Evaluation of First-Dose, Intravenous Push Penicillins and Carbapenems in the Emergency Department.

BACKGROUND: Early appropriate antibiotic administration is associated with improved outcomes in infectious illnesses. During drug shortages in 2017, the American Society of Health-System Pharmacists recommended intravenous push (IVP) administration of medications when possible to conserve small-volume parenteral solutions. Data supporting IVP penicillins and carbapenems was limited. OBJECTIVE: The primary objective of this study compared time from patient emergency department (ED) arrival to antibiotic administration between IVP and intravenous piggy-back (IVPB) administration. METHODS: This single-center pre-post protocol study assessed changes in administration timing and safety of ampicillin/sulbactam, piperacillin/tazobactam, and ertapenem from 2015-2018. Medication administration by IVPB (pre) or IVP (post), ED arrival, antibiotic order and administration times, potential effectors of administration time, and safety events were assessed. Acquisition costs were estimated. RESULTS: A total of 696 administrations were included, with 351 and 345 subjects in the IVPB and IVP cohorts, respectively. The median time from ED arrival to initiation of antibiotic administration was 140 (IQR 87-221) minutes and 110 (IQR 68-181) minutes in the IVPB and IVP cohorts, respectively, (P < 0.01). IVP administration increased the proportion of indexed antibiotics administered within 60 minutes of ED arrival compared to IVPB (20% vs. 12%, respectively, P < 0.01). There was no difference in adverse events between both cohorts. Supply acquisition cost savings totaled an more than $5,000 with the IVP protocol. CONCLUSION: IVP administration of ampicillin/sulbactam, piperacillin/tazobactam, and ertapenem improved times to initiation of empiric, first-dose antibiotics in the ED without an increase in adverse events, saving over $5,000 annually.

Adherence to oral oncolytics filled through an internal health-system specialty pharmacy compared with external specialty pharmacies.

BACKGROUND: Oral oncolytics are becoming increasingly common in the treatment of solid and hematological malignancies. Medication adherence is especially important to ensure adequate drug levels to treat active malignancies, notably in curative-intent therapy. Further data are needed to quantify and confirm the effects of internal health-system specialty pharmacies (HSSPs) on medication adherence. OBJECTIVE: To confirm the effect of an internal HSSP compared with external specialty pharmacies on oncolytic adherence as measured by proportion of days covered (PDC), medication possession ratio (MPR), and time to treatment (TTT). METHODS: This single-center retrospective cohort study included patients receiving oral oncolytics through an internal HSSP or external specialty pharmacies between January 2019 and June 2020. Fill data were extracted from pharmacy claims databases and electronic medical records. The primary adherence outcome was patient-level PDC. Secondary adherence outcomes included patient-level MPR and TTT. For PDC and MPR analyses, patients with at least 3 fills per oncolytic were included. All patients were included for the TTT analysis. Chi-square or Fisher's exact tests were used to analyze categorical differences between pharmacy groups. Differences in continuous variables across pharmacy groups were evaluated using Wilcoxon rank-sum tests. RESULTS: 871 prescriptions met inclusion criteria: 549 patients were included in the PDC/MPR analysis, and 758 patients were included in the TTT analysis (patients might have multiple prescriptions). Patients who filled at an internal HSSP had a higher median PDC compared with those who filled at external specialty pharmacies (0.99 [IQR = 0.89-1.00] vs 0.91 [IQR = 0.76-0.98]; P < 0.01). The adherence rate as measured by MPR was higher for patients who used an internal HSSP compared with those who used external specialty pharmacies (MPR = 1.00 [IQR = 0.90-1.00] vs 0.93 [IQR = 0.76-1.00]; P < 0.01). Median TTT was lower for patients using the internal HSSP vs an external specialty pharmacy (5 days [IQR = 2-13] vs 27 days [IQR = 2-82], respectively; P < 0.01). CONCLUSIONS: Internal HSSP services improved adherence as measured by PDC and MPR. Significantly lower TTT was seen with the internal HSSP compared with external pharmacies. These data confirm and support use of internal HSSPs to dispense oral oncolytics for treatment of solid and hematological malignancies. DISCLOSURES: This study received no financial support. The authors declare no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Longitudinal Functional Study of Murine Aging: A Resource for Future Study Designs.

