Browsing by Author "Aljabali, Alaa A."

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    Anti-bacterial activity of inorganic nanomaterials and their antimicrobial peptide conjugates against resistant and non-resistant pathogens
    (2020) Pardhi, Dinesh M.; Karaman, Didem Sen; Timonen, Juri; Wu, Wei; Zhang, Qi; Satija, Saurabh; Mehta, Meenu; Charbe, Nitin; McCarron, Paul A.; Tambuwala, Murtaza M.; Bakshi, Hamid A.; Negi, Poonam; Aljabali, Alaa A.; Dua, Kamal; Chellappan, Dinesh K.; Behera, Ajit; Pathak, Kamla; Watharkar, Ritesh B.; Rautio, Jarkko; Rosenholm, Jessica M.
    This review details the antimicrobial applications of inorganic nanomaterials of mostly metallic form, and the augmentation of activity by surface conjugation of peptide ligands. The review is subdivided into three main sections, of which the first describes the antimicrobial activity of inorganic nanomaterials against gram-positive, gram-negative and multidrug-resistant bacterial strains. The second section highlights the range of antimicrobial peptides and the drug resistance strategies employed by bacterial species to counter lethality. The final part discusses the role of antimicrobial peptide-decorated inorganic nanomaterials in the fight against bacterial strains that show resistance. General strategies for the preparation of antimicrobial peptides and their conjugation to nanomaterials are discussed, emphasizing the use of elemental and metallic oxide nanomaterials. Importantly, the permeation of antimicrobial peptides through the bacterial membrane is shown to aid the delivery of nanomaterials into bacterial cells. By judicious use of targeting ligands, the nanomaterial becomes able to differentiate between bacterial and mammalian cells and, thus, reduce side effects. Moreover, peptide conjugation to the surface of a nanomaterial will alter surface chemistry in ways that lead to reduction in toxicity and improvements in biocompatibility.
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    Biomedical applications of three-dimensional bioprinted craniofacial tissue engineering
    (WILEY, 2022) Charbe, Nitin Bharat; Tambuwala, Murtaza; Palakurthi, Sushesh Srivatsa; Warokar, Amol; HronniC-JahjefendiC, Altijana; Bakshi, Hamid; Zacconi, Flavia C. M.; Mishra, Vijay; Khadse, Saurabh; Aljabali, Alaa A.; El-Tanani, Mohamed; Serrano-Aroca, Angel; Palakurthi, Srinath
    Anatomical complications of the craniofacial regions often present considerable challenges to the surgical repair or replacement of the damaged tissues. Surgical repair has its own set of limitations, including scarcity of the donor tissues, immune rejection, use of immune suppressors followed by the surgery, and restriction in restoring the natural aesthetic appeal. Rapid advancement in the field of biomaterials, cell biology, and engineering has helped scientists to create cellularized skeletal muscle-like structures. However, the existing method still has limitations in building large, highly vascular tissue with clinical application. With the advance in the three-dimensional (3D) bioprinting technique, scientists and clinicians now can produce the functional implants of skeletal muscles and bones that are more patient-specific with the perfect match to the architecture of their craniofacial defects. Craniofacial tissue regeneration using 3D bioprinting can manage and eliminate the restrictions of the surgical transplant from the donor site. The concept of creating the new functional tissue, exactly mimicking the anatomical and physiological function of the damaged tissue, looks highly attractive. This is crucial to reduce the donor site morbidity and retain the esthetics. 3D bioprinting can integrate all three essential components of tissue engineering, that is, rehabilitation, reconstruction, and regeneration of the lost craniofacial tissues. Such integration essentially helps to develop the patient-specific treatment plans and damage site-driven creation of the functional implants for the craniofacial defects. This article is the bird's eye view on the latest development and application of 3D bioprinting in the regeneration of the skeletal muscle tissues and their application in restoring the functional abilities of the damaged craniofacial tissue. We also discussed current challenges in craniofacial bone vascularization and gave our view on the future direction, including establishing the interactions between tissue-engineered skeletal muscle and the peripheral nervous system.
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    Dynamics of Prolyl Hydroxylases Levels During Disease Progression in Experimental Colitis
    (2019) Bakshi, Hamid A.; Mishra, Vijay; Satija, Saurabh; Mehta, Meenu; Hakkim, Faruk L.; Kesharwani, Prashant; Dua, Kamal; Chellappan, Dinesh K.; Charbe, Nitin B.; Shrivastava, Garima; Rajeshkumar, S.; Aljabali, Alaa A.; Al-Trad, Bahaa; Pabreja, Kavita; Tambuwala, Murtaza M.
    Hypoxia inducible factor (HIF)-prolyl hydroxylase (PHD) inhibitors are shown to be protective in several models of inflammatory bowel disease (IBD). However, these non-selective inhibitors are known to inhibit all the three isoforms of PHD, i.e. PHD-1, PHD-2 and PHD-3. In the present report, we investigated the associated changes in levels of PHDs during the development and recovery of chemically induced colitis in mice. The results indicated that in the experimental model of murine colitis, levels of both, PHD-1 and PHD-2 were found to be increased with the progression of the disease; however, the level of PHD-3 remained the same in group of healthy controls and mice with colitis. Thus, the findings advocated that inhibitors, which inhibited all three isoforms of PHD could not be ideal therapeutics for IBD since PHD-3 is required for normal gut function. Hence, this necessitates the development of new compounds capable of selectively inhibiting PHD-1 and PHD-2 for effective treatment of IBD.
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    Hypoxia-Inducible Factor (HIF): Fuel for Cancer Progression
    (Bentham Science Publ. LTD, 2021) Satija, Saurabh; Kaur, Harpreet; Tambuwala, Murtaza M.; Sharma, Prabal; Vyas, Manish; Khurana, Navneet; Sharma, Neha; Bakshi, Hamid A.; Charbe, Nitin B.; Zacconi, Flavia C. M.; Aljabali, Alaa A.; Nammi, Srinivas; Dureja, Harish; Singh, Thakur G.; Gupta, Gaurav; Dhanjal, Daljeet S.; Dua, Kamal; Chellappan, Dinesh K.; Mehta, Meenu
    Hypoxia is an integral part of the tumor microenvironment, caused primarily due to rapidly multiplying tumor cells and a lack of proper blood supply. Among the major hypoxic pathways, HIF-1 transcription factor activation is one of the widely investigated pathways in the hypoxic tumor microenvironment (TME). HIF-1 is known to activate several adaptive reactions in response to oxygen deficiency in tumor cells. HIF-1 has two subunits, HIF-1 beta (constitutive) and HIF-1 alpha (inducible). The HIF-1 alpha expression is largely regulated via various cytokines (through PI3K-ACT-mTOR signals), which involves the cascading of several growth factors and oncogenic cascades. These events lead to the loss of cellular tumor suppressant activity through changes in the level of oxygen via oxygen-dependent and oxygen-independent pathways. The significant and crucial role of HIF in cancer progression and its underlying mechanisms have gained much attention lately among the translational researchers in the fields of cancer and biological sciences, which have enabled them to correlate these mechanisms with various other disease modalities. In the present review, we have summarized the key findings related to the role of HIF in the progression of tumors.