Synergistic co-loading of vincristine improved chemotherapeutic potential of pegylated liposomal doxorubicin against triple negative breast cancer and non-small cell lung cancer.

The current work aims to explore the biological characteristics of vincristine synergistic co-loading into pegylated liposomal doxorubicin in non-indicated modalities of non-small cell lung cancer (NSCLC) and triple negative breast cancer (TNBC). The combinatorial liposome prepared by active co-loading of the drugs against modified ammonium ion gradient exhibited 95% encapsulation of both drugs. The cellular uptake studies using confocal microscopy and flow cytometry showed significantly increased uptake of dual drug formulation as against liposomal doxorubicin. The co-loaded liposome formulation had significantly increased cell cycle arrest in G2/M phase with subsequent apoptosis and reduced cell viability in both tumor cell lines than doxorubicin liposome. This carrier exhibited similar acute toxicity, pharmacokinetic and tissue distribution profiles with significant increase in tumor regression as compared to liposomal doxorubicin. These results indicate that co-encapsulation of vincristine into clinically used pegylated liposomal doxorubicin significantly improved in-vitro and in-vivo therapeutic efficacy against NSCLC and TNBC.

IGF-II-Conjugated Nanocarrier for Brain-Targeted Delivery of p11 Gene for Depression.

Gene therapy involving p11 cDNA has been thought to be a futuristic approach for the effective management of depression as the existing treatment regimen presents many issues regarding late onset of action, patient withdrawal and their side effects. For the effective transfection of p11 gene intracellularly, two cationic lipids based on phospholipid DOPE conjugated to basic amino acids histidine and arginine were synthesised, used for liposome formulation and evaluated for their ability as gene delivery vectors. They were further converted using IGF-II mAb into immunoliposomes for CNS targeting and mAb conjugation to liposomes were characterised by SDS-PAGE. They were further analysed by in vitro characterisation studies that include erythrocyte aggregation study, electrolyte-induced study, heparin compatibility study and serum stability studies. SHSY5Y cells were used for conducting cytotoxicity of synthesised lipids and live imaging of cell uptake for 25 min. Finally, the brain distribution studies and western blot were carried out in animals to evaluate them for their BBB permeation ability and effects on p11 protein which is believed to be a culprit. These formulated liposomes from synthesised lipids offer a promising approach for the treatment of depression.

Targeted delivery of monoclonal antibody conjugated docetaxel loaded PLGA nanoparticles into EGFR overexpressed lung tumour cells.

The aim of this study was to develop anti-EGFR antibody conjugated poly(lactide-co-glycolide) nanoparticles (NPs) to target epidermal growth factor receptor, highly expressed on non-small cell lung cancer cells to improve cytotoxicity and site specificity. Cetuximab was conjugated to docetaxel (DTX) loaded PLGA NPs by known EDC/NHS chemistry and characterised for size, zeta potential, conjugation efficiency and the results were 128.4 ± 3.6 nm, -31.0 ± 0.8 mV, and 39.77 ± 3.4%, respectively. In vitro release study demonstrated sustained release of drug from NPs with 25% release at pH 5.5 after 48 h. In vitro cytotoxicity studies demonstrated higher anti-proliferative activity of NPs than unconjugated NPs. Cell cycle analysis and apoptosis study were performed to evaluate extent of cell arrest at different phases and apoptotic potential for the formulations, respectively. In vivo efficacy study showed significant reduction in tumour growth and so antibody conjugated NPs present a promising active targeting carrier for tumour selective therapeutic treatment.

Lipid-Based Oral Formulation Strategies for Lipophilic Drugs.

