Lang honored by physical therapy association – Washington University School of Medicine in St. Louis

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Recognized for leadership, achievements in advancing physical therapy field

Lang

Catherine Lang, PT, PhD, professor of physical therapy, of neurology and of occupational therapy, and associate director of the Movement Science Program at Washington University School of Medicine in St. Louis, has been named a Catherine Worthingham Fellow of the American Physical Therapy Association.

The award, the associations highest honor, serves as an inspiration for physical therapists to attain professional excellence and recognizes physical therapists who have demonstrated unwavering efforts to advance the profession.

Lang studies neural control of movement, particularly as it applies to stroke recovery and rehabilitation. In the past 15 years, her laboratory has been developing and testing motor rehabilitation interventions based on neuroscience and motor learning principals in people with stroke.

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Lang honored by physical therapy association - Washington University School of Medicine in St. Louis

Global Motor Neuron Diseases Treatment Market by Top Key players: NIH, UCL Institute of Neurology, National Neuroscience Institute, The University of…

This report focuses on global Motor Neuron Diseases Treatment status, future forecast, growth opportunity, key market, and key players. The study objectives are to present the Motor Neuron Diseases Treatment development in the United States, Europe, and China.

In 2019, the global Motor Neuron Diseases Treatment market size was million US$ and it is expected to reach million US$ by the end of 2025, with a CAGR of during 2025-2025.

The report also summarizes the various types of Motor Neuron Diseases Treatment market. Factors that influence the market growth of particular product category type and market status for it. A detailed study of the Motor Neuron Diseases Treatment Market has been done to understand the various applications of the usage and features of the product. Readers looking for scope of growth with respect to product categories can get all the desired information over here, along with supporting figures and facts.

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Top Key players: NIH, UCL Institute of Neurology, National Neuroscience Institute, The University of Melbourne, The University of Sheffield, OZBiosciences, The University of Queensland, MND Australia

Motor Neuron Diseases Treatment Market: Regional Segment Analysis.

This report provides pin-point analysis for changing competitive dynamics. It offers a forward-looking perspective on different factors driving or limiting market growth. It provides a five-year forecast assessed based on how the Motor Neuron Diseases Treatment Market is predicted to grow. It helps in understanding the key product segments and their future and helps in making informed business decisions by having complete insights of market and by making an in-depth analysis of market segments.

Key questions answered in the report include:

What will the market size and the growth rate be in 2026?

What are the key factors driving the Global Motor Neuron Diseases Treatment Market?

What are the key market trends impacting the growth of the Global Motor Neuron Diseases Treatment Market?

What are the challenges to market growth?

Who are the key vendors in the Global Motor Neuron Diseases Treatment Market?

What are the market opportunities and threats faced by the vendors in the Global Motor Neuron Diseases Treatment Market?

Trending factors influencing the market shares of the Americas, APAC, Europe, and MEA.

The report includes six parts, dealing with:

1.) Basic information;

2.) The Asia Motor Neuron Diseases Treatment Market;

3.) The North American Motor Neuron Diseases Treatment Market;

4.) The European Motor Neuron Diseases Treatment Market;

5.) Market entry and investment feasibility;

6.) The reports conclusion.

All the research report is made by using two techniques that are Primary and secondary research. There are various dynamic features of the business, like client need and feedback from the customers. Before (company name) curate any report, it has studied in-depth from all dynamic aspects such as industrial structure, application, classification, and definition.

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This report provides pin-point analysis for changing competitive dynamics

It provides a forward-looking perspective on different factors driving or restraining the market growth

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It helps in understanding the key product segments and their future

It provides pin point analysis of changing competition dynamics and keeps you ahead of competitors

It helps in making informed business decisions by having complete insights of market and by making an in-depth analysis of market segments

TABLE OF CONTENT:

1 Report Overview

2 Global Growth Trends

3 Market Share by Key Players

4 Breakdown Data by Type and Application

5 United States

6 Europe

7 China

8 Japan

9 Southeast Asia

10 India

11 Central & South America

12 International Players Profiles

13 Market Forecast 2025-2025

14 Analysts Viewpoints/Conclusions

15 Appendix

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Exploring future spinal cord injury therapies – Drug Target Review

Drug Target Review explores five of the latest research developments in the field of spinal cord injury (SCI) repair.

