5-FU, retaining high zeta potential for stability. With a 68% encapsulation efficiency, in vitro studies showed 46 to 54 % of 5-FU released across different pH levels within 510 minutes.

Conclusion

In acidic conditions, there is a greater release of 5-FU than neutral pH levels, indicating a pH-responsive release profile beneficial for cancer treatment, with the release mechanism of OSANPs following Fickian diffusion as identified by a Korsmeyer-Peppas mathematical model and the formulation showing improved therapeutic efficacy.

The Role of Nanomaterials in Diagnosis and Targeted Drug Delivery

Nanomaterials have evolved into the most useful resources in all spheres of life. Their small size imparts them with unique properties and they can also be designed and engineered according to the specific need. The use of nanoparticles (NPs) in medicine is particularly quite revolutionary as it has opened new therapeutic avenues to diagnose, treat and manage diseases in an efficient and timely manner. The review article presents the biomedical applications of nanomaterials including bioimaging, magnetic hypothermia and photoablation therapy, with a particular focus on disease diagnosis and targeted drug delivery. Nanobiosensors are highly specific and can be delivered into cells to investigate important biomarkers. They are also used for targeted drug delivery and deliver theranostic agents to specific sites of interest. Other than these factors, the review also explores the role of nano-based drug delivery systems for the management and treatment of nervous system disorders, tuberculosis and orthopaedics. The nano-capsulated drugs can be transported by blood to the targeted site for a sustained release over a prolonged period. Some other applications like their role in invasive surgery, photodynamic therapy and quantum dot imaging have also been explored. Despite that, the safety concerns related to nanomedicine are also pertinent to comprehend as well as the biodistribution of NPs in the body and the mechanistic insight.

Nanomedicine and clinical diagnostics part I: applications in conventional imaging (MRI, X-ray/CT, and ultrasound)

Integrating nanotechnologies in diagnostic imaging presents a promising step forward compared to traditional methods, which carry certain limitations. Conventional imaging routes, such as X-ray/computed tomography and magnetic resonance imaging, derive significant advantages from nanoparticles (NPs), which allow researchers and clinicians to overcome some of the limitations of traditional imaging agents. In this literature review, we explore recent advancements in nanomaterials being applied in conventional diagnostic imaging techniques by exploring relevant reviews and original research papers (e.g. experimental models and theoretical model studies) in the literature. Collectively, there are numerous nanomaterials currently being examined for use in conventional imaging modalities, and each imaging technique has unique NPs with properties that can be manipulated to answer an array of clinical questions specific to that imaging modality. There are still challenges to consider, including getting regulatory approval for clinical research and routine use about long-term biocompatibility, which collectively emphasize the need for continued research to facilitate the integration of nanotechnology into routine clinical practice. Most importantly, there is a continued need for strong, collaborative efforts between researchers, biomedical engineers, clinicians, and industry stakeholders, which are necessary to bridge the persistent gap between translational ideas and implementation in clinical settings.

Nanotechnology applications in oral pathology: A scoping review

Developments in tissue engineering, diagnosis, and therapy of oral diseases can be made possible by nanotechnology. The purpose of this scoping review was to assess the state of nanotechnology applications in oral pathology at the moment. A thorough search for research published between 2000 and 2024 was done using various online data bases. Relevant studies were identified, screened, and included in accordance with the Preferred Reporting Items of Systematic Reviews and Meta-Analyses (PRISMA) guidelines standards as per the selection criterion. A total of 57 studies satisfied the requirements for inclusion. Significant findings show that in oral disease, nanotechnology greatly enhances treatment delivery, regeneration capacity, and diagnostic accuracy. Among the most promising tools identified were nanofibers, liposomes, quantum dots, and gold nanoparticles. In the field of oral pathology, nanotechnology has great potential for novel approaches to early diagnosis, targeted therapy, and tissue regeneration. However, additional investigation are needed to solve safety and biocompatibility challenges.