Partition coefficient (log P) is a key physicochemical characteristic of lipophilic drugs which plays a significant role in formulation development for oral administration. Lipid-based formulation strategies can increase lymphatic transport of these drugs and can enhance bioavailability many folds. The number of lipophilic drugs in pharmacopoeias and under discovery are continuously increasing and making the job of the formulation scientist difficult to develop suitable formulation of these drugs due to potent nature and water insolubility of these drugs. Recently, many natural and synthetic lipids are appearing in the market which are helpful in the development of lipid-based formulations of these types of drugs having enhanced solubility and bioavailability. One such reason for this enhanced bioavailability is the accessibility of the lymphatic transport as well as avoidance of first-pass effect. This review discusses the impact of lipophilicity in enhancing the intestinal lymphatic drug transport thereby reducing first-pass metabolism. The most appropriate strategy for developing a lipid-based formulation depending upon the degree of lipophilicity has been critically discussed and provides information on how to develop optimum formulation. Various formulation strategies are discussed in-depth by classifying lipid-based oral drug delivery systems with case studies of few marketed formulations with challenges and opportunities for the future of the formulations.

Colloidally Stable Small Unilamellar Stearyl Amine Lipoplexes for Effective BMP-9 Gene Delivery to Stem Cells for Osteogenic Differentiation.

The biocompatibility of cationic liposomes has led to their clinical translation in gene delivery and their application apart from cancer to cardiovascular diseases, osteoporosis, metabolic diseases, and more. We have prepared PEGylated stearyl amine (pegSA) lipoplexes meticulously considering the physicochemical properties and formulation parameters to prepare single unilamellar vesicles (SUV) of < 100 nm size which retain their SUV nature upon complexation with pDNA rather than the conventional lipoplexes which show multilamellar nature. The developed PEGylated SA lipoplexes (pegSA lipoplexes) showed a lower N/P ratio (1.5) for BMP-9 gene complexation while maintaining the SUV character with a unique shape (square and triangular lipoplexes). Colloidal and pDNA complexation stability in the presence of electrolytes and serum indicates the suitability for intravenous administration for delivery of lipoplexes to bone marrow mesenchymal stem cells through sinusoidal vessels in bone marrow. Moreover, lower charge density of lipoplexes and low oxidative stress led to lower toxicity of lipoplexes to the C2C12 cells, NIH 3T3 cells, and erythrocytes. Transfection studies showed efficient gene delivery to C2C12 cells inducing osteogenic differentiation through BMP-9 expression as shown by enhanced calcium deposition in vitro, proving the potential of lipoplexes for bone regeneration. In vivo acute toxicity studies further demonstrated safety of the developed lipoplexes. Developed pegSA lipoplexes show potential for further in vivo preclinical evaluation to establish the proof of concept.

cRGD grafted siRNA nano-constructs for chemosensitization of gemcitabine hydrochloride in lung cancer treatment.

PURPOSE: The aim of present investigation was to effectively deliver ribonucleotide reductase subunit 1 (RRM1) targeted siRNA and assess chemo-sensitization of lung cancer cells against Gemcitabine hydrochloride. It was hypothesised that effective and selective delivery of RRM1 siRNA will help in the treatment of lung cancer chemotherapy using Gemcitabine hydrochloride by reducing drug dose and thereby, reduces dose related toxicity of Gemcitabine hydrochloride. METHODS: In this investigation, cRGD grafted siRNA nano-constructs were developed for efficient and targeted intracellular delivery of siRNA. Developed formulations were characterized for gel retardation assay, particle size, zeta potential, cryo transmission electron microscopy, serum stability, in vitro cytotoxicity, qualitative and quantitative cell uptake, gene expression, and chemo-sensitization. RESULTS: Complete complexation of siRNA with cRGD grafted nano-constructs was found at N/P ratio of 2.0. Naked siRNA was found to degrade within 6 h in presence of 50% serum while nano-constructs protected the complexed siRNA even after 24 h. RRM1 level significantly reduced when siRNA was delivered in nano-construct form as compared to naked siRNA. Pre-exposure of RRM1 siRNA decreased the IC50 value of Gemcitabine hydrochloride 5 folds in A-549 cells compared to Gemcitabine hydrochloride alone. CONCLUSION: These results suggest the application of present siRNA delivery strategy to potentiate the chemotherapeutic effect by means of chemosensitization which may be utilized for effective and thorough remission of lung cancer.