Aging is characterized by systemic declines in tissue and organ functions. Interventions that slow these declines represent promising therapeutics to protect against age-related disease and improve the quality of life. In this study, several interventions associated with lifespan extension in invertebrates or improvement of age-related disease were tested in mouse models to determine if they were effective in slowing tissue aging in a broad spectrum of functional assays. Benzoxazole, which extends the lifespan of Caenorhabditis elegans, slowed age-related femoral bone loss in mice. Rates of change were established for clinically significant parameters in untreated mice, including kyphosis, blood glucose, body composition, activity, metabolic measures, and detailed parameters of skeletal aging in bone. These findings have implications for the study of preclinical physiological aging and therapies targeting aging. Finally, an online application was created that includes the calculated rates of change and that enables power and variance to be calculated for many clinically important metrics of aging with an emphasis on bone. This resource will help in future study designs employing novel interventions in aging mice. © 2021 The Authors. JBMR Plus published by Wiley Periodicals LLC. on behalf of American Society for Bone and Mineral Research.

Opioid Prescribing After Discharge in a Previously Mechanically Ventilated, Opioid-Naïve Cohort.

BACKGROUND: Opioids are utilized for pain management during and after mechanical ventilation in the intensive care unit (ICU). OBJECTIVE: The purpose of this study was to determine the percentage of potentially unnecessary opioid prescriptions on discharge in previously opioid-naïve patients. METHODS: This retrospective cohort study included mechanically ventilated, opioid-naïve ICU patients who received opioids. The primary outcome of this study was the discrepancy between the amounts of opioids prescribed at discharge versus those likely required based on actual 24-hour prehospital discharge opioid requirements. RESULTS: A total of 71 patients were included. Of these, 63.3% (n = 45) of discharge prescriptions were in alignment with 24-hour predischarge requirements, and 36.7% (n = 26) of discharge prescriptions were in excess of calculated predischarge requirements. At discharge, 57.7% (n = 41) of patients received a nonopioid analgesic. Multivariable linear regression revealed that cardiothoracic ICU admission was associated with an increased risk of inappropriate discharge opioid prescribing, whereas a shorter duration of inpatient oral opioid therapy decreased risk of inappropriate discharge prescribing. CONCLUSION AND RELEVANCE: Opioid prescribing for previously mechanically ventilated patients warrants improvement as a part of the discharge planning process. Application of these data may aid in the reduction of opioid overprescribing at discharge after an ICU stay.

A Review of PI3K Inhibitors in B-Cell Malignancies.

The phosphoinositide 3-kinase (PI3K) pathway plays a primary role in cellular proliferation and metabolism. Inhibition of the PI3K pathway is an emerging area of drug development and cancer research. Idelalisib, copanlisib, and duvelisib are currently the only U.S. Food & Drug Administration-approved PI3K inhibitors available for use in hematologic malignancies. These PI3K inhibitors differ in their recommended indications, selectivity of PI3K isoforms, dosing, and potential toxicities. Several ongoing studies are aiming to expand the use of such drugs and identify unique combination regimens. This article discusses the current data supporting their place in therapy for B-cell malignancies, management of adverse events, and the clinical implications for advanced practitioners for the commercially available PI3K inhibitors.

Evidence that S6K1, but not 4E-BP1, mediates skeletal muscle pathology associated with loss of A-type lamins.

