Optimizing anidulafungin exposure across a wide adult body size range.

Echinocandins like anidulafungin are first-line therapies for candidemia and invasive candidiasis, but their dosing may be suboptimal in obese patients. Our objective was to quantify anidulafungin exposure in a cohort of adults across a wide body size range to test if body size affects anidulafungin pharmacokinetics (PK). We enrolled 20 adults between the ages of 18 and 80 years, with an equal distribution of patients above and below a body mass index of 30 kg/m2. A single 100-mg dose of anidulafungin was administered, followed by intensive sampling over 72 h. Population PK analysis was used to identify and compare covariates of anidulafungin PK parameters. Monte Carlo simulations were performed to compute the probability of target attainment (PTA) based on alternative dosing regimens. Participants (45% males) had a median (range) age of 45 (21-78) years and a median (range) weight of 82.7 (42.4-208.3) kg. The observed median (range) of AUC0-∞ was 106.4 (51.9, 138.4) mg∙h/L. Lean body weight (LBW) and adjusted body weight (AdjBW) were more influential than weight as covariates of anidulafungin PK parameters. The conventional 100 mg daily maintenance is predicted to have a PTA below 90% in adults with an LBW > 55 kg or an AdjBW > 75 kg. A daily maintenance dose of 150-200 mg is predicted in these heavier adults. Anidulafungin AUC0-∞ declines with increasing body size. A higher maintenance dose will increase the PTA compared to the current approach in obese patients.

Pegylated Liposomal Alendronate Biodistribution, Immune Modulation, and Tumor Growth Inhibition in a Murine Melanoma Model.

While tumor-associated macrophages (TAM) have pro-tumoral activity, the ablation of macrophages in cancer may be undesirable since they also have anti-tumoral functions, including T cell priming and activation against tumor antigens. Alendronate is a potent amino-bisphosphonate that modulates the function of macrophages in vitro, with potential as an immunotherapy if its low systemic bioavailability can be addressed. We repurposed alendronate in a non-leaky and long-circulating liposomal carrier similar to that of the clinically approved pegylated liposomal doxorubicin to facilitate rapid clinical translation. Here, we tested liposomal alendronate (PLA) as an immunotherapeutic agent for cancer in comparison with a standard of care immunotherapy, a PD-1 immune checkpoint inhibitor. We showed that the PLA induced bone marrow-derived murine non-activated macrophages and M2-macrophages to polarize towards an M1-functionality, as evidenced by gene expression, cytokine secretion, and lipidomic profiles. Free alendronate had negligible effects, indicating that liposome encapsulation is necessary for the modulation of macrophage activity. In vivo, the PLA showed significant accumulation in tumor and tumor-draining lymph nodes, sites of tumor immunosuppression that are targets of immunotherapy. The PLA remodeled the tumor microenvironment towards a less immunosuppressive milieu, as indicated by a decrease in TAM and helper T cells, and inhibited the growth of established tumors in the B16-OVA melanoma model. The improved bioavailability and the beneficial effects of PLA on macrophages suggest its potential application as immunotherapy that could synergize with T-cell-targeted therapies and chemotherapies to induce immunogenic cell death. PLA warrants further clinical development, and these clinical trials should incorporate tumor and blood biomarkers or immunophenotyping studies to verify the anti-immunosuppressive effect of PLA in humans.

Phase 1 trial of bemcentinib (BGB324), a first-in-class, selective AXL inhibitor, with docetaxel in patients with previously treated advanced non-small cell lung cancer.