Polymer assisted entrapment of netilmicin in PLGA nanoparticles for sustained antibacterial activity.

This study was aimed to develop poly(dl-lactide-co-glycolide) (PLGA) nanoparticle of highly water soluble antibiotic drug, netilmicin sulfate (NS) with improved entrapment efficiency (EE) and antibacterial activity. Dextran sulfate was introduced as helper polymer to form electrostatic complex with NS. Nanoparticles were prepared by double emulsification method and optimized using 2(5-1) fractional factorial design. EE was mainly influenced by dextran sulfate: NS charge ratio and PLGA concentration, whereas particle size (PS) was affected by all factors examined. The optimized NS-loaded-NPs had EE and PS of 93.23 ± 2.7% and 140.83 ± 2.4 nm respectively. NS-loaded-NPs effectively inhibited bacterial growth compared to free NS. Sustained release protected its inactivation and reduced the decline in its killing activity over time even in presence of bronchial cells. A MIC value of 18 µg/mL was observed for NPs on P. aeruginosa. Therefore, NPs with sustained bactericidal efficiency against P. aeruginosa may provide therapeutic benefit in chronic pulmonary infection, like cystic fibrosis.

Brain targeted intranasal delivery of tramadol: comparative study of microemulsion and nanoemulsion.

OBJECTIVE: The present investigation was aimed to develop and compare microemulsion and nanoemulsion for brain targeted intranasal delivery of tramadol to achieve maximum therapeutic efficacy in treatment of episodic and emergency pain. METHODS: Tramadol microemulsion (TME) and tramadol nanoemulsion (TNE) were developed and evaluated for physical properties. Ex vivo diffusion and nasal toxicity of TME and TNE were assessed by using sheep nasal mucosa. Biodistribution, pharmacokinetic and pharmacodynamic studies in mice were also performed. RESULTS: Globule sizes of TME and TNE were 16.69 ± 3.21 and 136.3 ± 4.3 nm, respectively. TNE was found be safe with respect to multiple dosing via nasal route. Both TME and TNE were stable during accelerated stability studies. AUC(0→24) in mice brain for TME and TNE was significantly higher as compared with tramadol solution. TME and TNE displayed significantly higher antinociceptive effect for a period of 16 h as compared with tramadol solution. DISCUSSION: TME and TNE were delivered to brain, circumventing BBB in brisk manner, establishing immediately the minimum effective concentration required for therapeutic response. Significant enhancement in antinociceptive effect was observed after intranasal delivery of TME and TNE. CONCLUSION: Intranasal administration of TME and TNE would be effective in management of episodic and emergency pain treatment.

Protein-functionalized PLGA nanoparticles of lamotrigine for neuropathic pain management.

Lamotrigine (LTG), a sodium and calcium channel blocker, has demonstrated efficacy for the treatment of neuropathic pain in multiple, randomized, controlled trials. However, its potential clinical applications in neuropathic pain are limited due to the risk of dose-dependent severe rashes associated with high dose and prompt dose escalation. Further, the poor pharmacokinetic profile due to non-selective distribution to organs other than brain reduces the efficacy of dosage regimen. Therefore, the aim of present investigation is to develop surface-engineered LTG nanoparticles (NPs) using transferrin and lactoferrin as ligand to deliver higher amount of drug to brain and improve the biodistribution and pharmacokinetic profile of drug with prolonged duration of action and reduced accumulation in non-target organs. The LTG NPs were prepared by nanoprecipitation and optimized by factorial design for high entrapment and optimized particle size. The optimized NPs were surface functionalized by conjugating with the lactoferrin (Lf) and transferrin (Tf) as ligands. The developed NPs were characterized for different physicochemical parameters and stability. The in vivo biodistribution showed preferential targeting to brain and reduced accumulation in non-target organs over a prolonged duration of time. Finally, partial sciatic nerve injury model was used to demonstrate the increased pharmacodynamic response as antinociceptive effect. Both biodistribution and pharmacodynamic study in mice confirmed that the approach used for LTG can help to increase clinical applications of LTG due to brain targeting and reduced side effects.