The mechanistic target of rapamycin (mTOR) signaling pathway plays a central role in aging and a number of different disease states. Rapamycin, which suppresses activity of the mTOR complex 1 (mTORC1), shows preclinical (and sometimes clinical) efficacy in a number of disease models. Among these are Lmna-/- mice, which serve as a mouse model for dystrophy-associated laminopathies. To confirm that elevated mTORC1 signaling is responsible for the pathology manifested in Lmna-/- mice and to decipher downstream genetic mechanisms underlying the benefits of rapamycin, we tested in Lmna-/- mice whether survival could be extended and disease pathology suppressed either by reduced levels of S6K1 or enhanced levels of 4E-BP1, two canonical mTORC1 substrates. Global heterozygosity for S6K1 ubiquitously extended lifespan of Lmna-/- mice (Lmna-/-S6K1+/- mice). This life extension is due to improving muscle, but not heart or adipose, function, consistent with the observation that genetic ablation of S6K1 specifically in muscle tissue also extended survival of Lmna-/- mice. In contrast, whole-body overexpression of 4E-BP1 shortened the survival of Lmna-/- mice, likely by accelerating lipolysis. Thus, rapamycin-mediated lifespan extension in Lmna-/- mice is in part due to the improvement of skeletal muscle function and can be phenocopied by reduced S6K1 activity, but not 4E-BP1 activation.

Cellular Senescence Promotes Adverse Effects of Chemotherapy and Cancer Relapse.

Cellular senescence suppresses cancer by irreversibly arresting cell proliferation. Senescent cells acquire a proinflammatory senescence-associated secretory phenotype. Many genotoxic chemotherapies target proliferating cells nonspecifically, often with adverse reactions. In accord with prior work, we show that several chemotherapeutic drugs induce senescence of primary murine and human cells. Using a transgenic mouse that permits tracking and eliminating senescent cells, we show that therapy-induced senescent (TIS) cells persist and contribute to local and systemic inflammation. Eliminating TIS cells reduced several short- and long-term effects of the drugs, including bone marrow suppression, cardiac dysfunction, cancer recurrence, and physical activity and strength. Consistent with our findings in mice, the risk of chemotherapy-induced fatigue was significantly greater in humans with increased expression of a senescence marker in T cells prior to chemotherapy. These findings suggest that senescent cells can cause certain chemotherapy side effects, providing a new target to reduce the toxicity of anticancer treatments. SIGNIFICANCE: Many genotoxic chemotherapies have debilitating side effects and also induce cellular senescence in normal tissues. The senescent cells remain chronically present where they can promote local and systemic inflammation that causes or exacerbates many side effects of the chemotherapy. Cancer Discov; 7(2); 165-76. ©2016 AACR.This article is highlighted in the In This Issue feature, p. 115.

Rapamycin Reverses Metabolic Deficits in Lamin A/C-Deficient Mice.

The role of the mTOR inhibitor, rapamycin, in regulation of adiposity remains controversial. Here, we evaluate mTOR signaling in lipid metabolism in adipose tissues of Lmna-/- mice, a mouse model for dilated cardiomyopathy and muscular dystrophy. Lifespan extension by rapamycin is associated with increased body weight and fat content, two phenotypes we link to suppression of elevated energy expenditure. In both white and brown adipose tissue of Lmna-/- mice, we find that rapamycin inhibits mTORC1 but not mTORC2, leading to suppression of elevated lipolysis and restoration of thermogenic protein UCP1 levels, respectively. The short lifespan and metabolic phenotypes of Lmna-/- mice can be partially rescued by maintaining mice at thermoneutrality. Together, our findings indicate that altered mTOR signaling in Lmna-/- mice leads to a lipodystrophic phenotype that can be rescued with rapamycin, highlighting the effect of loss of adipose tissue in Lmna-/- mice and the consequences of altered mTOR signaling.

Increased 4E-BP1 Expression Protects against Diet-Induced Obesity and Insulin Resistance in Male Mice.

