Mucus-Inspired Self-Healing Hydrogels: A Protective Barrier for Cells against Viral Infection.

Mucus is a dynamic biological hydrogel, composed primarily of the glycoprotein mucin, exhibits unique biophysical properties and forms a barrier protecting cells against a broad-spectrum of viruses. Here, this work develops a polyglycerol sulfate-based dendronized mucin-inspired copolymer (MICP-1) with ≈10% repeating units of activated disulfide as cross-linking sites. Cryo-electron microscopy (Cryo-EM) analysis of MICP-1 reveals an elongated single-chain fiber morphology. MICP-1 shows potential inhibitory activity against many viruses such as herpes simplex virus 1 (HSV-1) and SARS-CoV-2 (including variants such as Delta and Omicron). MICP-1 produces hydrogels with viscoelastic properties similar to healthy human sputum and with tuneable microstructures using linear and branched polyethylene glycol-thiol (PEG-thiol) as cross-linkers. Single particle tracking microrheology, electron paramagnetic resonance (EPR) and cryo-scanning electron microscopy (Cryo-SEM) are used to characterize the network structures. The synthesized hydrogels exhibit self-healing properties, along with viscoelastic properties that are tuneable through reduction. A transwell assay is used to investigate the hydrogel's protective properties against viral infection against HSV-1. Live-cell microscopy confirms that these hydrogels can protect underlying cells from infection by trapping the virus, due to both network morphology and anionic multivalent effects. Overall, this novel mucin-inspired copolymer generates mucus-mimetic hydrogels on a multi-gram scale. These hydrogels can be used as models for disulfide-rich airway mucus research, and as biomaterials.

Peptide-Grafted Nontoxic Cyclodextrins and Nanoparticles against Bacteriophage Infections.

One of the biggest threats for bacteria-based bioreactors in the biotechnology industry is infections caused by bacterial viruses called bacteriophages. More than 70% of companies admitted to encountering this problem. Despite phage infections being such a dangerous and widespread risk, to date, there are no effective methods to avoid them. Here we present a peptide-grafted compounds that irreversibly deactivate bacteriophages and remain safe for bacteria and mammalian cells. The active compounds consist of a core (cyclodextrin or gold nanoparticle) coated with a hydrophobic chain terminated with a peptide selective for bacteriophages. Such peptides were selected via a phage display technique. This approach enables irreversible deactivation of the wide range of T-like phages (including the most dangerous in phage infections, phage T1) at 37 °C in 1 h. We show that our compounds can be used directly inside the environment of the bioreactor, but they are also a safe additive to stocks of antibiotics and expression inducers (such as isopropyl ß-d-1-thiogalactopyranoside, i.e., IPTG) that cannot be autoclaved and are a common source of phage infections.

Selection and re-acclimation of bioprospected acid-tolerant green microalgae suitable for growth at low pH.

For mass culture of photosynthetic green microalgae, industrial flue gases can represent a low-cost resource of CO2. However, flue gases are often avoided, because they often also contain high levels of SO2 and/or NO2, which cause significant acidification of media to below pH 3 due to production of sulfuric and nitric acid. This creates an unsuitable environment for the neutrophilic microalgae commonly used in large-scale commercial production. To address this issue, we have looked at selecting acid-tolerant microalgae via growth at pH 2.5 carried out with samples bioprospected from an active smelter site. Of the eight wild samples collected, one consisting mainly of Coccomyxa sp. grew at pH 2.5 and achieved a density of 640 mg L-1. Furthermore, three previously bioprospected green microalgae from acidic waters (pH 3-4.5) near abandoned mine sites were also re-acclimated down to their in-situ pH environment after approximately 4 years spent at neutral pH. Of those three, an axenic culture of Coccomyxa sp. was the most successful at re-acclimating and achieved the highest density of 293.1 mg L-1 and maximum daily productivity of 38.8 mg L-1 day-1 at pH 3. Re-acclimation of acid-tolerant species is, therefore, achievable when directly placed at their original pH, but gradual reduction in pH is recommended to give the cells time to acclimate.

Estimation of Time Period for Effective Human Inhalational Anthrax Treatment Including Antitoxin Therapy.