Polymeric micelle as multifunctional pharmaceutical carriers.

A number of formulations have been developed and reported in literature as a carrier for drug, gene, and diagnostic agents. Amphiphilic block copolymers have achieved increasing attention due to their high stability both in vitro and in vivo and their good biocompatibility. In comparison to other long-circulating nanocarriers, micelles possess a number of advantages such as tissue penetrability, reduced toxicity, and controlled drug release. The characteristic features of micelle as carriers, such as particle size, shape, drug loading, cellular internalization, stability, and release kinetics of drugs can be improved by altering the physicochemical properties of the constituent block copolymers and method of preparation. Polymeric micelles formed from amphiphilic blocks have been successfully used for delivery of drugs that lack water solubility. Chelation or incorporation of a diagnostic agent in ligand conjugated micelle may help in tracing in vivo biodistribution. We review a number of research articles demonstrating that micelle formulations can be used efficiently in clinical situations by taking care of the toxicity of surfactants, and the interaction between polymer and drug, to prepare a formulation carrying a more therapeutic agent with a minimum amount of polymer.

Development and evaluation of oral osmotic pump of butorphanol tartrate.

Butorphanol is potent analgesic useful in pain management. However, because of high first-pass metabolism butorphanol is not available in market as oral dosage form. Drugs that undergo extensive first-pass metabolism can be delivered orally if protected in the stomach, and proximal small intestine. An oral controlled porosity osmotic pump (CPOP) was designed to deliver butorphanol tartrate that can maintain therapeutic blood concentration up to 24 h. The target release profile for extended release formulation was calculated by Wagner Nelson de-convolution using published immediate release blood concentration data for oral route. Composition of the core and coating were optimized using USFDA approved ingredients by evaluation of the drug release. Drug release from the developed system was inversely proportional to the weight gain and directly related to the level of pore former. Scanning electron microscopy (SEM) confirmed the formation of pores in the coating membrane on contact with water which lead to drug to release. Kinetic models were applied to drug release data to establish the drug release mechanism. The developed osmotic system effectively delivers selected drug at a predetermined rate for extended period.

Development and characterization of siRNA lipoplexes: Effect of different lipids, in vitro evaluation in cancerous cell lines and in vivo toxicity study.

Cationic liposomes have long been used as non-viral vectors for small interfering RNA (siRNA) delivery but are associated with high toxicity, less transfection efficiency, and in vivo instability. In this investigation, we have developed siRNA targeted to RRM1 that is responsible for development of resistance to gemcitabine in cancer cells. Effect of different lipid compositions has been evaluated on formation of stable and less toxic lipoplexes. Optimized cationic lipoplex (D2CH) system was comprised of dioleoyl-trimethylammoniumpropane (DOTAP), dioleoyl-sn-glycero-3-phosphoethanolamine (DOPE), hydrogenated soya phosphocholine (HSPC), cholesterol, and methoxy(polyethyleneglycol)2000-1,2-distearoyl-sn-glycero-3-phosphoethanolamine (mPEG2000-DSPE). D2CH lipoplexes have shown particle size (147.5 ± 2.89 nm) and zeta potential (12.26 ± 0.54 mV) characteristics essential for their in vivo use. In vitro cytotoxicity study has shown low toxicity of developed lipoplexes as compared with lipofectamine-2000 up to N/P ratio as high as 7.5. Cell uptake studies and gene expression studies have confirmed intracellular availability of siRNA. In addition, developed lipoplexes also showed ~3 times less hemolytic potential as compared with DOTAP/DOPE lipoplexes at lipid concentration of 5 mg/mL. Lipoplexes also maintained particle size less than 200 nm on exposure to high electrolyte concentration and showed >70% siRNA retention in presence of serum showing siRNA protection conferred by lipoplexes. Furthermore, in vivo acute toxicity studies in mice showed that formulation was non-toxic up to a dosage of 0.75 mg of siRNA/kg as lipoplexes and 300 mg lipid/kg as blank liposomes indicating tolerability of lipoplexes at a dose much higher than required for therapeutic use. Promising results of this study warrant further investigation of developed siRNA lipoplexes for cancer treatment.

