Department of Pharmacy
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Item Immunocyte Derived Exosomes: Insight into the Potential Chemo-immunotherapeutic Nanocarrier Targeting the Tumor Microenvironment(ACS, 2022-12) Mittal, Anupama“Cancer” is a dreadful immune-pathological condition that is characterized by anti-inflammatory and tumorigenic responses, elicited by the infiltrating immune cells in the vicinity of an uncontrollably proliferative tumor in the tumor microenvironment (TME). The TME offers a conducive microenvironment that supports cancer cell survival by modulating the host immune defense. Recent advancement in exosomal research has shown exosomes, originating from immune cells as well as the cancer cells, have immense potential for suppressing cancer progression and survival in the TME. Additionally, exosomes, irrespective of their diverse sources, have been reported to be efficient nanocarriers for cancer therapeutics with the ability for targeted delivery due to their biogenic nature, ease of cellular uptake, and scope for functionalization with biomolecules like peptides, aptamers, targeting ligands, etc. Immune cell-derived exosomes per se have been found efficacious against cancer owing to their immune-stimulant properties (in either naive or antigen primed form) even without loading any of cancer therapeutics or targeting ligand conjugation. Nevertheless, exosomes are being primarily explored as nanovesicular carriers for therapeutic molecules with different loading and targeting strategies, and the synergism between immunotherapeutic behavior of exosomes and the anticancer effect of the therapeutic molecules is yet to be explored. Hence, this review focuses specifically on the possible strategies to modulate the immunological nature of the source immune cells to obtain immune stimulant exosomes and bring these into the spotlight as chemo-immunotherapeutic nanovesicles, that can easily target and modulate the TME.Item Docetaxel and its nanoformulations: how delivery strategies could impact the therapeutic outcome?(Future Science Group, 2020-09) Mittal, Anupama; Chitkara, DeepakTo overcome problems associated with current conventional formulations of DTX, efforts have been made to develop a variety of DTX-loaded nanosystems. These systems have improved water solubility, bioavailability and antitumor efficacy with a specific accumulation of drugs at tumor sites. Some of the novel DTX nanoformulations, which demonstrated exciting in vivo anticancer efficacy results, have grabbed the attention of pharmaceutical companies and successfully entered clinical trialsItem New strategies for cancer management: how can temozolomide carrier modifications improve its delivery?(Future Science Group, 2017-06) Chitkara, Deepak; Mittal, AnupamaGlioblastoma multiform (GBM) is the most devastating, highly aggressive astrocytic cell neoplasm having a median survival of 12–15 months and a 5-year survival rate of <3% [1]. Surgery along with radiation therapy and/or chemotherapy is the standard treatment strategy for primary brain tumors wherein, the survival advantages are only palliative. Despite clinical and technological advances, a cure for GBM remains elusive due to its diffuse infiltrative pattern of growth (hindering complete surgical resection), cytogenetic heterogeneity (limiting the use of pathway-specific targeted agents) and location (need to cross the blood–brain barrier [BBB]). Temozolomide (TMZ) is the first-line chemotherapy for GBM used in conjunction with radiotherapy or as a single agent for maintenance therapy [1]. It is an imidazotetrazine class DNA alkylating agent that methylates guanine and adenine bases of DNA leading to DNA double-strand breaks, cell cycle arrest and eventual cell death [1]. An autophagy induction leading to cell death has also been reported as a putative mechanism of action of TMZ in cancer cells and GBM patients [2]. Looking at the current therapy for GBM, there is still an unmet medical need resulting due to its inefficient delivery of TMZ to the cancer tissue. Only a modest activity is seen for TMZ, particularly in high-grade gliomas, which is further limited by the development of resistance leaving no viable therapeutic option for recurrent glioblastoma [3]. Further, TMZ is an unstable molecule that undergoes rapid hydrolysis and has significant dose-limiting hematological toxicity that prevents dosage increase [1]. Currently, TMZ is given orally or intravenously (TEMODAR®) at a dose of 75 mg/m2 concomitant with radiotherapy for 49 days followed by 150 mg/m2 (cycle 1) and 200 mg/m2 (cycle 2–6) as a maintenance dose.Item Lipid-polymer hybrid nanocarriers for delivering cancer therapeutics(Elsevier, 2018-02) Chitkara, Deepak; Mittal, AnupamaCancer remained a major cause of death providing diversified challenges in terms of treatment including non-specific toxicity, chemoresistance and relapse. Nanotechnology- based delivery systems grabbed tremendous attention for delivering cancer therapeutics as they provide benefits including controlled drug release, improved biological half-life, reduced toxicity and targeted delivery. Majority of the nanocarriers consists of either a polymer or a lipid component along with other excipients to stabilize the colloidal system. Lipid-based systems provide advantages like better entrapment efficiency, scalability and low- cost raw materials, however, suffer from limitations including instability, a burst release of the drug, and limited surface functionalization. On the other hand, polymeric systems provide an excellent diversity of chemical modifications, stability, controlled release, however limited drug loading capacities and scale up limit their use. Hybrid nanocarriers consisting of lipid and polymer were able to overcome some of these disadvantages while retaining the advantages of both the systems. Designing a stable lipid-polymer hybrid system requires a thorough understanding of the material properties and their behavior in in vitro and in vivo environments. This review highlights the current status and future prospects of lipid-polymer hybrid systems with a particular focus on cancer nanotherapeuticsItem Efficacy of gemcitabine conjugated and miRNA-205 complexed micelles for treatment of advanced pancreatic cancer(Elsevier, 2014-08) Chitkara, Deepak; Mittal, AnupamaClinical effectiveness of gemcitabine in pancreatic cancer is hindered due to its rapid plasma metabolism and development of chemo-resistance. We have previously delineated the significant role of miRNAs in mediating the growth and proliferation of cancer stem cells (CSCs) which in turn result in chemo-resistance, invasion and metastasis. Here, we designed self-assembling, gemcitabine conjugated cationic copolymers for co-delivery of a tumor suppressor miRNA-205 (miR-205) and evaluated their in vivo efficacy in a pancreatic cancer ectopic tumor model developed using gemcitabine resistant MIA PaCa-2R cells. Combination formulations showed mean a particle size of <100 nm and gemcitabine payload of >10% w/w, exhibited miRNA complexation at N/P ratio of 4/1, sustained release of gemcitabine for >10 days, transfection efficiency of >90%, extended miRNA and drug stability in serum. Functional assays in gemcitabine resistant MIA PaCa-2R and CAPAN-1R pancreatic cancer cells revealed that the combination formulations effectively reversed chemo-resistance, invasion and migration. In pancreatic tumor model, the combination formulation treated group showed significant inhibition of tumor growth. Immuno-hiostochemical analysis revealed decreased tumor cell proliferation with increased apoptosis in the animals treated with miR-205 and gemcitabine combination.