Artificial Micromotors in the Mouse’s Stomach: A Step toward in Vivo Use of Synthetic Motors

Artificial micromotors, operating on locally supplied fuels and performing complex tasks, offer great potential for diverse biomedical applications, including autonomous delivery and release of therapeutic payloads and cell manipulation. Various types of synthetic motors, utilizing different propulsion mechanisms, have been fabricated to operate in biological matrices. However, the performance of these man-made motors has been tested exclusively under in vitro conditions (outside the body); their behavior and functionalities in an in vivo environment (inside the body) remain unknown. Herein, we report an in vivo study of artificial micromotors in a living organism using a mouse model. Such in vivo evaluation examines the distribution, retention, cargo delivery, and acute toxicity profile of synthetic motors in mouse stomach via oral administration. Using zinc-based micromotors as a model, we demonstrate that the acid-driven propulsion in the stomach effectively enhances the binding and retention of the motors as well as of cargo payloads on the stomach wall. The body of the motors gradually dissolves in the gastric acid, autonomously releasing their carried payloads, leaving nothing toxic behind. This work is anticipated to significantly advance the emerging field of nano/micromotors and to open the door to in vivo evaluation and clinical applications of these synthetic motors

Artificial Micromotors in the Mouse’s Stomach: A Step toward in Vivo Use of Synthetic Motors

Artificial micromotors, operating on locally supplied fuels and performing complex tasks, offer great potential for diverse biomedical applications, including autonomous delivery and release of therapeutic payloads and cell manipulation. Various types of synthetic motors, utilizing different propulsion mechanisms, have been fabricated to operate in biological matrices. However, the performance of these man-made motors has been tested exclusively under in vitro conditions (outside the body); their behavior and functionalities in an in vivo environment (inside the body) remain unknown. Herein, we report an in vivo study of artificial micromotors in a living organism using a mouse model. Such in vivo evaluation examines the distribution, retention, cargo delivery, and acute toxicity profile of synthetic motors in mouse stomach via oral administration. Using zinc-based micromotors as a model, we demonstrate that the acid-driven propulsion in the stomach effectively enhances the binding and retention of the motors as well as of cargo payloads on the stomach wall. The body of the motors gradually dissolves in the gastric acid, autonomously releasing their carried payloads, leaving nothing toxic behind. This work is anticipated to significantly advance the emerging field of nano/micromotors and to open the door to in vivo evaluation and clinical applications of these synthetic motors

Innovative Methods and Applications in Mucoadhesion Research.

The present review is aimed at elucidating relatively new aspects of mucoadhesion/mucus interaction and related phenomena that emerged from a Mucoadhesion workshop held in Munster on 2-3 September 2015 as a satellite event of the ICCC 13th-EUCHIS 12th. After a brief outline of the new issues, the focus is on mucus description, purification, and mucus/mucin characterization, all steps that are pivotal to the understanding of mucus related phenomena and the choice of the correct mucosal model for in vitro and ex vivo experiments, alternative bio/mucomimetic materials are also presented. Then a selection of preparative techniques and testing methods are described (at molecular as well as micro and macroscale) that may support the pharmaceutical development of mucus interactive systems and assist formulators in the scale-up and industrialization steps. Recent applications of mucoadhesive systems (including medical devices) intended for different routes of administration (oral, gastrointestinal, vaginal, nasal, ocular, and intravesical) and for the treatment of difficult to treat pathologies or the alleviation of symptoms are described

