Large scale systemic control short-circuits pathogen transmission by interrupting the sand rat (Psammomys obesus)-to-sand fly (Phlebotomus papatasi) Leishmania major transmission cycle

Systemic control uses the vertebrate hosts of zoonotic pathogens as “Trojan horses,” killing blood-feeding female vectors and short-circuiting host-to-vector pathogen transmission. Previous studies focused only on the effect of systemic control on vector abundance at small spatial scales. None were conducted at a spatial scale relevant for vector control and none on the effect of systemic control on pathogen transmission rates. We tested the application of systemic control, using Fipronil-impregnated rodent baits, in reducing Leishmania major (Kinetoplastida: Trypanosomatidae; Yakimoff & Schokhor, 1914) infection levels within the vector, Phlebotomus papatasi (Diptera: Psychodidae; Scopoli, 1786) population, at the town-scale. We provided Fipronil-impregnated food-baits to all Psammomys obesus (Mammalia:Muridae; Cretzschmar, 1828), the main L. major reservoir, burrows along the southern perimeter of the town of Yeruham, Israel, and compared sand fly abundance and infection levels with a non-treated control area. We found a significant and substantial treatment effect on L. major infection levels in the female sand fly population. Sand fly abundance was not affected. Our results demonstrate, for the first time, the potential of systemic control in reducing pathogen transmission rates at a large, epidemiologically relevant, spatial scale.     

Heat transfer analysis for EMHD peristalsis of ionic-nanofluids via curved channel with Joule dissipation and Hall effects

Journal of Biological Physics - The objective of this research is to study the combined influences of applied electric and magnetic fields on the two-phase peristaltic motion of nanofluid through a...     

Comparison of Insulins Glargine and Degludec in Diabetic Rhesus Macaques (Macaca mulatta) with CGM Devices

Treating and monitoring type 2 diabetes mellitus (T2DM) in NHP can be challenging. Multiple insulin and hypoglycemic therapies and management tools exist, but few studies demonstrate their benefits in a NHP clinical setting. The insulins glargine and degludec are long-acting insulins; their duration of action in humans exceeds 24 and 42 h, respectively. In the first of this study''s 2 components, we evaluated whether insulin degludec could be dosed daily at equivalent units to glargine to achieve comparable blood glucose (BG) reduction in diabetic rhesus macaques (Macaca mulatta) with continuous glucose monitoring (CGM) devices. The second component assessed the accuracy of CGM devices in rhesus macaques by comparing time-stamped CGM interstitial glucose values, glucometer BG readings, and BG levels measured by using an automated clinical chemistry analyzer from samples that were collected at the beginning and end of each CGM device placement. The CGM devices collected a total of 21,637 glucose data points from 6 diabetic rhesus macaques that received glargine followed by degludec every 24 h for 1 wk each. Ultimately, glucose values averaged 29 mg/dL higher with degludec than with glargine. Glucose values were comparable between the CGM device, glucometer, and chemistry analyzer, thus validating that CGM devices as reliable for measuring BG levels in rhesus macaques. Although glargine was superior to degludec when given at the same dose (units/day), both are safe and effective treatment options. Glucose values from CGM, glucometers, and chemistry analyzers provided results that were analogous to BG values in rhesus macaques. Our report further highlights critical clinical aspects of using glargine as compared with degludec in NHP and the benefits of using CGM devices in macaques.

