Facts on Dandruff

Dandruff often occurs after puberty, between 20–30 years of age.

In this article:

What is dandruff?

Causes

Treatments

Symptoms

Effect on your life

How Chemist Online can help

What is dandruff?
Dandruff (also called scurf) is a scalp disorder which can vary in severity. It is basically flaky dead skin which collects in the hair. It tends to affect men more than women.

Symptoms
The main symptom of dandruff is excessive shedding of dead skin cells from the scalp. For most people with this condition, the symptoms are mild. However, in severe cases some people can experience an unusually large amount of flaking. This can also be accompanied by irritation and redness.

Causes
Our skin cells are constantly renewing themselves, and so it is completely normal for skin on the scalp to die and flake off, but dandruff can also be caused by certain triggers such as frequent exposure to extreme cold or heat.

Effect on your life
You may suffer from a lack of confidence or low self-esteem as a result of having dandruff. You may also feel unable or reluctant to wear dark clothing – like a black suit jacket, dress or shirt – in case your dandruff becomes obvious to others.

Treatments
Most cases of dandruff can be easily and effectively treated with specialised shampoos. If these are not effective, arrange an appointment with your GP. He or she may prescribe a steroid lotion to decrease the redness, itching or scaling, and also make sure that your condition is dandruff, and not another skin problem such as psoriasis.

How Chemist Online can help
We have a range of products available that can help you relieve the symptoms of dandruff such as Alpecin Shampoo Double Effect and Head & Shoulders Shampoo – Citrus Fresh.

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This information and advice is not intended to replace the advice of your GP or chemist. Chemist Online is also not responsible or liable for any diagnosis made by a user based upon the content of the Chemist Online website. Chemist Online is also not liable for the contents of any external internet sites listed, nor does it endorse any commercial product or service mentioned or advised on any of the sites.

What are the latest technologies being used to develop ADCs?

Most targets of ADC have unique requirements, including homogenous expression of ADC-accessible tumor surface antigens that internalize well and trafficked to lysosomes. Ideally the ADC targets should have minimal expression of targets in normal tissues of critical importance. These targets could be on tumor membranes or tumor associated cells and in the tumor microenvironment. In the past, the target identification technologies have relied on differential expression- immunohistochemistry (IHC) based target identification. But given the complexity, labor-intensive- time consuming aspects of IHC analysis, there is an urgent need to employ new technologies to rapidly discover new targets for ADCs. New technologies have included (not limited to) tumor genomics and LC-MS/MS proteomics of the membrane proteins, TCGA RNA Seq, and functional genomic mRNA profiling (FGmRNA-profiling). Specially interesting is the FGmRNA-profiling of tumors and normal tissues for new targets.

Bispecifics
Multi-antigen antibodies for ADCs offer unique advantage in specificity for the differential targeting of tumor antigen versus normal tissue antigens. Bispecific ADCs can not only improve TI, they offer better targeting of tumor antigens. Medimmune’s Her2- bispecific- biparatopic ADC (MEDI-4276) allowed a better targeting of Her2- axis, including improved internalization, and lysosomal trafficking. Due-mab antibody technology of Medimmune that utilizes mono-valent interaction with the single target (non-tumor tissues) and bivalent interaction for paired targets (tumor tissues) is uniquely positioned to advance the bispecific ADC landscape. Additionally, there are more than 50 different formats for ADCs and many of these formats are adaptable to ADCs. Currently a large number of bispecific ADCs using these platform are being developed.

Linkers
Stable linkers are critical for the target specific safe delivery of highly potent cytotoxic warheads to tumors. Additionally stable linkers allow the maintenance of ADCs’ extracellular stability (systemic and normal tissue compartments) and intracellular release (e.g., tumors) in the acid environment, the reducing environment and accessibility to deconjugation/release pathways, including lysosomal proteases. Currently, the linkers landscape include hydrazones (acid environment based release), dual peptide (lysosomal protease (s) dependent release) , disulfide (disulfide exchange using typically glutathione) and thioether (proteolytic degradation similar to proteins). Typically there are two types of linkers, cleavable an non-cleavable, though, most ADC construct use cleavable linkers. Acid labile hydrazone linkers take the advantage of highly acidic compartment of tumors. Protease cleavable dipeptide linkers such as Val-Ala and Val-Cit take advantage of the unique lysosomal proteases highly dominated in many tumors while disulfide linkers take the advantage of highly abundant reducing hypoxia rich environment of some tumors.

