Most of the human genome, except for a small region that transcribes protein-coding RNAs, was considered junk. With the advent of RNA sequencing technology, we know that much of the genome codes for ...RNAs with no protein-coding potential. Long non-coding RNAs (lncRNAs) that form a significant proportion are dynamically expressed and play diverse roles in physiological and pathological processes. Precise spatiotemporal control of their expression is essential to carry out various biochemical reactions inside the cell. Intracellular organelles with membrane-bound compartments are known for creating an independent internal environment for carrying out specific functions. The formation of membrane-free ribonucleoprotein condensates resulting in intracellular compartments is documented in recent times to execute specialized tasks such as DNA replication and repair, chromatin remodeling, transcription, and mRNA splicing. These liquid compartments, called membrane-less organelles (MLOs), are formed by liquid–liquid phase separation (LLPS), selectively partitioning a specific set of macromolecules from others. While RNA binding proteins (RBPs) with low complexity regions (LCRs) appear to play an essential role in this process, the role of RNAs is not well-understood. It appears that short nonspecific RNAs keep the RBPs in a soluble state, while longer RNAs with unique secondary structures promote LLPS formation by specifically binding to RBPs. This review will update the current understanding of phase separation, physio-chemical nature and composition of condensates, regulation of phase separation, the role of lncRNA in the phase separation process, and the relevance to cancer development and progression.
Efficient optical outcoupling from organic light emitting diodes (OLEDs) is an important challenge in solid state lighting technology. In this work, the effect of an external light extraction layer, ...prepared using polydimethylsiloxane (PDMS) and zinc oxide (ZnO) nanoparticles, was studied on the performance of red, green, blue and white OLEDs. The self-standing flexible film can effectively address the loss modes at the substrate-air interface. With the application of the layer, a maximum enhancement of about 80% in light outcoupling was observed in white OLEDs. Monochrome OLEDs also showed appreciable enhancement in emission with green having the highest improvement (102%), followed by red (56%) and blue (35%). Finite-difference time-domain (FDTD) simulations were performed for elucidating the mechanism behind the improvement in light extraction due to nanoparticle scattering layer. Total-Field Scattered-Field (TFSF) source was used to simulate the scattering cross-section for different wavelengths. Reduced Fresnel reflections at the air-glass interface and advantageous Mie scattering by ZnO nanoparticles seem to increase the optical outcoupling. This film could be a potential candidate for light extraction in OLEDs because of its facile fabrication, economical precursors, and adaptability to flexible substrates and absence of any possible optical artefacts to the emission.
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•Efficient optical outcoupling is an important challenge in OLED research.•We report a polymer –nanoparticle based light extraction film.•Very efficient to control Fresnel reflections at air-glass interface.•Agglomeration of nanoparticles led to advantageous Mie scattering.•About 80% enhancement obtained for white light emission.
Background
Crossed fused renal ectopia is a rare congenital anomaly where both the kidneys are fused and situated on one side and drain bilaterally into the urinary bladder. Rarely crossed fused ...ectopia can present with a single ureter draining ipsilaterally into the bladder, but here we are presenting for the first time a rare case of right crossed fused ectopia, where a solitary ureter crosses midline and drains contralaterally into the bladder.
Case presentation
A 19-year-old adolescent male patient presented with intermittent chronic right flank pain for 3 months. General physical and per abdominal examinations were normal. Computerized tomography (CT) urography showed right side crossed fused ectopic kidneys with a solitary ureter draining both the kidneys and opening into the left side of the urinary bladder. The patient was managed conservatively and is on regular follow-up.
Conclusion
Crossed complete renal fused ectopia with solitary contralateral ureteral is a rare case. Individualized case-based management is needed depending upon the symptoms, associated anomalies, and pathology. Reporting of all rare congenital cases will help in the future understanding and management of these conditions.
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