Diabetes is a group of metabolic diseases that cause hyperglycemia secondary to deficient insulin response, secretion, or both.⁴ Diabetes is categorized by the American Diabetes Association into 4 types: 1) type 1 diabetes mellitus, in which the pancreas is unable to produce insulin for glucose absorption; 2) type 2 diabetes mellitus (T2DM), when the body does not use insulin correctly; 3) gestational diabetes, in which the body is insulin-intolerant during pregnancy (or is first discovered then); and 4) other specific forms of diabetes in which the patient is particularly predisposed to becoming diabetic due to various comorbidities or to inadvertent induction caused by some medications.⁴ In 2018, 34.2 million (10.5%) Americans of all ages were diagnosed with diabetes.^22,23,30 Approximately 90% to 95% of Americans with diabetes have T2DM,²⁴ making T2DM the most common form of diabetes diagnosed in humans.T2DM is a multifactorial disease primarily determined by genetics, behavioral and environmental factors (for example, age, diet, sedentary lifestyle, obesity).^4,46,50,74 As a consequence of these factors, the pancreas increases insulin secretion to maintain normal glucose tolerance.⁷⁴ Over time, the high insulin demand causes pancreatic β-cell destruction, resulting in reduced production of insulin.^39,50,74 As β-cell destruction increases, hyperglycemia and T2DM develop. Insulin resistance and hyperglycemia are tolerated for a period of time^19,82,83 before clinical signs associated with T2DM develop (e.g., polydipsia, polyuria, polyphagia with concurrent weight loss).⁴ Once clinical signs develop, T2DM is most commonly diagnosed as a fasting blood glucose level (FBG) of 126 mg/dL or greater,^2,4 2-h plasma glucose value of 200 mg/d or greater during a 75-g oral glucose tolerance test,^2,4 and/or glycosylated hemoglobin (HbA1c) of 6.5% or greater.^2,4 Depending on the FBG, oral glucose tolerance test, and HbA1c results, various treatment options are recommended by the American Diabetes Association. Most importantly, lifestyle changes, including diet and exercise, are recommended as the first line of treatment, along with oral antihyperglycemic drugs such as metformin.^5,25,46 Treatment efficacy is evaluated with self-monitoring blood glucose or continuous glucose monitoring (CGM) devices.³ Human patients using CGM devices have achieved considerable reductions in HbA1c compared with patients not using them.³ As CGM devices have become more readily available, user friendly, and affordable, they have become an essential tool in managing T2DM.Similar to humans, most NHP affected by diabetes are diagnosed with T2DM.^80,83 NHP are predisposed to similar genetic, behavioral and environmental factors (e.g., age, diet, sedentary lifestyle, obesity);^{6,18,19,37,44,52,82,83} have similar pathophysiology;^38,81-83 are diagnosed via FBG,^39,83 HbA1c,^21,31,49,56 fructosamine,^20,83,87 and weight loss;^49,80,83,86 and are treated with exercise and diet modifications as a first line of treatment.^{11,19,39,53,79} Although the human and NHP conditions are similar, the treatment and management of T2DM is somewhat different, especially when NHP have restricted physical activity due to housing constraints.Previous studies indicate that daily dosing with insulin glargine achieves appropriate glycemic control in NHP.⁴⁸ Therefore, we implemented glargine, along with some diet modification, to improve glycemic control in our diabetic colony. Other noninsulin therapies, such as metformin, had been used, but compliance was low (for example, due to large pill size, unpleasant taste, etc.). However, achieving glycemic control using diet modification, insulin glargine treatment, monthly scheduled FBG, quarterly HbA1c, and regular weight monitoring was challenging in a large colony. Monthly FBG and fructosamine testing were performed due to affordability and practicality for NHP in a research setting. Given that fructosamine levels correlate with BG concentrations for the preceding 2 to 3 wk and HbA1c percentages relate to BG concentration over 1.5 to 3 mo,^49,87 HbA1C was selected over fructosamine for T2DM management in our colony. Determining which T2DM treatment and diagnostics are most effective can be difficult in large colonies of NHP. Therefore, improved treatment and management strategies would help to manage T2DM in NHP more efficiently.Insulin glargine is a long-acting insulin, with a half-life of 12 h and duration of action of 12 to 24 h in humans^40,55 and 12 h in dogs.^34,43,60 Once injected subcutaneously, insulin glargine forms a microprecipitate in the neutral pH environment, which delays and prolongs absorption in subcutaneous tissues.¹² Insulin degludec is a newer form of long-acting insulin, with a half-life of 25 h^41,63,62,77 and duration of action that exceeds 42 h in humans.^40,41,68,77 Insulin degludec forms a soluble and stable dihexamer in the pharmaceutical formulation, which includes phenol and zinc.^63,78 The phenol diffuses away, leading to the formation of a soluble depot in the form of long multihexamer chains in which zinc slowly diffuses from the end of the multihexamers, causing a gradual, continuous, and extended-release of monomers from the depot of the injection site.^63,78 Pharmacodynamic studies in humans, demonstrate that the “glucose-lowering effect” of insulin degluc⁴⁰ is evenly distributed over 24 h, allowing a more stable steady-state and improved wellbeing.⁷⁸ This approach could potentially reduce the number of hypoglycemic events and provide a less rigid daily injection schedule,⁵⁸ thus potentially making insulin degludec—compared with insulin glargine—a safer, alternative diabetes therapy.In addition to medical intervention, glycemic control is achieved through regular management and monitoring of BG. Self-monitoring blood glucose checks in humans^3,5 and glucose curves in animals¹⁰ are some of the management tools used to determine or evaluate therapy for T2DM patients. Telemetry systems like CGM devices are used to monitor interstitial glucose and have been used extensively in humans^3,17,33 and animals^{16,27,36,42,47,84,85} to monitor BG in real-time. Using CGM devices 1) reduces or eliminates the number of blood draws needed to collect FBG,⁶¹ 2) accurately assesses insulin therapy via a real-time glucose curve,^72,84,85 3) allows patients and clinicians to titrate treatment^61,73 as indicated, and 4) obtains continuous glucose data with reduced manipulation and subsequent decreased stress.^72,84,85 Therefore, CGM devices can be a safe and informative tool in monitoring spontaneous T2DM in NHP.Between 2015 and 2030, the prevalence of diabetes is predicted to increase by 54% to more than 54 million Americans affected by diabetes (i.e., diabetes mellitus types 1 and 2).⁷⁰ NHP are an essential model for human T2DM because of their similar pathophysiology, diagnostics, treatment, and management. As more people develop diabetes, novel therapies will continue to be developed. Studying new treatments and management tools in NHP can further human and NHP T2DM research to prevent the progression of T2DM and hopefully diminish projections for the number of future diabetes cases. Human medical literature, American Diabetes Association, and drug manufacturers all recommend giving equal doses (i.e., number of units/day) of long-acting insulins when changing from one long-acting insulin to degludec.^26,63,67 Therefore, we hypothesized that insulin degludec would provide effective glycemic control for rhesus macaques with T2DM when dosed at equivalent doses (that is, the same number of units/day) as insulin glargine. In addition, we hypothesized that CGM devices would provide accurate BG readings as compared with chemistry analyzer and glucometer BG readings, making it a more efficient and effective tool for measurement of BG levels in rhesus macaques with T2DM.     