Antimicrobial Nanotherapeutics Against Helicobacter pylori Infection /

Helicobacter pylori (H. pylori) infection with its vast prevalence is responsible for various gastric diseases including gastritis, peptic ulcers, and gastric malignancy. While effective, current treatment regimens are challenged by a fast-declining eradication rate due to the increasing emergence of H. pylori strains resistant to existing antibiotics. Therefore, there is an urgent need to develop novel antibacterial strategies against H. pylori. The first area of this research, we developed a liposomal nanoformulation of linolenic acid (LipoLLA) and evaluated its bactericidal activity against resistant strains of H. pylori. We found that LipoLLA was effective in killing both spiral and dormant forms of the bacteria via disrupting bacterial membranes. LipoLLA eradicated all strains of the bacteria regardless of their antibiotic resistance status. Furthermore, the bacteria did not develop drug resistance toward LipoLLA. Our findings suggest that LipoLLA is a promising antibacterial nanotherapeutic to treat antibiotic-resistant H. pylori infection. The next step, we investigated the in vivo therapeutic potential of LipoLLA for the treatment of H. pylori infection. In vivo tests further confirmed that LipoLLA was able to kill H. pylori and reduce bacterial load in the mouse stomach. LipoLLA treatment was also shown to reduce the levels of proinflammatory cytokines including interleukin-[beta] (IL-1[beta]), IL-6, and tumor necrosis factor alpha, which were otherwise elevated due to the H. pylori infection. Finally, toxicity test demonstrated excellent biocompatibility of LipoLLA to normal mouse stomach. Collectively, results from this work indicate that LipoLLA is a promising, new, effective, and safe therapeutic agent for the treatment of H. pylori infection. The second area is stimuli-responsive liposomes development. By adsorbing small chitosan-modified gold nanoparticles (AuChi) onto the outer surface of liposomes, we show that at gastric pH the liposomes have excellent stability with limited fusion ability and negligible cargo releases. However when the stabilized liposomes are present in an environment with neutral pH, the gold stabilizers detach from the liposomes resulting in free liposomes that can actively fuse with bacterial membranes. The reported liposome system holds a substantial potential for gastric drug delivery; it remains inactive (stable) in the stomach lumen but actively interact with bacteria once reaches the mucus layer of the stomach where the bacteria may reside. Another stimulus that can activate drug release from liposomes is virulence factor released from bacteria themselves. We formulate liposomes with a lipid composition sensitive to bacterium-secreted phospholipase A₂ (PLA₂) degradation and then adsorb AuChi onto their surfaces. The resulting AuChi-stabilized liposomes (AuChi- liposomes) showed prohibited fusion activity and negligible drug leakage. When loaded with doxycycline, AuChi-liposomes effectively inhibit H. pylori growth in vitro. Overall, the design of AuChi-liposomes allows for a smart "on-demand" payload delivery : the more enzymes or bacteria at the infection site, which depends on the severity of infection, the more drug will be released. Given the strong association of PLA₂ with a diverse range of diseases, the present liposomal delivery technique holds broad application potential for tissue microenvironment-responsive drug deliver

Antimicrobial Nanotherapeutics Against Helicobacter pylori Infection /

Helicobacter pylori (H. pylori) infection with its vast prevalence is responsible for various gastric diseases including gastritis, peptic ulcers, and gastric malignancy. While effective, current treatment regimens are challenged by a fast-declining eradication rate due to the increasing emergence of H. pylori strains resistant to existing antibiotics. Therefore, there is an urgent need to develop novel antibacterial strategies against H. pylori. The first area of this research, we developed a liposomal nanoformulation of linolenic acid (LipoLLA) and evaluated its bactericidal activity against resistant strains of H. pylori. We found that LipoLLA was effective in killing both spiral and dormant forms of the bacteria via disrupting bacterial membranes. LipoLLA eradicated all strains of the bacteria regardless of their antibiotic resistance status. Furthermore, the bacteria did not develop drug resistance toward LipoLLA. Our findings suggest that LipoLLA is a promising antibacterial nanotherapeutic to treat antibiotic-resistant H. pylori infection. The next step, we investigated the in vivo therapeutic potential of LipoLLA for the treatment of H. pylori infection. In vivo tests further confirmed that LipoLLA was able to kill H. pylori and reduce bacterial load in the mouse stomach. LipoLLA treatment was also shown to reduce the levels of proinflammatory cytokines including interleukin-[beta] (IL-1[beta]), IL-6, and tumor necrosis factor alpha, which were otherwise elevated due to the H. pylori infection. Finally, toxicity test demonstrated excellent biocompatibility of LipoLLA to normal mouse stomach. Collectively, results from this work indicate that LipoLLA is a promising, new, effective, and safe therapeutic agent for the treatment of H. pylori infection. The second area is stimuli-responsive liposomes development. By adsorbing small chitosan-modified gold nanoparticles (AuChi) onto the outer surface of liposomes, we show that at gastric pH the liposomes have excellent stability with limited fusion ability and negligible cargo releases. However when the stabilized liposomes are present in an environment with neutral pH, the gold stabilizers detach from the liposomes resulting in free liposomes that can actively fuse with bacterial membranes. The reported liposome system holds a substantial potential for gastric drug delivery; it remains inactive (stable) in the stomach lumen but actively interact with bacteria once reaches the mucus layer of the stomach where the bacteria may reside. Another stimulus that can activate drug release from liposomes is virulence factor released from bacteria themselves. We formulate liposomes with a lipid composition sensitive to bacterium-secreted phospholipase A₂ (PLA₂) degradation and then adsorb AuChi onto their surfaces. The resulting AuChi-stabilized liposomes (AuChi- liposomes) showed prohibited fusion activity and negligible drug leakage. When loaded with doxycycline, AuChi-liposomes effectively inhibit H. pylori growth in vitro. Overall, the design of AuChi-liposomes allows for a smart "on-demand" payload delivery : the more enzymes or bacteria at the infection site, which depends on the severity of infection, the more drug will be released. Given the strong association of PLA₂ with a diverse range of diseases, the present liposomal delivery technique holds broad application potential for tissue microenvironment-responsive drug deliver

