Characterizing Erythrocyte Motions in Flowing Blood

Characterizing the probabilistic motions of cells is a prerequisite for the development of a general model of transport and surface deposition of white cells and platelets (WBC/P). These phenomena differ greatly when red blood cells (RBC) are present at normal levels, but follow convective diffusion in dilute suspensions. A critical need is to understand and characterize dispersion and diffusion as they apply to red cells in suspension flow. The dispersive motions of 0.5-micrometer beads and fluorescently labeled human RBC flowing in dilute (0.003%) and concentrated (25%) RBC suspensions, respectively, were characterized using fluorescence videomicroscopy methods, and times for individual tracer particles to move fixed distances were measured. The particles were tracked in the axial direction and in a moving reference frame. The experimentally estimated effective diffusion coefficient of the particles was in good agreement with published work (RBC ~ 1x10 -8 and beads ~ 4x10 -9 [cm 2 /sec]). Using a continuous time random walk model (CTRW) to characterize the particles’ random motions in a shear field, the average time was plotted versus the squared displacement and a power law fit exponent was used to quantitatively distinguish between diffusion and dispersion. Values consistent with Brownian motion were found for the bead suspensions and an anomalous diffusion was found for the RBC suspensions, which indicated that beads random motions were diffusive and the RBC ones were dispersive. The methods developed in this work could be used to study dispersion events at different lateral locations along the channel’s height and investigate the effects of flow parameters such as wall shear rate, hematocrit, and cell type

Ambiguity of structure determination from a minimum of diffraction intensities

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/107547/1/S2053273314007578.pd

Clinical Pharmacology and Dosing Regimen Optimization of Neonatal Opioid Withdrawal Syndrome Treatments

In this paper, we review the management of neonatal opioid withdrawal syndrome (NOWS) and clinical pharmacology of primary treatment agents in NOWS, including morphine, methadone, buprenorphine, clonidine, and phenobarbital. Pharmacologic treatment strategies in NOWS have been mostly empirical, and heterogeneity in dosing regimens adds to the difficulty of extrapolating study results to broader patient populations. As population pharmacokinetics (PKs) of pharmacologic agents in NOWS become more well-defined and knowledge of patient-specific factors affecting treatment outcomes continue to accumulate, PK/pharmacodynamic modeling and simulation will be powerful tools to aid the design of optimal dosing regimens at the patient level. Although there is an increasing number of clinical trials on the comparative efficacy of treatment agents in NOWS, here, we also draw attention to the importance of optimizing the dosing regimen, which can be arguably equally important at identifying the optimal treatment agent

Semi-Synthetic Mithramycin Derivatives with Anti-Cancer Activity

Mithramycin derivatives and their pharmaceutically acceptable salts are disclosed. The mithramycin derivatives can be used in the treatment of Ewing sarcoma or other cancer or neuro-disease associated with an aberrant erythroblast transformation- specific transcription factor

Phenylethynyl-Substituted Benzenes and Heterocycles for the Treatment of Cancer

Halogenated phenylethynyl-substituted heterocycles that possess either an N-alkylamino or N,N-dialkylamino group attached to the heterocycle or halogenated phenylethynyl-substituted benzenes that a nitrogen-containing heterocycle attached to the benzene inhibit the proliferation cancer cells and are useful antineoplastic agents

Phase 1b Trial of Proteasome Inhibitor Carfilzomib with Irinotecan in Lung Cancer and Other Irinotecan-Sensitive Malignancies That Have Progressed on Prior Therapy (Onyx IST Reference Number: CAR-IST-553)

Introduction Proteasome inhibition is an established therapy for many malignancies. Carfilzomib, a novel proteasome inhibitor, was combined with irinotecan to provide a synergistic approach in relapsed, irinotecan-sensitive cancers. Materials and Methods Patients with relapsed irinotecan-sensitive cancers received carfilzomib (Day 1, 2, 8, 9, 15, and 16) at three dose levels (20/27 mg/m2, 20/36 mg/m2 and 20/45 mg/m2/day) in combination with irinotecan (Days 1, 8 and 15) at 125 mg/m2/day. Key eligibility criteria included measurable disease, a Zubrod PS of 0 or 1, and acceptable organ function. Patients with stable asymptomatic brain metastases were eligible. Dose escalation utilized a standard 3 + 3 design. Results Overall, 16 patients were enrolled to three dose levels, with four patients replaced. Three patients experienced dose limiting toxicity (DLT) and the maximum tolerated dose (MTD) was exceeded in Cohort 3. The RP2 dose was carfilzomib 20/36 mg/m2 (given on Days 1, 2, 8, 9, 15, and 16) and irinotecan 125 mg/m2 (Days 1, 8 and 15). Common Grade (Gr) 3 and 4 toxicities included fatigue (19%), thrombocytopenia (19%), and diarrhea (13%). Conclusions Irinotecan and carfilzomib were well tolerated, with common toxicities of fatigue, thrombocytopenia and neutropenic fever. Objective clinical response was 19% (one confirmed partial response (PR) in small cell lung cancer (SCLC) and two unconfirmed); stable disease (SD) was 6% for a disease control rate (DCR) of 25%. The recommended phase II dose was carfilzomib 20/36 mg/m2 and irinotecan125 mg/m2. The phase II evaluation is ongoing in relapsed small cell lung cancer