OBJECTIVES: AXL, a transmembrane receptor tyrosine kinase, is highly expressed and associated with poor prognosis in non-small cell lung cancer (NSCLC). Bemcentinib (BGB324), a selective orally bioavailable small molecule AXL inhibitor, synergizes with docetaxel in preclinical models. We performed a phase I trial of bemcentinib plus docetaxel in previously treated advanced NSCLC. MATERIALS AND METHODS: Escalation of two dose levels of bemcentinib (200 mg load × 3 days then 100 mg daily, or 400 mg load × 3 days then 200 mg daily) in combination with docetaxel (60 or 75 mg/m2 every 3 weeks) followed a 3+3 study design. Due to hematologic toxicity, prophylactic G-CSF was added. Bemcentinib monotherapy was administered for one week prior to docetaxel initiation to assess pharmacodynamic and pharmacokinetic effects alone and in combination. Plasma protein biomarker levels were measured. RESULTS: 21 patients were enrolled (median age 62 years, 67% male). Median treatment duration was 2.8 months (range 0.7-10.9 months). The main treatment-related adverse events were neutropenia (86%, 76% ≥G3), diarrhea (57%, 0% ≥G3), fatigue (57%, 5% ≥G3), and nausea (52%, 0% ≥G3). Neutropenic fever occurred in 8 (38%) patients. The maximum tolerated dose was docetaxel 60 mg/m2 with prophylactic G-CSF support plus bemcentinib 400 mg load × 3 days followed by 200 mg daily thereafter. Bemcentinib and docetaxel pharmacokinetics resembled prior monotherapy data. Among 17 patients evaluable for radiographic response, 6 (35%) patients had partial response and 8 (47%) patients had stable disease as best response. Bemcentinib administration was associated with modulation of proteins involved in protein kinase B signaling, reactive oxygen species metabolism, and other processes. CONCLUSION: Bemcentinib plus docetaxel with G-CSF support demonstrates anti-tumor activity in previously treated, advanced NSCLC. The role of AXL inhibition in the treatment of NSCLC remains under investigation.

Combination of triheptanoin with the ketogenic diet in Glucose transporter type 1 deficiency (G1D).

Fuel influx and metabolism replenish carbon lost during normal neural activity. Ketogenic diets studied in epilepsy, dementia and other disorders do not sustain such replenishment because their ketone body derivatives contain four carbon atoms and are thus devoid of this anaplerotic or net carbon donor capacity. Yet, in these diseases carbon depletion is often inferred from cerebral fluorodeoxyglucose-positron emission tomography. Further, ketogenic diets may prove incompletely therapeutic. These deficiencies provide the motivation for complementation with anaplerotic fuel. However, there are few anaplerotic precursors consumable in clinically sufficient quantities besides those that supply glucose. Five-carbon ketones, stemming from metabolism of the food supplement triheptanoin, are anaplerotic. Triheptanoin can favorably affect Glucose transporter type 1 deficiency (G1D), a carbon-deficiency encephalopathy. However, the triheptanoin constituent heptanoate can compete with ketogenic diet-derived octanoate for metabolism in animals. It can also fuel neoglucogenesis, thus preempting ketosis. These uncertainties can be further accentuated by individual variability in ketogenesis. Therefore, human investigation is essential. Consequently, we examined the compatibility of triheptanoin at maximum tolerable dose with the ketogenic diet in 10 G1D individuals using clinical and electroencephalographic analyses, glycemia, and four- and five-carbon ketosis. 4 of 8 of subjects with pre-triheptanoin beta-hydroxybutyrate levels greater than 2 mM demonstrated a significant reduction in ketosis after triheptanoin. Changes in this and the other measures allowed us to deem the two treatments compatible in the same number of individuals, or 50% of persons in significant beta-hydroxybutyrate ketosis. These results inform the development of individualized anaplerotic modifications to the ketogenic diet.ClinicalTrials.gov registration NCT03301532, first registration: 04/10/2017.

Maximum dose, safety, tolerability and ketonemia after triheptanoin in glucose transporter type 1 deficiency (G1D).

Augmentation of anaplerosis, or replenishment of carbon lost during intermediary metabolic transitions, is desirable in energy metabolism defects. Triheptanoin, the triglyceride of 7-carbon heptanoic acid, is anaplerotic via direct oxidation or 5-carbon ketone body generation. In this context, triheptanoin can be used to treat Glucose transporter type 1 deficiency encephalopathy (G1D). An oral triheptanoin dose of 1 g/Kg/day supplies near 35% of the total caloric intake and impacted epilepsy and cognition in G1D. This provided the motivation to establish a maximum, potentially greater dose. Using a 3 + 3 dose-finding approach useful in oncology, we studied three age groups: 4-6, 6.8-10 and 11-16 years old. This allowed us to arrive at a maximum tolerated dose of 45% of daily caloric intake for each group. Safety was ascertained via analytical blood measures. One dose-limiting toxicity, occurring in 1 of 6 subjects, was encountered in the middle age group in the context of frequently reduced gastrointestinal tolerance for all groups. Ketonemia following triheptanoin was determined in another group of G1D subjects. In them, ß-ketopentanoate and ß-hydroxypentanoate concentrations were robustly but variably increased. These results enable the rigorous clinical investigation of triheptanoin in G1D by providing dosing and initial tolerability, safety and ketonemic potential.ClinicalTrials.gov registration: NCT03041363, first registration 02/02/2017.