Cell Membrane-Coated Nanoparticles As an Emerging Antibacterial Vaccine Platform

Nanoparticles have demonstrated unique advantages in enhancing immunotherapy potency and have drawn increasing interest in developing safe and effective vaccine formulations. Recent technological advancement has led to the discovery and development of cell membrane-coated nanoparticles, which combine the rich functionalities of cellular membranes and the engineering flexibility of synthetic nanomaterials. This new class of biomimetic nanoparticles has inspired novel vaccine design strategies with strong potential for modulating antibacterial immunity. This article will review recent progress on using cell membrane-coated nanoparticles for antibacterial vaccination. Specifically, two major development strategies will be discussed, namely (i) vaccination against virulence factors through bacterial toxin sequestration; and (ii) vaccination against pathogens through mimicking bacterial antigen presentation

Coating Nanoparticles with Gastric Epithelial Cell Membrane for Targeted Antibiotic Delivery against Helicobacter pylori

Inspired by the natural pathogen-host interactions and adhesion, this study reports on the development of a novel targeted nanotherapeutics for the treatment of Helicobacter pylori (H. pylori) infection. Specifically, plasma membranes of gastric epithelial cells (e.g. AGS cells) are collected and coated onto antibiotic-loaded polymeric cores, the resulting biomimetic nanoparticles (denoted AGS-NPs) bear the same surface antigens as the source AGS cells and thus have inherent adhesion to H. pylori bacteria. When incubated with H. pylori bacteria in vitro, the AGS-NPs preferentially accumulate on the bacterial surfaces. Using clarithromycin (CLR) as a model antibiotic and a mouse model of H. pylori infection, the CLR-loaded AGS-NPs demonstrate superior therapeutic efficacy as compared the free drug counterpart as well as non-targeted nanoparticle control group. Overall, this work illustrates the promise and strength of using natural host cell membranes to functionalize drug nanocarriers for targeted drug delivery to pathogens that colonize on the host cells. As host-pathogen adhesion represents a common biological event for various types of pathogenic bacteria, the bioinspired nanotherapeutic strategy reported here represents a versatile delivery platform that may be applied to treat numerous infectious diseases

Mechanism of Antibacterial Activity of Liposomal Linolenic Acid against <i>Helicobacter pylori</i>

<div><p><i>Helicobacter pylori</i> infects approximately half of the world population and is a major cause of gastritis, peptic ulcer, and gastric cancer. Moreover, this bacterium has quickly developed resistance to all major antibiotics. Recently, we developed a novel liposomal linolenic acid (LipoLLA) formulation, which showed potent bactericidal activity against several clinical isolated antibiotic-resistant strains of <i>H</i>. <i>pylori</i> including both the spiral and coccoid form. In addition, LipoLLA had superior <i>in vivo</i> efficacy compared to the standard triple therapy. Our data showed that LipoLLA associated with <i>H</i>. <i>pylori</i> cell membrane. Therefore, in this study, we investigated the possible antibacterial mechanism of LipoLLA against <i>H</i>. <i>pylori</i>. The antibacterial activity of LipoLLA (C18:3) was compared to that of liposomal stearic acid (LipoSA, C18:0) and oleic acid (LipoOA, C18:1). LipoLLA showed the most potent bactericidal effect and completely killed <i>H</i>. <i>pylori</i> within 5 min. The permeability of the outer membrane of <i>H</i>. <i>pylori</i> increased when treated with LipoOA and LipoLLA. Moreover, by detecting released adenosine triphosphate (ATP) from bacteria, we found that bacterial plasma membrane of <i>H</i>. <i>pylori</i> treated with LipoLLA exhibited significantly higher permeability than those treated with LipoOA, resulting in bacteria cell death. Furthermore, LipoLLA caused structural changes in the bacterial membrane within 5 min affecting membrane integrity and leading to leakage of cytoplasmic contents, observed by both transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Our findings showing rapid bactericidal effect of LipoLLA suggest it is a very promising new, effective anti-<i>H</i>. <i>pylori</i> agent.</p></div