INTRODUCTION: Infrequent natural human inhalational anthrax cases coupled with high bioterrorism risk have brought about use of animal models to serve as the basis for approval of novel treatments. For inhalational anthrax, protective antigen (PA) drives much of the mortality, and raxibacumab, an anti-PA monoclonal antibody, has been approved for therapeutic use using the Animal Rule. Given the paucity of human inhalational anthrax clinical data including PA kinetics, the post-exposure period for effective treatment of human disease remains unknown. The objective of this investigation was to extrapolate animal PA kinetics to a conceptual human model to estimate the post-exposure period for effective treatment of human inhalational anthrax. METHODS: Human PA kinetic parameters were extrapolated from reported rabbit and monkey data. PA profiles were simulated with and without antibiotic induced PA clearance to represent antibiotic-sensitive and -resistant infections, respectively. Antitoxin levels equimolar to or greater than concurrent PA levels were considered protective. RESULTS: For antibiotic sensitive infections, treatment with antibiotics alone ≤4 days after spore exposure prevents toxemia. Administration of raxibacumab together with antibiotics protects ≥ 80% of subjects for 3 additional days (7 days post exposure). In the setting of antibiotic resistance, raxibacumab would be protective for at least 6 days post exposure. CONCLUSIONS: Although the animal model of disease does not reflect the potential impact of supportive care (e.g. fluid resuscitation received by critically ill patients) on PA kinetics and raxibacumab PK, the simulations suggest that administration of antitoxin in combination with antibiotics should provide a longer postexposure window for effective treatment than for antibiotics alone. In addition, raxibacumab administration soon after exposure to an antibiotic resistant strain should provide effective treatment.

Bacillus anthracis protective antigen kinetics in inhalation spore-challenged untreated or levofloxacin/ raxibacumab-treated New Zealand white rabbits.

Inhaled Bacillus anthracis spores germinate and the subsequent vegetative growth results in bacteremia and toxin production. Anthrax toxin is tripartite: the lethal factor and edema factor are enzymatic moieties, while the protective antigen (PA) binds to cell receptors and the enzymatic moieties. Antibiotics can control B. anthracis bacteremia, whereas raxibacumab binds PA and blocks lethal toxin effects. This study assessed plasma PA kinetics in rabbits following an inhaled B. anthracis spore challenge. Additionally, at 84 h post-challenge, 42% of challenged rabbits that had survived were treated with either levofloxacin/placebo or levofloxacin/raxibacumab. The profiles were modeled using a modified Gompertz/second exponential growth phase model in untreated rabbits, with added monoexponential PA elimination in treated rabbits. Shorter survival times were related to a higher plateau and a faster increase in PA levels. PA elimination half-lives were 10 and 19 h for the levofloxacin/placebo and levofloxacin/raxibacumab groups, respectively, with the difference attributable to persistent circulating PA-raxibacumab complex. PA kinetics were similar between untreated and treated rabbits, with one exception: treated rabbits had a plateau phase nearly twice as long as that for untreated rabbits. Treated rabbits that succumbed to disease had higher plateau PA levels and shorter plateau duration than surviving treated rabbits.

Population pharmacokinetics and exposure-response of albinterferon alfa-2b.

Albinterferon alfa-2b (albIFN) has been studied for treatment of chronic hepatitis C virus (HCV). A population pharmacokinetics model was developed using nonlinear mixed-effects modeling. Efficacy/safety exposure-response relationships were assessed for subcutaneous albIFN doses (900-1800 µg once every 2 or 4 weeks) administered for either 24 weeks (HCV genotypes 2/3) or 48 weeks (genotype 1), plus daily oral ribavirin. Sustained virologic response (SVR) exposure-response was modeled using logistic regression. Adverse event incidence was tabulated versus exposure quartiles. First-order absorption rate constant (0.0148 h(-1)), apparent clearance (38.9 mL/h), and apparent volume of distribution (11.6 L) had interindividual variances (coefficient of variation) of 21%, 34%, and 24%, respectively. Residual variance estimates were 27% (coefficient of variation) and 1.51 ng/mL (standard deviation). For the only explanatory covariate-body weight-exposure decreased as weight increased. Important SVR predictors included baseline HCV RNA, fibrosis score, and black race (genotype 1); SVR was minimally related to exposure. Most adverse events had similar incidence rates across exposure quartiles. Some adverse events had a higher incidence in the upper exposure quartile without evidence of exposure-response across the lower quartiles. Given the lack of consistent efficacy/safety exposure-response relationships, further investigation is necessary to optimize albIFN dosing.

A phase 1 study of mapatumumab (fully human monoclonal antibody to TRAIL-R1) in patients with advanced solid malignancies.