Nanotherapeutic and Nano-Bio Interface for Regeneration and Healing

Wound and injury healing processes are intricate and multifaceted, involving a sequence of events from coagulation to scar tissue formation. Effective wound management is crucial for achieving favorable clinical outcomes. Understanding the cellular and molecular mechanisms underlying wound healing, inflammation, and regeneration is essential for developing innovative therapeutics. This review explored the interplay of cellular and molecular processes contributing to wound healing, focusing on inflammation, innervation, angiogenesis, and the role of cell surface adhesion molecules. Additionally, it delved into the significance of calcium signaling in skeletal muscle regeneration and its implications for regenerative medicine. Furthermore, the therapeutic targeting of cellular senescence for long-term wound healing was discussed. The integration of cutting-edge technologies, such as quantitative imaging and computational modeling, has revolutionized the current approach of wound healing dynamics. The review also highlighted the role of nanotechnology in tissue engineering and regenerative medicine, particularly in the development of nanomaterials and nano-bio tools for promoting wound regeneration. Moreover, emerging nano-bio interfaces facilitate the efficient transport of biomolecules crucial for regeneration. Overall, this review provided insights into the cellular and molecular mechanisms of wound healing and regeneration, emphasizing the significance of interdisciplinary approaches and innovative technologies in advancing regenerative therapies. Through harnessing the potential of nanoparticles, bio-mimetic matrices, and scaffolds, regenerative medicine offers promising avenues for restoring damaged tissues with unparalleled precision and efficacy. This pursuit marks a significant departure from traditional approaches, offering promising avenues for addressing longstanding challenges in cellular and tissue repair, thereby significantly contributing to the advancement of regenerative medicine.

Antifungal Activity of Newly Formed Polymethylmethacrylate (PMMA) Modification by Zinc Oxide and Zinc Oxide-Silver Hybrid Nanoparticles

Incorporating nanoparticles into denture materials shows promise for the prevention of denture-associated fungal infections. This study investigates the antifungal properties of acrylic modified with microwave-sintered ZnO-Ag nanoparticles. ZnO-Ag nanoparticles (1% and 2.5% wt.) were synthesized via microwave solvothermal synthesis (MSS). Nanoparticles were characterized for phase purity, specific surface area (SSA), density, morphology, and elemental composition. ZnO and ZnO-Ag nanoparticles were added to acrylic material (PMMA) at concentrations of 1% and 2.5% and polymerized. Pure PMMA (control) and obtained PMMA-nanocomposites were cut into homogeneous 10 × 10 mm samples. Antifungal activity of nanoparticles and PMMA-nanocomposites against C. albicans was tested using minimal inhibitory concentration (MIC) determination, and biofilm formation was assessed using crystal violet staining followed by absorbance measurements. Laboratory tests confirmed phase purity and uniform, spherical particle distribution. MIC results show antifungal activity of 1% Ag nanoparticles and the PMMA-2.5% (ZnO-1% Ag) nanocomposite. PMMA-1% (ZnO-1% Ag) nanocomposite and 1% ZnO-Ag nanoparticles are efficient in preventing biofilm formation. However, ZnO nanoparticles showed antibiofilm activity, and the PMMA-ZnO nanocomposite does not protect against biofilm deposition. Incorporating hybrid ZnO-Ag nanoparticles into PMMA is a promising antibiofilm method, especially with ZnO-1% Ag nanoparticles.

CRISPR/Cas system and its application in the diagnosis of animal infectious diseases

Infectious diseases are a serious threat to the existence of animals and humans' life. In the 21st century, the emergence and re-emergence of several zoonotic and non-zoonotic global pandemic diseases of socio-economic importance has affected billions of humans and animals. The need for expensive equipment and laboratories, non-availability of on-site testing abilities, with time-consuming and low sensitivity and specificity issues of currently available diagnostic techniques to identify these pathogenic micro-organisms on a large scale highlighted the need for developing cheap, portable environment friendly diagnostic methods. In recent years, these issues have been addressed by clustered regularly interspaced palindromic repeats (CRISPR)-based diagnostic platforms that have transformed the molecular diagnostic field due to their outstanding ultra-sensitive nucleic acid detecting capabilities. In this study, we highlight the types, potential of different Cas proteins, and amplification systems. We also illuminate the application of currently available CRISPR integrated setups on the diagnosis of infectious diseases, majorly in food-producing animals (pigs, ruminants, poultry, and aquaculture), domestic pets (dogs and cats), and diseases of zoonotic importance. We conclude the challenges and future perspectives of using these systems to rapidly diagnose and treat other infectious diseases and also develop control strategies to prevent the spread of pathogenic organisms.