Recording of pig neuronal activity in the comparative context of the awake human brain.

Gyriform mammals display neurophysiological and neural network activity that other species exhibit only in rudimentary or dissimilar form. However, neural recordings from large mammals such as the pig can be anatomically hindered and pharmacologically suppressed by anesthetics. This curtails comparative inferences. To mitigate these limitations, we set out to modify electrocorticography, intracerebral depth and intracortical recording methods to study the anesthetized pig. In the process, we found that common forms of infused anesthesia such as pentobarbital or midazolam can be neurophysiologic suppressants acting in dose-independent fashion relative to anesthetic dose or brain concentration. Further, we corroborated that standard laboratory conditions may impose electrical interference with specific neural signals. We thus aimed to safeguard neural network integrity and recording fidelity by developing surgical, anesthesia and noise reduction methods and by working inside a newly designed Faraday cage, and evaluated this from the point of view of neurophysiological power spectral density and coherence analyses. We also utilized novel silicon carbide electrodes to minimize mechanical disruption of single-neuron activity. These methods allowed for the preservation of native neurophysiological activity for several hours. Pig electrocorticography recordings were essentially indistinguishable from awake human recordings except for the small segment of electrical activity associated with vision in conscious persons. In addition, single-neuron and paired-pulse stimulation recordings were feasible simultaneously with electrocorticography and depth electrode recordings. The spontaneous and stimulus-elicited neuronal activities thus surveyed can be recorded with a degree of precision similar to that achievable in rodent or any other animal studies and prove as informative as unperturbed human electrocorticography.

Using the HyFlex model to deliver a capstone seminar course.

INTRODUCTION: The HyFlex course structure allows students to attend class in-person or via synchronous videoconferencing technology. This model has been described, but no data are available in pharmacy curricula. METHODS: Students enrolled in Grand Rounds (GR) were eligible. The GR Engagement Assessment Tool (GREAT) measured engagement three times during the semester. Eighteen statements across four domains were rated using a five-point Likert scale (1 = not true at all and 5 = completely true). Free-text responses were collected for qualitative analysis. The primary outcome was the difference in GR engagement between students attending in-person vs. remotely. Descriptive statistics were used for demographic information. Wilcoxon rank-sum tests compared Likert-scale responses between in-person and remote attendance. RESULTS: Surveys included 128 responses from 88 unique students. There were no differences between remote and in-person attendance for the boredom and elaboration domains. In-person students reported listening more intently (median 4, IQR [3,4]; P = .03). In-person students felt the material was more practical (median 4, IQR [4,5]) than remote students (median 4, IQR [3,4]; P = .002) and more applicable to other situations (median 3, IQR [3,5]) than remote students (median 3, IQR [2,4]; P = .04). Qualitative analysis of the entire cohort demonstrated five themes for satisfaction: safety, flexibility, convenience, technology, and professionalism. CONCLUSIONS: There were subtle differences in student engagement or satisfaction using the HyFlex model. This study supports the expansion of this methodology to similar courses where remote instruction is needed.

Oligonucleotides containing abasic threoninol-terpyridine residues as potential artificial ribonucleases.

Artificial ribonucleases, also known as synthetic ribozymes, were synthesized with an internal, stereochemically-pure, abasic threoninol backbone-residue to which the RNA transesterification catalyst copper (II) terpyridine was covalently linked. These oligonucleotide conjugates were constructed to determine if the stereochemistry of the abasic threoninol backbone residue influences the transesterification rate of complementary RNA oligonucleotides. Following synthesis, these compounds were reacted with complementary 28-mer and 159-mer RNA substrates and their relative transesterification efficiencies were determined. The transesterification kinetics were also compared with previously synthesized oligonucleotides that incorporated copper (II) terpyridine via a serinol-residue. It was determined that oligonucleotides that contained copper (II) terpyridine linked via a (2S,3S)-threoninol backbone were more efficient at RNA transesterification than their (2R,3R)-stereoisomer counterpart.

Development and validation of a LC-MS/MS method for quantitation of 3-hydroxypentanoic acid and 3-oxopentanoic acid in human plasma and its application to a clinical study of glucose transporter type I deficiency (G1D) syndrome.