PURPOSE: Mapatumumab (TRM-1, HGS-ETR1) is a fully human agonistic monoclonal antibody that targets and activates tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) receptor 1 (death receptor 4). Mapatumumab functions like the natural receptor ligand, TRAIL, a tumor necrosis factor superfamily member that is an important mediator of apoptosis in cancer cell lines. Promising preclinical activity with mapatumumab has been observed. EXPERIMENTAL DESIGN: This phase I, open-label, dose-escalation study assessed the tolerability and toxicity profile of > or =2 doses of mapatumumab administered i.v. in patients with advanced solid tumors. Patients received mapatumumab every 28 days until progression or dose-limiting toxicity. RESULTS: There were escalation levels from 0.01 to 20.0 mg/kg. Forty-one patients, 27 female, with a median age of 55 years (range, 23-81) were entered into the study and received 143 courses. The most common diagnoses were colorectal (10 patients) and ovarian cancer (9 patients). Patients received a median of two cycles (range, 1-33). Mapatumumab was well tolerated. Adverse events considered at least possibly related to mapatumumab that occurred most frequently included fatigue (36.2%), hypotension (34.1%), nausea (29.3%), and pyrexia (12.2%). The majority of adverse events were grade 1 or 2. The maximum tolerated dose was not reached. Linear pharmacokinetics was observed for doses up to 0.3 mg/kg and for the 20 mg/kg level, whereas exposure at 3 and 10 mg/kg increased less than proportionally. No objective responses were observed, but 12 patients had stable disease for 1.9 to 29.4 months. CONCLUSIONS: Mapatumumab is well tolerated and further evaluation of this TRAIL-R1 targeting agent is warranted.

Phase 1 and pharmacokinetic study of lexatumumab in patients with advanced cancers.

PURPOSE: To assess the safety and tolerability, pharmacokinetics, and early evidence of antitumor activity of escalating doses of lexatumumab (HGS-ETR2), a fully human agonistic monoclonal antibody which targets and activates the tumor necrosis factor-related apoptosis-inducing ligand receptor 2 (TRAIL-R2) in patients with advanced solid malignancies. EXPERIMENTAL DESIGN: In this phase 1, open label study, patients with advanced solid malignancies were treated with escalating doses of lexatumumab administered i.v. over 30 to 120 min every 21 days. A cohort of four patients, which could be expanded to six patients, was studied at each dose level. The dose-limiting toxicity (DLT) dose was defined as the dose at which the incidence of DLT in the first two cycles was >or=33%. The maximum tolerated dose was defined as the highest dose at which <33% of subjects experienced DLT. The pharmacokinetics and immunogenicity of lexatumumab were also characterized. Tumor specimens from historical or current biopsies, when available, were stained for TRAIL-R2 using immunohistochemistry techniques. RESULTS: Thirty-seven patients received 120 cycles of lexatumumab at doses ranging from 0.1 to 20 mg/kg every 21 days as of May 2006. The 20 mg/kg dose was identified as the DLT dose based on DLTs in three of seven patients treated with this dose; DLTs included asymptomatic elevations of serum amylase, transaminases, and bilirubin. The 10 mg/kg dose cohort was expanded to 12 patients and the 10 mg/kg dose was identified as the maximum tolerated dose. The mean (+/-SD) clearance and apparent terminal half-life values at the 10 mg/kg dose averaged 6.0 (2.9) mL/d/kg and 16.4 (10.9) days, respectively. Twelve patients had durable stable disease that lasted a median of 4.5 months, including three patients with sarcoma having prolonged stable disease (>or=6.7 months). Immunohistochemistry for TRAIL-R2 showed specific staining in >10% of tumor cells for 16 of the 20 evaluable specimens submitted (80%). CONCLUSIONS: Lexatumumab was safe and well tolerated at doses up to and including 10 mg/kg every 21 days. Lexatumumab was associated with sustained stable disease in several patients. Pharmacokinetics were linear over the dose range studied, and consistent with a two-compartment model with first-order elimination from the central compartment. Additional evaluation of this novel apoptosis-inducing agent, particularly in combination with chemotherapy agents, is warranted and ongoing.

Phase I pharmacokinetic and biologic correlative study of mapatumumab, a fully human monoclonal antibody with agonist activity to tumor necrosis factor-related apoptosis-inducing ligand receptor-1.