A Comprehensive Review: Mesoporous Silica Nanoparticles Greatly Improve Pharmacological Effectiveness of Phytoconstituent in Plant Extracts

Medicinal plants are increasingly being explored due to their possible pharmacological properties and minimal adverse effects. However, low bioavailability and stability often limit efficacy, necessitating high oral doses to achieve therapeutic levels in the bloodstream. Mesoporous silica nanoparticles (MSNs) offer a potential solution to these limitations. Due to their large surface area, substantial pore volume, and ability to precisely control pore size. MSNs are also capable of efficiently incorporating a wide range of therapeutic substances, including herbal plant extracts, leading to potential use for drug containment and delivery systems. Therefore, this review aimed to discuss and summarize the successful developments of herbal plant extracts loaded into MSN, focusing on preparation, characterization, and the impact on efficacy. Data were collected from publications on Scopus, PubMed, and Google Scholar databases using the precise keywords "mesoporous silica nanoparticle" and "herbal extract". The results showed that improved phytoconstituent bioavailability, modified release profiles, increased stability, reduced dose and toxicity are the primary benefits of this method. This review offers insights on the significance of integrating MSNs into therapeutic formulations to improve pharmacological characteristics and effectiveness of medicinal plant extracts. Future prospects show favorable potential for therapeutic applications using MSNs combined with herbal medicines for clinical therapy.

Liver-targeting iron oxide nanoparticles and their complexes with plant extracts for biocompatibility

Thanks to their simple synthesis, controlled physical properties, and minimal toxicity, iron oxide nanoparticles (Fe3O4 NPs) are widely used in many biomedical applications (e.g., bioimaging, drug delivery, biosensors, diagnostics, and theranostics). However, the use of NPs does not preclude the possibility of selective toxicity and undesirable effects, including accumulation in tissues and direct interaction with specific biological targets. This study evaluated the biocompatibility of Fe3O4 NPs, Teucrium polium (T. polium) extract, rutin, and the corresponding complexes on the liver tissue of healthy white Wistar rats. The impact profile of the synthesized Fe3O4 NPs (15 ± 4 nm), rutin, T. polium extract, and their complexes on biochemical markers of liver function (ALT, AST, ALP, GGT, HDL, LDL, total cholesterol, total protein, and albumin) and morphological indicators of rat liver was investigated. Fe3O4 NPs, rutin, and T. polium extract do not show direct hepatotoxicity when administered intraperitoneally to rats, unlike their complexes. All agents exert a hypolipidemic effect by lowering LDL, despite maintaining the synthetic functions of the liver. Fe3O4 NPs increase the activity of GPO, which is associated with their peroxidase-like properties. A multifaceted and diverse mechanism of action of all studied samples on the liver of Wistar rats was identified.

Human-Computer Interaction in Healthcare: A Bibliometric Analysis with CiteSpace

BACKGROUND/OBJECTIVES

Studies on the application and exploration of human-computer interaction (HCI) technologies within the healthcare sector have rapidly expanded, showcasing the immense potential of HCI to enhance medical services, elevate patient experiences, and advance health management. Despite this proliferating interest, there is a notable shortage of comprehensive bibliometric analyses dedicated to the application of HCI in healthcare, which limits a thorough comprehension of the growth trends and future trajectories in this area.

METHODS

To bridge this gap, we employed bibliometric methods using the CiteSpace tool to systematically review and analyze the current state and trends of HCI research in healthcare. A meticulous topic search of Web of Science yielded 3598 papers published between 2004 and 2023.

RESULTS

Through literature analysis, the most productive researchers, institutes, and countries/territories and the collaboration networks among authors and countries within the field were analyzed. Additionally, by conducting a co-citation analysis, journals and literature with high citation rates and influence within the academic community in this field were revealed. Through a cluster analysis based on literature co-citations and keyword burst analyses, we further explored the main research themes and hot topics within the fields of healthcare and HCI.

CONCLUSIONS

In summary, through a comprehensive and systematic bibliometric analysis, this study provides a solid knowledge foundation for HCI in the healthcare research community, thereby fostering the development of innovative research and the optimization of practical applications in the field.