Protein functionalized tramadol-loaded PLGA nanoparticles: preparation, optimization, stability and pharmacodynamic studies.

Poly (d,l-lactide-co-glycolide acid) (PLGA) Nanoparticles (NPs) with sustained drug release and enhanced circulation time presents widely explored non-invasive approach for drug delivery to brain. However, blood-brain barrier (BBB) limits the drug delivery to brain. This can be overcome by anchoring endogenous ligand like Transferrin (Tf) and Lactoferrin (Lf) on the surface of NPs, allowing efficient brain delivery via receptor-mediated endocytosis. The aim of the present investigation was preparation, optimization, characterization and comparative evaluation of targeting efficiency of Tf- vs. Lf-conjugated NPs. Tramadol-loaded PLGA NPs were prepared by nanoprecipitation techniques and optimized using 3(3) factorial design. The effect of polymer concentration, stabilizer concentration and organic:aqueous phase ratio were evaluated on particle size (PS) and entrapment efficiency (EE). The formulation was optimized based on desirability for lower PS (<150 nm) and higher EE (>70%). Optimized PLGA NPs were conjugated with Tf and Lf, characterized and evaluated for stability study. Pharmacodynamic study was performed in rat after intravenous administration. The optimized formulation had 100 mg of PLGA, 1% polyvinyl alcohol (PVA) and 1:2 acetone:water ratio. The Lf and Tf conjugation to PLGA NPs was estimated to 186 Tf and 185 Lf molecules per NPs. Lyophilization was optimized at 1:2 ratio of NPs:trehalose. The NPs were found stable for 6 months at refrigerated condition. Pharmacodynamic study demonstrated enhanced efficacy of ligand-conjugated NPs against unconjugated NPs. Conjugated NPs demonstrated significantly higher pharmacological effect over a period of 24 h. Furthermore Lf functionalized NPs exhibited better antinociceptive effect as compared to Tf functionalized NPs.

Fragmented antibodies in non-small cell lung cancer: A novel nano-engineered delivery system for detection and treatment of cancer.

Non-small cell lung cancer (NSCLC) has a long history of defying traditional cytotoxic treatment. Significant advancements in biotechnology, cancer biology, and immunotherapy have provided new insights that have altered the landscape for the management of NSCLC, clearing the way for a new era of pharmaceuticals in the form of monoclonal antibodies and their fragments. Antibody fragments are superior to monoclonal antibodies because of their small size, which allows them to penetrate cells and tissues effectively. When combined with functional nanocarriers, antibody fragments can target cancer cells while offering improved efficacy and fewer off-target effects. We discuss current topics of interest including anti-CTLA-4 mAbs, Talactoferrin alfa (TLF), and the CYFRA 21-1 biomarker, with brief insights into its novel detection system.

In vitro mechanistic study of cell death and in vivo performance evaluation of RGD grafted PEGylated docetaxel liposomes in breast cancer.

Objectives of the investigations were to prepare RGD grafted docetaxel liposomes (RGD-PEG-LP-DC) using supercritical fluid technology and evaluate it in vitro for cytotoxicity, DNA content analysis, mechanism of cell death, and in vivo for pharmacokinetic and biodistribution studies in BALB/c mice. The RGD-PEG-LP-DCs were found to be most cytotoxic in BT-20 and MDA-MB-231 cell lines. The flowcytometry results shows at 48 hours, 96% G2 phase arrest for RGD-PEG-LP-DC at 5 nM drug concentration. The mode of cell death was found to be mainly by necrosis at low drug equivalent concentration (1 nM) and by apoptosis at high drug equivalent concentration (10 nM). With increase in time and concentration the mode of cell death by apoptosis was found to be increasing. Biodistribution demonstrated that site specific drug distribution, t(1/2), and MRT improved significantly for RGD-PEG-LP-DC. From the studies site specific and sustained intracellular drug delivery from RGD-PEG-LP-DCs may provide promising strategy in enhancing embattled against breast cancer treatment. FROM

The in vivo behavior and antitumor activity of doxorubicin-loaded poly(γ-benzyl l-glutamate)-block-hyaluronan polymersomes in Ehrlich ascites tumor-bearing BalB/c mice.