Obesity is a major risk factor driving the global type II diabetes pandemic. However, the molecular factors linking obesity to disease remain to be elucidated. Gender differences are apparent in humans and are also observed in murine models. Here, we link these differences to expression of eukaryotic translation initiation factor 4E binding protein 1 (4E-BP1), which, upon HFD feeding, becomes significantly reduced in the skeletal muscle and adipose tissue of male but not female mice. Strikingly, restoring 4E-BP1 expression in male mice protects them against HFD-induced obesity and insulin resistance. Male 4E-BP1 transgenic mice also exhibit reduced white adipose tissue accumulation accompanied by decreased circulating levels of leptin and triglycerides. Importantly, transgenic 4E-BP1 male mice are also protected from aging-induced obesity and metabolic decline on a normal diet. These results demonstrate that 4E-BP1 is a gender-specific suppressor of obesity that regulates insulin sensitivity and energy metabolism.

Muscle-specific 4E-BP1 signaling activation improves metabolic parameters during aging and obesity.

Eukaryotic translation initiation factor 4E-binding protein 1 (4E-BP1) is a key downstream effector of mTOR complex 1 (mTORC1) that represses cap-dependent mRNA translation initiation by sequestering the translation initiation factor eIF4E. Reduced mTORC1 signaling is associated with life span extension and improved metabolic homeostasis, yet the downstream targets that mediate these benefits are unclear. Here, we demonstrated that enhanced 4E-BP1 activity in mouse skeletal muscle protects against age- and diet-induced insulin resistance and metabolic rate decline. Transgenic animals displayed increased energy expenditure; altered adipose tissue distribution, including reduced white adipose accumulation and preserved brown adipose mass; and were protected from hepatic steatosis. Skeletal muscle-specific 4E-BP1 mediated metabolic protection directly through increased translation of peroxisome proliferator-activated receptor γ coactivator-1α (PGC-1α) and enhanced respiratory function. Non-cell autonomous protection was through preservation of brown adipose tissue metabolism, which was increased in 4E-BP1 transgenic animals during normal aging and in a response to diet-induced type 2 diabetes. Adipose phenotypes may derive from enhanced skeletal muscle expression and secretion of the known myokine FGF21. Unlike skeletal muscle, enhanced adipose-specific 4E-BP1 activity was not protective but instead was deleterious in response to the same challenges. These findings indicate that regulation of 4E-BP1 in skeletal muscle may serve as an important conduit through which mTORC1 controls metabolism.

Rapamycin-mediated mTORC2 inhibition is determined by the relative expression of FK506-binding proteins.

The mechanism by which the drug rapamycin inhibits the mechanistic target of rapamycin (mTOR) is of intense interest because of its likely relevance in cancer biology, aging, and other age-related diseases. While rapamycin acutely and directly inhibits mTORC1, only chronic administration of rapamycin can inhibit mTORC2 in some, but not all, cell lines or tissues. The mechanism leading to cell specificity of mTORC2 inhibition by rapamycin is not understood and is especially important because many of the negative metabolic side effects of rapamycin, reported in mouse studies and human clinical trials, have been attributed recently to mTORC2 inhibition. Here, we identify the expression level of different FK506-binding proteins (FKBPs), primarily FKBP12 and FKBP51, as the key determinants for rapamycin-mediated inhibition of mTORC2. In support, enforced reduction of FKBP12 completely converts a cell line that is sensitive to mTORC2 inhibition to an insensitive cell line, and increased expression can enhance mTORC2 inhibition. Further reduction of FKBP12 in cell lines with already low FKBP12 levels completely blocks mTORC1 inhibition by rapamycin, indicating that relative FKBP12 levels are critical for both mTORC1 and mTORC2 inhibition, but at different levels. In contrast, reduction of FKBP51 renders cells more sensitive to mTORC2 inhibition. Our findings reveal that the expression of FKBP12 and FKBP51 is the rate limiting factor that determines the responsiveness of a cell line or tissue to rapamycin. These findings have implications for treating specific diseases, including neurodegeneration and cancer, as well as targeting aging in general.