Current Combinatorial Therapeutic Aspects: The Future Prospect for Glioblastoma Treatment

There are several types of brain tumors but glioblastoma (GBM) is one of the highly malignant tumors. A primary concern with GBM is that the treatment is inadequate. Even after giving many multi-stacked combinations of therapies to patients, inclusive of chemotherapy, radiation, and surgery, the median survival rate remains poor. Due to its heterogeneous nature, the use of selective therapy for specific targeting of tumor cells is of particular importance. Although many treatment alternatives which include surgery with adjuvant chemotherapy and radiotherapy are available, the prognosis of the disease is very poor. Combination therapy is becoming the foundation of modern antitumor therapy and it is continuously evolving and developing innovative drug regimens as evidenced by ongoing preclinical and clinical trials. In this review, we discuss the current treatment options and emerging therapeutic approaches for the treatment of GBM. The prospects for alternative glioblastoma therapy are also discussed.

Metallic and metallic oxide nanoparticles toxicity primarily targets the mitochondria of hepatocytes and renal cells

Nanoparticles (NPs) are utilized in various applications, posing potential risks to human health, tissues, cells, and macromolecules. This study aimed to investigate the ultrastructural alterations in hepatocytes and renal tubular cells induced by metallic and metal oxide NPs. Adult healthy male Wistar albino rats (Rattus norvegicus) were divided into 6 (n = 7) control and 6 treated groups (n = 7). The rats in the treated groups exposed daily to silver NPs, gold NPs, zinc oxide NPs, silicon dioxide NPs, copper oxide NPs, and ferric oxide NPs for 35 days. The members of the control group for each corresponding NPs received the respective vehicle. Liver and kidney tissue blocks from all rats were processed for Transmission Electron Microscopy (TEM) examinations. The hepatocytes and renal tubular cells of all NPs-treated rats demonstrated mitochondrial ultrastructural alterations mainly cristolysis, swelling, membrane disruption, lucent matrices, matrices lysis, and electron-dense deposits. However, other organelles demonstrated injury but to a lesser extent in the form of shrunken nuclei, nuclear membrane indentation, endoplasmic reticulum fragmentation, cellular membranes enfolding, brush border microvilli disruption, lysosomal hyperplasia, ribosomes dropping, and peroxisome formation. One may conclude from the findings that the hepatocytes and the renal tubular cells mitochondria are the main targets for nanoparticles toxicity ending in mitochondrial disruption and cell injury. Further studies taking into account the relation of mitochondrial ultrastructural damage with a weakened antioxidant defense system induced by chronic exposure to nanomaterials are needed.

Advancements in breast cancer therapy: The promise of copper nanoparticles

BACKGROUND

Breast cancer (BC) is the most prevalent cancer among women worldwide and poses significant treatment challenges. Traditional therapies often lead to adverse side effects and resistance, necessitating innovative approaches for effective management.

OBJECTIVE

This review aims to explore the potential of copper nanoparticles (CuNPs) in enhancing breast cancer therapy through targeted drug delivery, improved imaging, and their antiangiogenic properties.

METHODS

The review synthesizes existing literature on the efficacy of CuNPs in breast cancer treatment, addressing common challenges in nanotechnology, such as nanoparticle toxicity, scalability, and regulatory hurdles. It proposes a novel hybrid method that combines CuNPs with existing therapeutic modalities to optimize treatment outcomes.

RESULTS

CuNPs demonstrate the ability to selectively target cancer cells while sparing healthy tissues, leading to improved therapeutic efficacy. Their unique physicochemical properties facilitate efficient biodistribution and enhanced imaging capabilities. Additionally, CuNPs exhibit antiangiogenic activity, which can inhibit tumor growth by preventing the formation of new blood vessels.

CONCLUSION

The findings suggest that CuNPs represent a promising avenue for advancing breast cancer treatment. By addressing the limitations of current therapies and proposing innovative solutions, this review contributes valuable insights into the future of nanotechnology in oncology.