The in vivo efficacy of doxorubicin (DOX)-loaded poly(γ-benzyl l-glutamate)-block-hyaluronan (PBLG(23)-b-HYA(10))-based polymersomes (PolyDOX) was evaluated. Samples were efficiently labeled with technetium-99m radionuclide with good stability for in vivo studies. PolyDOX enhanced circulation time compared to free DOX. Biodistribution studies revealed selective accumulation of PolyDOX in the Ehrlich ascites tumor (EAT) as a result of passive accumulation and active targeting (CD44-mediated endocytosis) in EAT-bearing mice. Toxicity studies demonstrated PolyDOX is a safe drug carrier, and no hemolysis was observed with PolyDOX equivalent to 200 µg/mL of free DOX. PolyDOX dominantly controlled tumor growth by delaying doubling time of EATs compared to free DOX over 30 days after treatment. PolyDOX also increased life span six times more than free DOX. Hence, it is reasonable to expect that higher DOX levels attributable to PolyDOX improve the therapeutic index and reduce side effects due to site-specific drug accumulation. FROM THE CLINICAL EDITOR: In this preclinical project, doxorubicin loaded polymersomes enhanced intracellular uptake of doxorubicin in a murine model of Ehrlich Ascites Tumor (EAT) through CD44 receptor mediated endocytosis, resulting in prolonged Tumor Doubling Time and increase in life span of mice.

Design and pharmacodynamic evaluation of DPK-060 loaded Nanostructured lipid carrier embedded gel for dermal delivery: A novel approach in the treatment of atopic dermatitis.

DPK-060 is a synthetic, 17 amino acid peptide, structurally derived from the human protein kininogen. DPK-060 mainly acts by membrane disruption mechanism, thus demonstrating strong broad-spectrum antimicrobial activity against both gram-positive and gram-negative microbes, including methicillin-resistant S. aureus (MRSA) in-vitro and in-vivo. Apart from its antimicrobial effect, DPK-060 also possesses anti-inflammatory activity. In addition, DPK-060 has demonstrated positive results in phase II clinical trials in atopic dermatitis (AD) patients; but was not statistically conclusive due to the instability of DPK-060 as a drug substance in the formulation. Thus, the present investigation was aimed to assess and compare the efficacy of DPK-060 nanostructured lipid (NLC) based gel with conventional formulations (free DPK-060 gel and lotion) in AD mice animal models. DPK-060 loaded NLCs were formulated by meltemulsification technique and loaded into Carbopol 934 P gel and characterized for various physicochemical parameters such as particle size, zeta-potential, shape and surface morphology, rheological parameters, in-vitro drug release, cytotoxicity, cellular uptake, ex-vivo skin permeation/deposition, in-vitro antimicrobial activity, and proteolytic stability studies. NLCs exhibited 85 % encapsulation with 6.7 % loading efficacy, a size, and zeta potential of 128.6 nm and -22.5 mv, respectively. Additionally, DPK-060 NLC gel demonstrated controlled release and a better permeation profile in comparison to free DPK-060 gel and lotion. A substantial reduction in pro-inflammatory cytokines levels and improvement in AD lesions was achieved by DPK-060 NLC gel compared to free DPK-060 gel and lotion-based formulations. The present study confirms that DPK-060 NLC gel-based formulation can be an effective, safe, and novel alternative for the treatment of AD.

Liposomes encapsulating novel antimicrobial peptide Omiganan: Characterization and its pharmacodynamic evaluation in atopic dermatitis and psoriasis mice model.