Design, Synthesis, and Preliminary Evaluation of a Potential Synthetic Opioid Rescue Agent

BACKGROUND: One of the most prominent opioid analgesics in the United States is the high potency agonist fentanyl. It is used in the treatment of acute and chronic pain and as an anesthetic adjuvant. When used inappropriately, however, ingestion of just a few milligrams of fentanyl or other synthetic opioid can cause opioid-induced respiratory depression (OIRD), often leading to death. Currently, the treatment of choice for OIRD is the opioid receptor antagonist naloxone. Recent reports, however, suggest that higher doses or repeated dosing of naloxone (due to recurrence of respiratory depression) may be required to reverse fully fentanyl-induced respiratory depression, rendering this treatment inadequate. To combat this synthetic opioid overdose crisis, this research aims at identifying a novel opioid reversal agent with enhanced efficacy towards fentanyl and other synthetic opioids. METHODS: A series of naltrexone analogues were characterized for their ability to antagonize the effects of fentanyl in vitro utilizing a modified forskolin-induced cAMP accumulation assay. Lead analogue 29 was chosen to undergo further PK studies, followed by in vivo pharmacological analysis to determine its ability to antagonize opioid-induced antinociception in the hot plate assay. RESULTS: A series of potent MOR antagonists were identified, including the highly potent analogue 29 (IC50 = 2.06 nM). Follow-up PK studies revealed 29 to possess near 100% bioavailability following IP administration. Brain concentrations of 29 surpassed plasma concentrations, with an apparent terminal half-life of ~ 80 min in mice. In the hot plate assay, 29 dose-dependently (0.01–0.1 mg/kg; IP) and fully antagonized the antinociception induced by oxycodone (5.6 mg/kg; IP). Furthermore, the dose of 29 that is fully effective in preventing oxycodone-induced antinociception (0.1 mg/kg) was ineffective against locomotor deficits caused by the KOR agonist U50,488. CONCLUSIONS: Methods have been developed that have utility to identify enhanced rescue agents for the treatment of OIRD. Analogue 29, possessing potent MOR antagonist activity in vitro and in vivo, provides a promising lead in our search for an enhanced synthetic opioid rescue agent

Nanoparticles Containing Anti-inflammatory Agents as Chemotherapy Adjuvants II: Role of Plasma Esterases in Drug Release

The pre-administration of the anti-inflammatory drugs dexamethasone (DEX) and cortisone acetate reduces toxicity and enhances efficacy of anticancer agents in murine models and in human clinical trials (1–5). We previously reported on the formulation of the lipophilic dexamethasone palmitate ester (DEX-P) in nanoparticles (NPs) employing a microemulsion template engineering technique to achieve tumor-specific delivery of dexamethasone (6). The nanoparticles exhibited significantly enhanced stealth properties as indicated by reduced macrophage uptake and decreased adsorption of opsonin proteins in in vitro assays (6). Unexpectedly, preliminary biodistribution studies of NPs containing [3H]-DEX-P in tumor-bearing mice showed that the radiolabel was cleared from the circulation rapidly and exhibited high liver uptake. Our previous in vitro release studies demonstrated that rapid release of the radiolabel from the NPs was observed when 10% mouse plasma was used as the medium, while nominal release was observed in phosphate-buffered saline (PBS) buffer (6). Esterolysis of NP-associated DEX-P was presumed to be the main cause for the rapid drug release in plasma, as most of the released radioactivity was in the form of DEX and not DEX-P. High degradation rates of ester prodrugs in rodent plasma has been attributed to increased esterase activity, while only minimal degradation in human plasma has been observed (7–9). Based on our observation of the release of [3H]-DEX from NPs in mouse plasma, we studied the release of DEX from nanoparticles in various plasma sources as a guide for the design of future in vivo experiments