Interest in human and experimental animal metabolism of substrates containing an odd number of carbons capable of fueling the tricarboxylic acid cycle such as heptanoic acid has motivated us to develop and validate a selective and specific liquid chromatographytandem mass spectrometric method for the simultaneous, quantitative determination of the ketone body byproducts 3-hydroxypentanoic acid and 3-oxopentanoic acid in plasma. Human plasma samples were protein-precipitated with methanol containing 0.2% formic acid. Chromatographic resolution was achieved on a Phenomenex Luna C18 column using gradient elution with mobile phases of water containing 0.1% formic acid and methanol containing 0.1% formic acid at 0.3 mL/min flow rate. The retention times of 3-hydroxypentanoic acid, 3-oxopentanoic acid and sulbactam (internal standard) were 3.85, 4.23, and 5.11 min, respectively. Validation was conducted in accordance with United States Food and Drug Administration guidance. The validated range of 3-hydroxypentanoic acid was 0.078-5 µg/mL and 0.156-10 µg/mL for 3-oxopentanoic acid. The method was accurate and precise over this range and exhibited 10-fold dilution integrity in human plasma. Recovery> 88% was achieved for analytes and internal standard. There was no matrix effect observed in human plasma. Both 3-hydroxypentanoic acid and 3-oxopentanoic acid were stable across conditions including autosampler, benchtop and freeze-thaw, as well as demonstrated long-term stability at -80 °C. The method was applied to the measurement of 3-hydroxypentanoic acid and 3-oxopentanoic acid concentrations in plasma from subjects receiving the triglyceride triheptanoin (as a source of heptanoate) for the experimental treatment of glucose transporter type I deficiency (G1D) syndrome.

Itraconazole Exerts Its Antitumor Effect in Esophageal Cancer By Suppressing the HER2/AKT Signaling Pathway.

Itraconazole, an FDA-approved antifungal, has antitumor activity against a variety of cancers. We sought to determine the effects of itraconazole on esophageal cancer and elucidate its mechanism of action. Itraconazole inhibited cell proliferation and induced G1-phase cell-cycle arrest in esophageal squamous cell carcinoma and adenocarcinoma cell lines. Using an unbiased kinase array, we found that itraconazole downregulated protein kinase AKT phosphorylation in OE33 esophageal adenocarcinoma cells. Itraconazole also decreased phosphorylation of downstream ribosomal protein S6, transcriptional expression of the upstream receptor tyrosine kinase HER2, and phosphorylation of upstream PI3K in esophageal cancer cells. Lapatinib, a tyrosine kinase inhibitor that targets HER2, and siRNA-mediated knockdown of HER2 similarly suppressed cancer cell growth in vitro Itraconazole significantly inhibited growth of OE33-derived flank xenografts in mice with detectable levels of itraconazole and its primary metabolite, hydroxyitraconazole, in esophagi and tumors. HER2 total protein and phosphorylation of AKT and S6 proteins were decreased in xenografts from itraconazole-treated mice compared to xenografts from placebo-treated mice. In an early phase I clinical trial (NCT02749513) in patients with esophageal cancer, itraconazole decreased HER2 total protein expression and phosphorylation of AKT and S6 proteins in tumors. These data demonstrate that itraconazole has potent antitumor properties in esophageal cancer, partially through blockade of HER2/AKT signaling.

Assessing the safety of transarterial locoregional delivery of low-density lipoprotein docosahexaenoic acid nanoparticles to the rat liver.

Hepatic-arterial infusion (HAI) of low-density lipoprotein (LDL) nanoparticles reconstituted with docosahexaenoic acid (DHA) (LDL-DHA) has been shown in a rat hepatoma model to be a promising treatment for hepatocellular carcinoma. To date, little is known regarding the safety of HAI of LDL-DHA to the liver. Therefore, we aimed to investigate the deposition, metabolism and safety of HAI of LDL-DHA (2, 4 or 8 mg/kg) in the rat. Following HAI, fluorescent labeled LDL nanoparticles displayed a biexponential plasma concentration time curve as the particles were rapidly extracted by the liver. Overall, increasing doses of HAI of LDL-DHA was well tolerated in the rat. Body weight, plasma biochemistry and histology were all unremarkable and molecular markers of inflammation did not increase with treatment. Lipidomics analyses showed that LDL-DHA was preferentially oxidized to the anti-inflammatory mediator, protectin DX. We conclude that HAI of LDL-DHA nanoparticles is not only safe, but provides potential hepatoprotective benefits.

Development and validation of a quantitative LC-MS/MS method for the simultaneous determination of ceftolozane and tazobactam in human plasma and urine.