Omiganan is a novel 12 amino acid synthetic cationic peptide from the cathelicidin family. Omiganan possesses antimicrobial action against a wide range of microbes, including gram-positive and gram-negative bacteria and fungi. Omiganan mainly acts by depolarizing the cytoplasmic membrane, resulting in cellular disruption and death. Apart from its antimicrobial effect, Omiganan also has anti-inflammatory activity. The present investigation aimed to evaluate and compare the efficacy of Omiganan liposomal gel with conventional formulations (Omiganan gel and lotion) in atopic dermatitis (AD) and psoriasis mice animal models. Liposomes encapsulating Omiganan were prepared using the reverse-phase evaporation technique and incorporated into Carbopol 934P gel. The optimized Omiganan liposomes were then characterized for various physicochemical parameters such as vesicle size, shape and surface morphology, zeta-potential, rheological parameters, in-vitro drug release, ex-vivo skin permeation/deposition, in-vitro antimicrobial activity, proteolytic stability, and cellular toxicity and uptake studies. Liposomes exhibited 72 % encapsulation with 7.8 % loading efficacy, a vesicle size, and zeta potential of 120 nm and - 17.2 mv, respectively. Moreover, Omiganan liposomal gel demonstrated controlled release and a better permeation profile than conventional formulations. A substantial reduction in levels of pro-inflammatory cytokines and improvement in AD and psoriatic lesions were achieved by Omiganan liposomal gel compared to Omiganan gel and lotion-based formulations. The present study confirms that Omiganan liposomal formulation can be an effective, safe, and novel alternative treatment approach in atopic dermatitis and psoriasis.

Transdermal Delivery of Macromolecules Using Nano Lipid Carriers.

Skin being the largest external organ, offers an appealing procedure for transdermal drug delivery, so the drug needs to reach above the outermost layer of the skin, i.e., stratum corneum. Small molecular drug entities obeying the Lipinski rule, i.e., drugs having a molecular weight less than 500 Da, high lipophilicity, and optimum polarity, are favored enough to be used on the skin as therapeutics. Skin's barrier properties prevent the transport of macromolecules at pre-determined therapeutic rates. Notable advancements in macromolecules' transdermal delivery have occurred in recent years. Scientists have opted for liposomes, the use of electroporation, low-frequency ultrasound techniques, etc. Some of these have shown better delivery of macromolecules at clinically beneficial rates. These physical technologies involve complex mechanisms, which may irreversibly incur skin damage. Majorly, two types of lipid-based formulations, including Solid Lipid Nanoparticles (SLNs) and Nanostructured Lipid Carriers (NLCs), are widely investigated as transdermal delivery systems. In this review, the concepts, mechanisms, and applications of nanostructured lipid carriers used to transport macromolecules via transdermal routes are thoroughly reviewed and presented along with their clinical perspective.

Role of lipid nanocarriers for enhancing oral absorption and bioavailability of insulin and GLP-1 receptor agonists.

Growing demand for insulin and glucagon-like peptide-1 receptor agonists (GLP-1 RA) is observed, considering the progressive nature of diabetes and the potential therapeutic role of peptides in its treatment. However, chronic parenteral administration is responsible for pain and rashes at the site of injection. Oral delivery of insulin and GLP-1 RA promises better patient compliance owing to their ease of administration and reduction in chances of peripheral hypoglycaemia and weight gain. The review article discusses the potential of lipid carriers in combination with different strategies such as absorption enhancers, PEGylation, lipidisation, etc. The lipid nanocarriers improve the membrane permeability and oral bioavailability of high molecular weight peptides. Additionally, the clinical status of different nanocarriers for anti-diabetic peptides is discussed. Previous research on nanocarriers showed significant hypoglycaemic activity and safety in animal studies; however, extrapolation of the same in human subjects is not validated. With the rising global burden of diabetes, the lipid nanocarriers show the potential to revolutionise treatment with oral delivery of insulin and GLP-1 RA.