Bioefficacy of Zinc oxide nanoparticle synthesis and their Biological, Environmental applications from Eranthemum roseum

Synthesis of metal oxide nanoparticles using medicinal plants increasing rapidly due to its eco-friendly to environment. In this study Zinc oxide nanoparticle is synthesized using the leaf extract of plant E. roseum. Synthesized NPs was characterized using UV- Vis Spectroscopy analysis where the peak observed at 374 nm with band gap of 2.5 eV, FTIR and XRD analysis validate pure hexagonal structure, Spherical shape of NPs was confirmed by SEM with EDX analysis and main compounds are zinc 75 % and oxygen 22 %. Transmission Electron Microscopy Analysis confirms the oval shaped ZnO NPs Biological activity of E. roseum ZnO NPs such as antioxidant assay DPPH, ABTS, hydroxyl radical activity shows good inhibition against free radicals. The In-vitro Hypoglycemic effects has maximum inhibition of 96 % on α- amylase activity and 87 % on α- Glycosidase activity. Anti-inflammatory activity recorded 93 % maximum inhibition at Albumin denaturation assay and 75 % at Membrane stabilization assay. E. roseum ZnO NPs shows 67.79 % on HepG2 Anti-proliferative cells line. AO/EtBr staining assays confirms the apoptosis effect. Larvicidal activity shows highest mortality of 98.44 % on species C. quinquefasciatus. Photocatalytic dyedegradation of Methylene blue dye shows 65 % of dye degradation.

The Role of Amphiphilic Compounds in Nasal Nanoparticles

Nasal medications hold significant importance and are widely utilized due to their numerous advantageous properties, offering a compelling route for both local and systemic therapeutic effects. Nowadays, the development of nasal particles under 1 micrometer is in the focus of much scientific research. In our experiments, the use of innovative nanotechnology to increase the effectiveness of the active substance was of paramount importance. Our aim was to create solid nanoparticles that enable targeted and effective delivery of the active ingredient into the body. The innovation of this experimental series lies not only in highlighting the importance of amphiphilic compounds in enhancing penetration, but also in the fact that while most nasally administered formulations are in liquid form, our formulation is solid. Liquid formulations frequently suffer from the disadvantage of possible leakage during administration, which can reduce the bioavailability of the active ingredient. In our experiments we created novel drug delivery systems of finely divided powders, which, thanks to the penetration enhancers, can be successfully administered. These enhancers facilitate the swift disintegration and penetration of the particles through the membrane. This represents a new direction in nasal drug delivery methods. The results of our trials are promising in the development of innovative pharmaceutical products and outline the role of amphiphilic compounds in more efficient utilization and targeted application of active substances. According to our results it can be concluded that this innovative approach not only addresses the common issues associated with liquid nasal formulations but also paves the way for more stable and effective delivery methods. The use of finely divided powders for nasal delivery, enabled by penetration enhancers, represents a major breakthrough in the field, providing a dependable alternative to conventional liquid formulations and ensuring improved therapeutic results.

Nanotechnology in healthcare, and its safety and environmental risks

Nanotechnology holds immense promise in revolutionising healthcare, offering unprecedented opportunities in diagnostics, drug delivery, cancer therapy, and combating infectious diseases. This review explores the multifaceted landscape of nanotechnology in healthcare while addressing the critical aspects of safety and environmental risks associated with its widespread application. Beginning with an introduction to the integration of nanotechnology in healthcare, we first delved into its categorisation and various materials employed, setting the stage for a comprehensive understanding of its potential. We then proceeded to elucidate the diverse healthcare applications of nanotechnology, spanning medical diagnostics, tissue engineering, targeted drug delivery, gene delivery, cancer therapy, and the development of antimicrobial agents. The discussion extended to the current situation surrounding the clinical translation and commercialisation of these cutting-edge technologies, focusing on the nanotechnology-based healthcare products that have been approved globally to date. We also discussed the safety considerations of nanomaterials, both in terms of human health and environmental impact. We presented the in vivo health risks associated with nanomaterial exposure, in relation with transport mechanisms, oxidative stress, and physical interactions. Moreover, we highlighted the environmental risks, acknowledging the potential implications on ecosystems and biodiversity. Lastly, we strived to offer insights into the current regulatory landscape governing nanotechnology in healthcare across different regions globally. By synthesising these diverse perspectives, we underscore the imperative of balancing innovation with safety and environmental stewardship, while charting a path forward for the responsible integration of nanotechnology in healthcare.