The purpose of this work was to develop and validate a single sensitive, selective and rapid bioanalytical method to determine ceftolozane and tazobactam concentrations in human plasma and urine and to use this method to analyze samples from a human clinical study. Human plasma and urine samples were prepared by protein precipitation using a solution of acetonitrile, water and formic acid. Following protein precipitation, samples were analyzed by liquid chromatography tandem mass spectrometry. Chromatographic resolution was achieved on a Kinetex PFP column using a gradient elution, a flow rate of 0.4 mL/min, and a total run time of 5 min. Positive electrospray ionization was employed and analytes were quantitated using multi-reaction monitoring mode. Method validation was conducted in accordance with Unites States Food and Drug Administration's regulatory guidelines for bioanalytical method validation. Calibration curves were determined to linear over the range of 0.1 to 40 µg/mL for ceftolozane and 0.05 to 20 µg/mL for tazobactam. The method was determined to be accurate (-6.24 to 12.53 percent relative error), precise (less than 13.28 percent standard deviation) and sensitive in both human plasma and urine. Ceftolozane and tazobactam were determined to be stable across a battery of stability studies including autosampler, benchtop, freeze/thaw and long-term stability. This validated method successfully applied to human clinical samples to determine the concentration versus time profiles of the intravenously administered combination of Zerbaxa (ceftolozane-tazobactam) in burn patients.

Concentration-dependent Early Antivascular and Antitumor Effects of Itraconazole in Non-Small Cell Lung Cancer.

PURPOSE: Itraconazole has been repurposed as an anticancer therapeutic agent for multiple malignancies. In preclinical models, itraconazole has antiangiogenic properties and inhibits Hedgehog pathway activity. We performed a window-of-opportunity trial to determine the biologic effects of itraconazole in human patients. EXPERIMENTAL DESIGN: Patients with non-small cell lung cancer (NSCLC) who had planned for surgical resection were administered with itraconazole 300 mg orally twice daily for 10-14 days. Patients underwent dynamic contrast-enhanced MRI and plasma collection for pharmacokinetic and pharmacodynamic analyses. Tissues from pretreatment biopsy, surgical resection, and skin biopsies were analyzed for itraconazole and hydroxyitraconazole concentration, and vascular and Hedgehog pathway biomarkers. RESULTS: Thirteen patients were enrolled in this study. Itraconazole was well-tolerated. Steady-state plasma concentrations of itraconazole and hydroxyitraconazole demonstrated a 6-fold difference across patients. Tumor itraconazole concentrations trended with and exceeded those of plasma. Greater itraconazole levels were significantly and meaningfully associated with reduction in tumor volume (Spearman correlation, -0.71; P = 0.05) and tumor perfusion (Ktrans; Spearman correlation, -0.71; P = 0.01), decrease in the proangiogenic cytokines IL1b (Spearman correlation, -0.73; P = 0.01) and GM-CSF (Spearman correlation, -1.00; P < 0.001), and reduction in tumor microvessel density (Spearman correlation, -0.69; P = 0.03). Itraconazole-treated tumors also demonstrated distinct metabolic profiles. Itraconazole treatment did not alter transcription of GLI1 and PTCH1 mRNA. Patient size, renal function, and hepatic function did not predict itraconazole concentrations. CONCLUSIONS: Itraconazole demonstrates concentration-dependent early antivascular, metabolic, and antitumor effects in patients with NSCLC. As the number of fixed dose cancer therapies increases, attention to interpatient pharmacokinetics and pharmacodynamics differences may be warranted.

Bioanalytical method development and validation of a liquid chromatography-tandem mass spectrometry method for determination of ß-lapachone in human plasma.

The purpose of this work was to develop and validate a rapid, sensitive and robust liquid chromatography tandem mass spectrometric method for the quantification of ß-lapachone in human plasma and to use that method to analyze human clinical samples. Sample preparation for the developed method involved liquid-liquid extraction using ethyl acetate for extraction of ß-lapachone and cryptotanshinone (internal standard) from human plasma. Chromatographic resolution was achieved on a Kinetex C18 column using a gradient elution and a chromatographic flow rate of 0.5 mL/min. The retention times of ß-lapachone and cryptotanshinone were 1.98 and 2.28 min, respectively, and the method had a total run time of 4 min. Bioanalytical method validation was conducted in accordance with the United States Food and Drug Administration regulatory guidelines. The method was validated over 2 calibration ranges in order to support high- and low-dose clinical studies. Calibration curve-1 covered the range of 0.25-50 ng/mL and calibration curve-2 covered the range of 50-2000 ng/mL. The method was determined to be accurate (percent relative errors between -1.07 to 5.36 %), precise (percent relative standard deviations less than 7.4), and sensitive (LLOQ 0.25 ng/mL). ß-lapachone was determined to be stable (% change from time = 0 between -11.6 and 12.6 %) across the autosampler, benchtop, freeze/thaw and long-term (63 days) stability studies. The validated bioanalytical method was employed to determine ß-lapachone concentrations in human plasma samples from a clinical study.