Biochempeg has over 3000 high purity PEG linkers in stock for pharmaceutical and biotech R&D, such as mPEG, Biotin PEG, Amine PEG, Azide PEG, DSPE PEG, and others.

Non-cleavable stable linkers are designed to degrade ADCs naturally similar to all naked antibodies by the proteolytic degradation. The non-cleavable linkers require intracellular uptake and are not degraded by blood enzymes allowing very high degree of extracellular stability. The thioether technology developed by Genentech was used in generation of non-cleavable linker for ado-trastuzumab emtansine (Kadcyla™; Genentech/Roche). Although there are great stability and safety advantages for non-cleavable linkers for maintaining high systemic stability, they often modify cytotoxic warheads to largely polar entities during proteolytic degradation and reduce the bystander potency of warheads. In some cases, polar warheads generated during proteolytic degradation of non-cleavable linkers enabled ADCs get stuck inside the cell (e,g., lysosomes) and are unable to make their site of action (e.g., DNA in nucleus).

Translational
ADCs are different from chemotherapeutic cytotoxic drugs (small molecule based cellular uptake mainly through diffusion) because they need tumor target binding and internalization for the intracellular delivery of the cytotoxic warheads. Given very limited intracellular distribution of ADCs ( typically less 1% of the injected dose) even with high target expression on tumors, it is imperative that translational approaches include those patients whose tumors have high expression of targeted antigens, at least during the expansion stage of Phase I trials at or near the MTD dose. If the candidate ADC shows good activity or insufficient activity in tumors with high and homogeneous expression of antigens, this may serve as a major Go or No Go decision criteria. Given the limitations of invasive tumor biopsies, non-invasive PET bioimaging approaches are increasingly being to identify patients who have high expression of tumor antigens. Additionally, unique sensitivity of certain DNA repair deficient tumors to certain warheads (e.g., PBD) is being further assessed. Translational approaches may also include defining tumor resistance pathways and the pairing of the warheads with the targets. If a tumor has a very high expression of topoisomerase II (TOP-II) but resistance to tubulin inhibition or DNA damaging agents, it may be prudent to use TOP-II inhibitor based ADC. Biomarkers such as circulating tumor DNA, tumor derived exosomes are increasingly being used.

Standard Treatment of LSAW Steel Pipe after Welding

The heat treatment after welding is a new technique to eliminate residual stress. Preheating the material to the post-heat treatment temperature before welding and welding of the workpiece continued to keep the heating temperature, the use of insulation after the completion of the insulation of cotton to its slow cooling. This method can effectively reduce the welding residual stress and improve the stress corrosion resistance of metal.

After welding heat treatment can effectively reduce the welding residual stress, and the higher the heat treatment temperature, the better the residual stress elimination effect. The heat treatment of large diameter lsaw steel pipe can effectively improve the stress corrosion resistance of large diameter steel pipe. The higher the temperature of post-heat treatment, the more remarkable the stress corrosion resistance is. Diffusion method Metal carbide coating steel pipe technology is the workpiece placed in special media, the proliferation of role in the workpiece surface to form a layer of several microns to tens of microns of metal carbide layer. Large-diameter lsaw steel pipe buried pipe and corrosion of the internal corrosion, are linked to galvanized iron wire mesh, spray compressive strength of not less than 30N / mm2 cement mortar lining.

Nondestructive testing of the weld inside Because the pipe in the water supply project is very large steel pipe, especially the thickness t = 30mm steel pipe is used as a pipe bridge, it is necessary to withstand the internal water pressure, but also by the structural steel pipe weight and water body formation Bending moment, so the quality of the welding requirements are particularly high. For the pipe bridge with t = 30mm thick large diameter steel pipe, the longitudinal seam and girth are belong to a class of welds, requiring 100% of the X-ray film inspection and 100% of the ultrasonic flaw detection; and thickness t = 24mm buried steel pipe, longitudinal seam is a class of welding, 20% of the X-ray film inspection and 50% of the ultrasonic flaw detection.