Cutting-edge advances in nano/biomedicine: A review on transforming thrombolytic therapy

Thrombotic blockages within blood vessels give rise to critical cardiovascular disorders, including ischemic stroke, venous thromboembolism, and myocardial infarction. The current approach to the therapy of thrombolysis involves administering Plasminogen Activators (PA), but it is hindered by fast drug elimination, narrow treatment window, and the potential for bleeding complications. Leveraging nanomedicine to encapsulate and deliver PA offers a solution by improving the efficacy of therapy, safeguarding the medicine from proteinase biodegradation, and reducing unwanted effects in in vivo trials. In this review, we delve into the underlying venous as well as arterial thrombus pathophysiology and provide an overview of clinically approved PA used to address acute thrombotic conditions. We explore the existing challenges and potential directions within recent pivotal research on a variety of targeted nanocarriers, such as lipid, polymeric, inorganic, and biological carriers, designed for precise delivery of PA to specific sites. We also discuss the promising role of microbubbles and ultrasound-assisted Sono thrombolysis, which have exhibited enhanced thrombolysis in clinical studies. Furthermore, our review delves into approaches for the strategic development of nano-based carriers tailored for targeting thrombolytic action and efficient encapsulation of PA, considering the intricate interaction in biology systems as well as nanomaterials. In conclusion, the field of nanomedicine offers a valuable method for the exact and effective therapy of severe thrombus conditions, presenting a pathway toward improved patient outcomes and reduced complications.

Exploring the therapeutic applications of nano-therapy of encapsulated cisplatin and anthocyanin-loaded multiwalled carbon nanotubes coated with chitosan-conjugated folic acid in targeting breast and liver cancers

This study aimed to assess the targeted nano-therapy of encapsulated cisplatin (Cis) and anthocyanin (Ant)-loaded multiwalled carbon nanotubes (CNT) coated with chitosan conjugated folic acid on breast MCF7 and liver HepG2 cancer cells. Zeta potential, UV-spectroscopy, FTIR, TEM, and SEM were used to evaluate CNT, its modified form (CNT Mod), CNT-loaded Cis NPs, CNT-loaded Ant NPs, and CNT- Cis + Ant NPs. All treatments induced apoptosis-dependent cytotoxicity in both cell lines as revealed functionally by the MTT assay, morphologically (DNA degradation) by acridine orange/ethidium bromide (AO/EB) double staining, and molecularly (Bax upregulation and Bcl2 downregulation) by real-time PCR, with best effect for the combined treatment (CNT- Cis + Ant NPs). This combined treatment also significantly reduced inflammation (low TNFα), migration (low MMP9 and high TIMP1), and angiogenesis (low VEGF), while significantly increasing antioxidant status (high Nrf2 and OH-1) in MCF7 and HepG2 cells compared to other treatments. Interestingly, cells treated with CNT Mod exhibited higher cytotoxic, apoptotic, anti-migratory, and anti-angiogenic potentials relative to CNT-treated cells. In conclusion, targeted nano-therapy of encapsulated cisplatin and anthocyanin-loaded carbon nanotubes coated with chitosan conjugated folic acid can efficiently combat breast and liver cancers by sustained release, in addition to its apoptotic, antioxidant, anti-inflammatory, anti-metastatic, and anti-angiogenic effects.

The Role of Nanoparticles in Accelerating Tissue Recovery and Inflammation Control in Physiotherapy Practices

Physiotherapy has significantly evolved since its inception in the late 19th century, expanding into various specializations such as sports, neurology, and wound care. Its primary goal is to restore or enhance bodily functions through therapeutic interventions, aiding in conditions ranging from injuries to chronic pain. Tissue recovery, which involves repair and regeneration, is a critical aspect of physiotherapy. This natural process is influenced by factors like inflammation and injury severity. Nanotechnology, a relatively recent advancement, has transformed medicine, including wound care, through innovations in drug delivery, diagnostics, and anti-inflammatory treatments. Nanoparticles, owing to their small size and enhanced bioavailability, play a crucial role in improving drug delivery, increasing the efficacy of treatments, and promoting faster recovery. In the context of tissue healing, nanoparticles aid in cell proliferation, inflammation control, and scar reduction, among other therapeutic benefits. They are increasingly used in physiotherapy applications, to support tissue regeneration and inflammation management. This review examines the role of nanoparticles in physiotherapy, with a focus on their application in wound healing, muscle recovery, and inflammation control. It discusses various in-vitro and in-vivo studies that have explored the therapeutic potential of nanoparticles in these domains, providing insights into their mechanisms of action and effectiveness in promoting tissue regeneration and managing inflammation in physiotherapy settings.