An implanted port-catheter system for repeated hepatic arterial infusion of low-density lipoprotein-docosahexaenoic acid nanoparticles in normal rats: A safety study.

BACKGROUND: In recent years, small animal arterial port-catheter systems have been implemented in rodents with reasonable success. The aim of the current study is to employ the small animal port-catheter system to evaluate the safety of multiple hepatic-artery infusions (HAI) of low-density lipoprotein-docosahexaenoic acid (LDL-DHA) nanoparticles to the rat liver. METHODS: Wistar rats underwent surgical placement of indwelling HAI ports. Repeated administrations of PBS or LDL-DHA nanoparticles were performed through the port at baseline and days 3 and 6. Rats were sacrificed on day 9 at which point blood and various organs were collected for histopathology and biochemical analyses. RESULTS: The port-catheter systems were implanted successfully and repeated infusions of PBS or LDL-DHA nanoparticles were tolerated well by all animals over the duration of the study. Measurements of serum liver/renal function tests, glucose and lipid levels did not differ between control and LDL-DHA treated rats. The liver histology was unremarkable in the LDL-DHA treated rats and the expression of hepatic inflammatory regulators (NF-κß, IL-6 and CRP) were similar to control rats. Repeated infusions of LDL-DHA nanoparticles did not alter liver glutathione content or the lipid profile in the treated rats. The DHA extracted by the liver was preferentially metabolized to the anti-inflammatory DHA-derived mediator, protectin DX. CONCLUSION: Our findings indicate that repeated HAI of LDL-DHA nanoparticles is not only well tolerated and safe in the rat, but may also be protective to the liver.

Steady-State Ceftazidime-Avibactam Serum Concentrations and Dosing Recommendations in a Critically Ill Patient Being Treated for Pseudomonas aeruginosa Pneumonia and Undergoing Continuous Venovenous Hemodiafiltration.

Ceftazidime-avibactam (CAZ-AVI) is a novel intravenous ß-lactam/ß-lactamase inhibitor combination used in the treatment of multidrug-resistant (MDR) gram-negative infections. Although renal dosing recommendations exist for the medication, limited data are available for dosing in patients receiving continuous renal replacement therapy. In this report, we describe a case in which CAZ-AVI 2.5 g was administered as a 2-hour infusion every 8 hours to a 50-year-old critically ill patient with MDR Pseudomonas aeruginosa (CAZ-AVI minimum inhibitory concentration [MIC] 8 µg/ml) pneumonia who was also receiving continuous venovenous hemodiafiltration (CVVHDF). Total serum concentrations of both ceftazidime and avibactam were measured at ~0.5, 2, 4, and 6 hours after completion of the 2-hour infusion of the 11th dose of CAZ-AVI. Ceftazidime pharmacokinetic parameters were as follows: maximum serum concentration (Cmax ) 152.39 µg/ml, half-life 5.17 hours, volume of distribution at steady state (Vdss ) 11.51 L, clearance 1.54 L/hour, and area under the concentration-time curve (AUC) 1295.38 hour•µg/ml. This regimen achieved free ceftazidime serum concentrations more than 4 times the MIC for 100% of the dosing interval. Avibactam pharmacokinetic parameters were as follows: Cmax 35.83 µg/ml, half-life 5.92 hours, Vdss 12.44 L, clearance 1.45 L/hour, and AUC 343.44 hour•µg/ml, which achieved free avibactam concentrations above 1 µg/ml for 100% of the dosing interval. Higher CAZ-AVI dosing is critical in the treatment of pneumonia due to limited ceftazidime penetration into epithelial lining fluid; however, epithelial lining fluid drug concentrations were not collected or measured. Based on this case report and the available evidence, a dose of CAZ-AVI 2.5 g infused over 2 hours every 8 hours appears to be appropriate for critically ill patients who are being treated for pneumonia and are receiving CVVHDF.