The ribosomal protein Rpl22 controls ribosome composition by directly repressing expression of its own paralog, Rpl22l1.

Most yeast ribosomal protein genes are duplicated and their characterization has led to hypotheses regarding the existence of specialized ribosomes with different subunit composition or specifically-tailored functions. In yeast, ribosomal protein genes are generally duplicated and evidence has emerged that paralogs might have specific roles. Unlike yeast, most mammalian ribosomal proteins are thought to be encoded by a single gene copy, raising the possibility that heterogenous populations of ribosomes are unique to yeast. Here, we examine the roles of the mammalian Rpl22, finding that Rpl22(-/-) mice have only subtle phenotypes with no significant translation defects. We find that in the Rpl22(-/-) mouse there is a compensatory increase in Rpl22-like1 (Rpl22l1) expression and incorporation into ribosomes. Consistent with the hypothesis that either ribosomal protein can support translation, knockdown of Rpl22l1 impairs growth of cells lacking Rpl22. Mechanistically, Rpl22 regulates Rpl22l1 directly by binding to an internal hairpin structure and repressing its expression. We propose that ribosome specificity may exist in mammals, providing evidence that one ribosomal protein can influence composition of the ribosome by regulating its own paralog.

Chronic rapamycin treatment or lack of S6K1 does not reduce ribosome activity in vivo.

Reducing activity of the mTORC1/S6K1 pathway has been shown to extend lifespan in both vertebrate and invertebrate models. For instance, both pharmacological inhibition of mTORC1 with the drug rapamycin or S6K1 knockout extends lifespan in mice. Since studies with invertebrate models suggest that reducing translational activity can increase lifespan, we reasoned that the benefits of decreased mTORC1 or S6K1 activity might be due, at least in part, to a reduction of general translational activity. Here, we report that mice given a single dose of rapamycin have reduced translational activity, while mice receiving multiple injections of rapamycin over 4 weeks show no difference in translational activity compared with vehicle-injected controls. Furthermore, mice lacking S6K1 have no difference in global translational activity compared with wild-type littermates as measured by the percentage of ribosomes that are active in multiple tissues. Translational activity is reduced in S6K1-knockout mice following single injection of rapamycin, demonstrating that rapamycin's effects on translation can occur independently of S6K1. Taken together, these data suggest that benefits of chronic rapamycin treatment or lack of S6K1 are dissociable from potential benefits of reduced translational activity, instead pointing to a model whereby changes in translation of specific subsets of mRNAs and/or translation-independent effects of reduced mTOR signaling underlie the longevity benefits.

Late-life rapamycin treatment reverses age-related heart dysfunction.

Rapamycin has been shown to extend lifespan in numerous model organisms including mice, with the most dramatic longevity effects reported in females. However, little is known about the functional ramifications of this longevity-enhancing paradigm in mammalian tissues. We treated 24-month-old female C57BL/6J mice with rapamycin for 3 months and determined health outcomes via a variety of noninvasive measures of cardiovascular, skeletal, and metabolic health for individual mice. We determined that while rapamycin has mild transient metabolic effects, there are significant benefits to late-life cardiovascular function with a reversal or attenuation of age-related changes in the heart. RNA-seq analysis of cardiac tissue after treatment indicated inflammatory, metabolic, and antihypertrophic expression changes in cardiac tissue as potential mechanisms mediating the functional improvement. Rapamycin treatment also resulted in beneficial behavioral, skeletal, and motor changes in these mice compared with those fed a control diet. From these findings, we propose that late-life rapamycin therapy not only extends the lifespan of mammals, but also confers functional benefits to a number of tissues and mechanistically implicates an improvement in contractile function and antihypertrophic signaling in the aged heart with a reduction in age-related inflammation.