PURPOSE: To assess the safety, pharmacokinetics, and preliminary evidence of antitumor activity of mapatumumab (HGS-ETR1, TRM-1), a fully human agonist monoclonal antibody directed to the tumor necrosis factor-related apoptosis-inducing ligand receptor-1 (TRAIL-R1). PATIENTS AND METHODS: Patients with advanced solid malignancies were treated with escalating doses of mapatumumab intravenously (IV) administered over 30 to 120 minutes, initially as a single dose and then repetitively. Plasma mapatumumab concentrations were measured and serum was assayed to detect human antimapatumumab antibody formation. Archival tumor specimens were collected to detect the presence of TRAIL-R1 by immunohistochemistry. RESULTS: Forty-nine patients received 158 courses at doses ranging from 0.01 to 10 mg/kg IV. Initially, patients received mapatumumab as a single dose, then every 28 days repetitively, and then 10 mg/kg every 14 days. Mild (grade 1 or 2) fatigue, fever, and myalgia were the most frequently reported nonhematologic adverse events related to mapatumumab, whereas hematologic toxicity was not clinically significant. The mean (+/- standard deviation) clearance and terminal elimination half-life values for mapatumumab at 10 mg/kg every 14 days were 3.7 mL/d/kg (+/- 1.5 mL/d/kg) and 18.8 days (+/- 10.1 days), respectively. TRAIL-R1 was documented in 68% of patients' tumors assayed. Nineteen patients had stable disease, with two lasting 9 months. CONCLUSION: Mapatumumab can be administered safely and feasibly at 10 mg/kg IV every 14 days. The absence of severe toxicities and the attainment of plasma mapatumumab concentrations that are active in preclinical models warrant further disease-directed studies of this agent alone and in combination with chemotherapy in a broad array of tumors.

Influence of coadministration on the pharmacokinetics of azimilide dihydrochloride and digoxin.

The influence of coadministration on digoxin and azimilide pharmacokinetics/pharmacodynamics was assessed in a randomized, 3-way crossover study in 18 healthy men. Serial blood and urine samples were obtained for azimilide and digoxin quantitation. Treatment effects on pharmacokinetics were assessed using analysis of variance. The relationship between azimilide blood concentrations and QT(c) prolongation was characterized by an E(max) model. Effects of coadministration on pharmacodynamics were assessed using a mechanistic-based inhibition model. Azimilide pharmacokinetics was unaffected by digoxin, except for a 36% increase in CL(r) (P = .0325), with no change in CL(o). Digoxin pharmacokinetics was unaffected by azimilide, except for a 21% increase in C(max) (P = .0176) and a 10% increase in AUC(tau) (P = .0121). Digoxin coadministration increased the apparent EC(50) with no effect on E(max), consistent with competitive inhibition (K(i) = 0.899 ng/mL). The pharmacokinetic and pharmacodynamic changes observed upon coadministration were small and are not expected to be clinically important.

Effect of mild and moderate hepatic impairment on azimilide pharmacokinetics following single dose oral administration.

Azimilide dihydrochloride (75-125 mg/day) is currently being developed for use in prolonging the time to recurrence of atrial fibrillation/flutter and for reducing the frequency of shocks in patients with an implantable cardioverting defibrillator. This study investigated the influence of mild and moderate hepatic impairment on azimilide pharmacokinetics. Six subjects each with mild and moderate hepatic impairment (Child-Pugh grades A and B, respectively) were age, weight, smoking status, and gender-matched to a healthy subject (total N = 24). Each subject was administered a single, oral dose of 100 mg azimilide dihydrochloride following an overnight fast. Blood/plasma and urine samples were collected up to 28 days and over 9 days, respectively, and analyzed using HPLC with MS/MS or UV detection. For azimilide, most parameters in subjects with mild to moderate hepatic impairment were within 25% of those observed in matched healthy subjects, with no statistically significant differences observed. For F-1292 (major metabolite in plasma), a significant decrease in AUC was observed in subjects with moderate hepatic impairment, secondary to an increase in renal clearance (CL(r)). Based on these results, no a priori dosage adjustment is required in subjects with mild to moderate hepatic impairment.

Effect of severe renal impairment on the pharmacokinetics of azimilide following single dose oral administration.

AIMS: To assess the influence of severe renal impairment on azimilide pharmacokinetics. METHODS: A single oral dose of 125 mg azimilide dihydrochloride was administered to subjects with normal and severely impaired renal function. Blood and urine samples were collected for 22-28 and 10 days, respectively. RESULTS: Azimilide renal clearance decreased in subjects with renal impairment (mean 14 vs 4.8 ml h-1 kg-1, 95% confidence interval on the ratio 0.23, 0.50). However, no change in any other pharmacokinetic parameter including oral clearance (mean 109 vs 104 ml h-1 kg-1, 95% confidence interval on the ratio 0.67, 1.36) was observed. CONCLUSIONS: Since azimilide blood concentrations are essentially unaffected by renal function, an a priori dosage regimen adjustment is not required in patients with renal impairment.