Design,synthesis and DNA interaction studies of new fluorescent platinum complex containing anti-HIV drug didanosine

Abstract

Forming coordination complexes with nucleoside analogues may be helpful in studying anti-tumour activity of them. Therefore, to improve the clinical efficacy of nucleoside analogue and design new ones, a new fluorescent platinum (Pt) complex with anti-human immunodeficiency virus drug didanosine (ddI); K[PtCl(OCH₃)₂(ddI)]; was synthesized and characterized. The ultraviolet–visible (UV-vis) spectroscopy, infrared, thermogravimetric analysis, mass assignments and elemental analysis confirmed the preparation of the complex. The molecular ion peaks seen at the positive mass spectrum of Pt complex confirm coordination of the drug to metal centre. The interaction of this complex with calf thymus DNA (ct-DNA) was studied using several spectroscopic techniques such as UV absorption, fluorescence spectroscopy and dynamic viscosity measurements. Hyperchromism of the band in the UV-vis spectra and the intrinsic binding constant (0.56?±?0.25) × 10⁴ M^?1, decreasing in Hoechst-DNA fluorescence by adding Pt complex concentration and also relatively small changes in DNA viscosity indicated that this complex could interact as a groove-binder. According to the UV spectra and the fluorescence quenching of the complex in our case seems to be primarily caused by complex formation between the Pt complex and DNA. The thermodynamic parameters showed that hydrogen bond and van der Waals interactions play main roles in the binding of Pt complex to ct-DNA. The free energy values are negative, showing the spontaneity of the Pt complex–DNA binding. The docking simulation was performed and the results confirm a preference of groove site of synthesized complex on DNA helix. The knowledge gained from this study will be helpful to further understand the DNA binding mechanism and can also provide much fruitful information for designing a new type of anti-cancer drugs.

Communicated by Ramaswamy H. Sarma     

Potential of joyweed Alternanthera sessilis for rapid treatment of domestic sewage in SHEFROL® bioreactor

In a first-ever report on this subject, it is shown that a common amphibious plant joyweed (Alternanthera sessilis) can be used in rapid and efficient treatment of biodegradable wastewaters, typified by domestic sewage. The plant was effective when used indoors under artificial lighting, as well as outdoors. It enabled treatment of sewage, varying widely in strength (from 300?mg/L to 1800?mg/L in chemical oxygen demand), to the extent of 78.9–83.9%. It was also able to remove biological oxygen demand, suspended solids, phosphorous, nitrogen, and the heavy metal copper to the extent of 87%, 93%, 45%, and 43%, respectively. Over 99% of total coliforms, faecal coliforms, and faecal streptococci were also removed. The treatment was very swiftly achieved, at a hydraulic retention time of just 6?h, in the “sheet flow root level” (SHEFROL^®) bioreactor developed earlier by us and of which a patent claim has been registered. The findings indicate that A. sessilis has the potential to affect primary, secondary, and tertiary treatment of domestic sewage along with significant pathogen removal in a single process step when used in SHEFROL^® bioreactors.