Evaluation of Latent Fingerprints for Drug Screening in a Social Care Setting.

Sweat deposited via latent fingerprints (LFPs) was previously used to detect cocaine, opioids, cannabis and amphetamine via a point-of-care test (POCT). This screening method combined non-invasive sampling with a rapid result turnaround to produce a qualitative result outside of the laboratory. We report the novel application of a LFP drug screening test in a social care setting. Clients were tested on either an ad hoc or a routine basis using the POCT DOA114 (Intelligent Fingerprinting Ltd) drug screening cartridge. Screening cutoff values were 45, 35 and 95 pg/fingerprint for benzoylecgonine (BZE), morphine and amphetamine analytes, respectively. Confirmation LFP samples (DOA150, Intelligent Fingerprinting Ltd) and oral fluid (OF) were analyzed using ultra-performance liquid chromatography with tandem mass spectrometry. Thirty-six clients aged 36 ± 11 years participated (53% females). Individuals self-reported alcohol consumption (39%) and smoking (60%). Of 131 screening tests collected over 8 weeks, 14% tested positive for cocaine, 2% tested positive for opioids and 1% tested positive for amphetamine. Polydrug use was indicated in 10% of tests. Of 32 LFP confirmation tests, 63% were positive for cocaine and BZE. Opioids were also detected (31%), with the metabolite 6-monoacetylmorphine (6-MAM) being the most common (16%). In OF, cocaine was the dominant analyte (9%) followed by 6-MAM (5%). On comparing positive LFP screening tests with positive OF samples, we found that 39% and 38% were cocaine and opiate positive, respectively. Of the drugs screened for via the LFP POCT, cocaine was the most prevalent analyte in LFP and OF confirmation samples. The study is a step change in the routine drug screening procedures in a social care setting, especially useful for on-site cocaine detection in clients whose drug use was being monitored. Additionally, testing was easily accepted by clients and social care workers.

Repurposing Melt Degradation for the Evaluation of Mixed Amorphous-Crystalline Blends.

Medicine regulators require the melting points for crystalline drugs, as they are a test for chemical and physical quality. Many drugs, especially salt-forms, suffer concomitant degradation during melting; thus, it would be useful to know if the endotherm associated with melt degradation may be used for characterising the crystallinity of a powder blend. Therefore, the aim of this study was to investigate whether melt-degradation transitions can detect amorphous content in a blend of crystalline and amorphous salbutamol sulphate. Salbutamol sulphate was rendered amorphous by freeze and spray-drying and blended with crystalline drug, forming standards with a range of amorphous content. Crystalline salbutamol sulphate was observed to have a melt-degradation onset of 198.2±0.2°C, while anhydrous amorphous salbutamol sulphate prepared by either method showed similar glass transition temperatures of 119.4±0.7°C combined. Without the energy barrier provided by the ordered crystal lattice, the degradation endotherm for amorphous salbutamol sulphate occurred 50°C below the melting point, with an onset of 143.6±0.2°C. The enthalpies for this degradation transition showed no significant difference between freeze- and spray-dried samples (p>0.05). Distinct from convention, partial integration of the crystalline melt-degradation endotherm was applied to the region 193-221°C which had no contribution from the degradation of amorphous salbutamol sulphate. The linear correlation of these partial areas with amorphous content, R2=0.994, yielded limits of detection and quantification of 0.13% and 0.44% respectively, independent of drying technique. Melt-degradation transitions may be re-purposed for the measurement of amorphous content in powder blends, and they have potential for evaluating disorder more generally.

A novel natural GRAS-grade enteric coating for pharmaceutical and nutraceutical products.

In this study, enteric coatings based exclusively on naturally occurring ingredients were reported. Alginate (Alg) and pectin (Pec) blends with or without naturally occurring glyceride, glycerol monostearate (GMS), were initially used to produce solvent-casted films. Incorporating GMS in the natural polymeric films significantly enhanced the acid-resistance properties in gastric medium. Theophylline tablets coated with Alg-Pec blends without GMS disintegrated shortly after incubation in gastric medium (pH 1.2), leading to a premature and complete release of theophylline. Interestingly, tablets coated with Alg-Pec blends that contain the natural glyceride (GMS) resisted the gastric environment for 2 h with minimal drug release (<5%) and disintegrated rapidly following introduction to the intestinal medium, allowing a fast and complete drug release. Furthermore, the coating system proved to be stable for six months under accelerated conditions. These findings are particularly appealing to nutraceutical industry as they provide the foundation to produce naturally-occurring GRAS based enteric coatings.

Glycerol Solvates DPPC Headgroups and Localizes in the Interfacial Regions of Model Pulmonary Interfaces Altering Bilayer Structure.

The inclusion of glycerol in formulations for pulmonary drug delivery may affect the bioavailability of inhaled steroids by retarding their transport across the lung epithelium. The aim of this study was to evaluate whether the molecular interactions of glycerol with model pulmonary interfaces provide a biophysical basis for glycerol modifying inhaled drug transport. Dipalmitoylphosphatidylcholine (DPPC) monolayers and liposomes were used as model pulmonary interfaces, in order to examine the effects of bulk glycerol (0-30% w/w) on their structures and dynamics using complementary biophysical measurements and molecular dynamics (MD) simulations. Glycerol was found to preferentially interact with the carbonyl groups in the interfacial region of DPPC and with phosphate and choline in the headgroup, thus causing an increase in the size of the headgroup solvation shell, as evidenced by an expansion of DPPC monolayers (molecular area increased from 52 to 68 Å2) and bilayers seen in both Langmuir isotherms and MD simulations. Both small angle neutron scattering and MD simulations indicated a reduction in gel phase DPPC bilayer thickness by ∼3 Å in 30% w/w glycerol, a phenomenon consistent with the observation from FTIR data, that glycerol caused the lipid headgroup to remain oriented parallel to the membrane plane in contrast to its more perpendicular conformation adopted in pure water. Furthermore, FTIR measurements suggested that the terminal methyl groups of the DPPC acyl chains were constrained in the presence of glycerol. This observation is supported by MD simulations, which predict bridging between adjacent DPPC headgroups by glycerol as a possible source of its putative membrane stiffening effect. Collectively, these data indicate that glycerol preferentially solvates DPPC headgroups and localizes in specific areas of the interfacial region, resulting in structural changes to DPPC bilayers which may influence cell permeability to drugs.