Room-temperature insertion of elemental tellurium into the Cspł-Br and -I bonds of α-bromo-and α-iodopinacolone

Pinacolyltellurium(IV) dihalides, (t-BuCOCH₂)₂TeX₂ (X ) Br (1b), I (1c)) and Ar(t-BuCOCH₂)TeCl₂ (Ar == 1-C₁₀H₇ (Np) (2a), 2,4,6-Me₃C₆H₂ (Mes) (3a)), are readily prepared at room temperature by the oxidative insertion of elemental tellurium into the C_sp³-Br or -I bond of the α-halopinacolone and by the reaction of ArTeCl₃ with the pinacolone t-BuCOCH₃. The bromides Np(t-BuCOCH₂)TeBr₂ (2b) and Mes(t-BuCOCH₂)TeBr₂ (3b) can be prepared by the addition of bromine to the telluride Ar(t-BuCOCH₂)-Te or of α-bromopinacolone to ArTeBr. Variable-temperature ¹H and ¹³C NMR of the separate signals for the o-Me groups in 3a,b indicate a very high barrier to rotation about the Te-C(aryl) bond. Crystal diffraction data for 1c, 2a-c, and 3b show that intramolecular 1,4-Te …O(C) secondary bonding interactions (SBIs) are retained even in the presence of bulky aryl groups and intermolecular Te …X SBIs are subject to electronic population and steric congestion around the Te(IV) center in the solid state.

3D haptic needle insertion simulator utilising an agent based spherical voxel model

This paper describes a technique for the real-time modeling of deformable tissue. Specifically geared towards needle insertion simulation, the low computational requirements of the model enable highly accurate haptic feedback to a user without introducing noticeable time delay or buzzing generally associated with haptic surgery simulation. Using a spherical voxel array combined with aspects of computational geometry and agent communication and interaction principals, the model is capable of providing haptic update rates of over 1000Hz with real-time visual feedback. Iterating through over 1000 voxels per millisecond to determine collision and haptic response while making use of Vieta’s Theorem for extraneous force culling.

Inadvertent intracranial insertion of nasogastric tubes : An overview and nursing implications

Nasogastric tubes are a commonly used medical device. There are numerous complications associated with their use, one of the most significant is when they are inadvertently inserted into the cranium. Clinicians need to be aware of this complication and the type of patient who is most susceptible.

Pressure- and heat-induced insertion of CO2 into an auxetic small-pore zeolite

When the small-pore zeolite natrolite is compressed at ca. 1.5 GPa and heated to ca. 110 °C in the presence of CO₂, the unit cell volume of natrolite expands by 6.8% and ca. 12 wt % of CO₂ is contained in the expanded elliptical channels. This CO₂ insertion into natrolite is found to be reversible upon pressure release.

Measurement of vein diameter for peripherally inserted central catheter (PICC) insertion: an observational study

Choosing an appropriately sized vein reduces the risk of venous thromboembolism associated with peripherally inserted central catheters. This observational study described the diameters of the brachial, basilic, and cephalic veins and determined the effect of patient factors on vein size. Ultrasound was used to measure the veins of 176 participants. Vein diameter was similar in both arms regardless of hand dominance and side. Patient factors-including greater age, height, and weight, as well as male gender-were associated with increased vein diameter. The basilic vein tended to have the largest diameter statistically. However, this was the case in only 55% of patients.

Vein diameter for peripherally inserted cathether insertion: a scoping review

Background: The risk of venous thromboembolism (VTE) may be reduced if a vein of appropriate diameter is used forperipherally inserted central catheter (PICC) insertion. However, clinicians may have predilections to cannulate certainvein types and use particular insertion sites (eg, right or left arm) and therefore do not necessarily assess all veinsavailable to determine the most optimal vessel to introduce a catheter. It is important that clinicians have anunderstanding of the diameter of veins used for PICC insertion and the effect of patient factors such as hand dominanceon vein size to determine whether their clinical practice is appropriate.

Methods: A scoping review of published literature was performed to determine existing knowledge regarding thediameters of veins used for PICC insertion and the influence of patient factors such as hand dominance and laterality(left or right arm) on vein size.

Results: There was limited published research about the diameters of the basilic, brachial, and cephalic veins at themidupper arm, with only 6 studies identified. Three of the 6 selected articles focused on vein diameter measurement toinform arteriovenous fistula development. Only 1 study included participants undergoing PICC insertion. Scant researchexamined the effect of laterality on vein diameter and 1 study was identified that reported the influence of handdominance or vein type on the diameter of veins used for PICC insertion.

Conclusions: This review found that there is a paucity of studies that have examined the veins used for PICC insertion.Nevertheless, it appears that the basilic vein has the largest diameter (with smaller brachial and cephalic veins),although this is not always the case. Laterality and hand dominance does not seem to influence vein diameter. Furtherresearch about the vasculature used for PICC insertion is needed to inform clinical practice.

High thermal gradient in thermo-electrochemical cells by insertion of a poly(vinylidene fluoride) membrane

Thermo-Electrochemical cells (Thermocells/TECs) transform thermal energy into electricity by means of electrochemical potential disequilibrium between electrodes induced by a temperature gradient (ΔT). Heat conduction across the terminals of the cell is one of the primary reasons for device inefficiency. Herein, we embed Poly(Vinylidene Fluoride) (PVDF) membrane in thermocells to mitigate the heat transfer effects - we refer to these membrane-thermocells as MTECs. At a ΔT of 12 K, an improvement in the open circuit voltage (Voc) of the TEC from 1.3 mV to 2.8 mV is obtained by employment of the membrane. The PVDF membrane is employed at three different locations between the electrodes i.e. x = 2 mm, 5 mm, and 8 mm where 'x' defines the distance between the cathode and PVDF membrane. We found that the membrane position at x = 5 mm achieves the closest internal ΔT (i.e. 8.8 K) to the externally applied ΔT of 10 K and corresponding power density is 254 nWcm-2; 78% higher than the conventional TEC. Finally, a thermal resistivity model based on infrared thermography explains mass and heat transfer within the thermocells.