MRIs of Lumbar & Thoracic spine showing how a fracture of thoracic spine gets worse over time.

Researchers have shown that increasing energy supply to injured spinal cord neurons can promote axon regrowth and motor function restoration after a spinal cord injury (SCI).

We are the first to show that spinal cord injury results in an energy crisis that is intrinsically linked to the limited ability of damaged axons to regenerate, said Dr Zu-Hang Sheng, study co-senior author, senior principal investigator at the US National Institute of Neurological Disorders and Stroke (NINDS).

According to the team, energy levels are damaged because the mitochondria that produce adenosine triphosphate (ATP) for neurons are located in the axons. When damaged, the mitochondria are unable to produce ATP at the same level.

Nerve repair requires a significant amount of energy, said Dr Sheng. Our hypothesis is that damage to mitochondria following injury severely limits the available ATP and this energy crisis is what prevents the regrowth and repair of injured axons.

The scientists suggest that this is compounded by the anchoring of mitochondria in adult cells alongside the axons, so once damaged they are hard to replace.

Using a murine model, called a Syntaphilin knockout, where mitochondria are free to move along the axons, the researchers showed that when mitochondria are more mobile, mice have significantly more axon regrowth across the site of SCI compared to control animals. The paper also demonstrated that newly-grown axons made appropriate connections beyond the injury site, leading to functional recovery of motor tasks.

They hypothesised that increasing mitochondrial transport and thus the available energy to the injury site could enable repair of damaged nerve fibres.

When fed creatine, a compound that enhances the formation of ATP, both the control and knockout mice had increased axon regrowth following injury, compared to mice fed saline instead. More robust nerve regrowth was seen in the knockout mice that received creatine.

We were very encouraged by these results, said Dr Sheng. The regeneration that we see in our knockout mice is very significant and these findings support our hypothesis that an energy deficiency is holding back the ability of both central and peripheral nervous systems to repair after injury.

Dr Sheng highlighted that despite the promising results of the study published in Cell Metabolism, genetic manipulation was required for the best regrowth as creatine produced only modest regeneration. He concluded that further research is required to develop therapeutic compounds that are more effective in entering the nervous system and increasing energy production for the treatment of SCI.

Experiments exploring the role of immune and glial cells in wound healing and neural repair has revealed that Plexin-B2, an axon guidance protein, is essential for their organisation after SCI.

The researchers suggest their findings could aid in the development of therapies that target axon guidance pathways for treatment of SCI.

An artists impression of a macrophage.

The paper published in Nature Neuroscience reveals that Plexin-B2 on macrophages and microglia is essential for the process of corralling, where microglia and macrophages are mobilised and form a protective barrier around the site of SCI, separating healthy and necrotic tissue. In this study, researchers found that corralling begins early in the healing process and requires the ability of Plexin-B2 to steer immune cells away from colliding cells.

When they deleted Plexin-B2 from the microglia and macrophages in tissues, it led to tissue damage, inflammatory spillover and hindered axonal regeneration.

The lead investigator Dr Hongyan Jenny Zou, Professor of Neurosurgery and Neuroscience at the Icahn School of Medicine at Mount Sinai, US, said the results were quite unexpected.

She concluded that understanding the signalling pathways and interactions of glial cells with each other and the injury environment is fundamental to improving neural repair after a traumatic brain or spinal cord injury.

Another studyexploring the interactions of macrophages and microglia has revealed that in the central nervous system (CNS), microglia interfere with macrophages preventing them from moving out of damaged regions of the CNS.

We expected the macrophages would be present in the area of injury, but what surprised us was that microglia actually encapsulated those macrophages and surrounded them almost like police at a riot. It seemed like the microglia were preventing them from dispersing into areas they should not be, said Jason Plemel, a medical researcher at Canadas University of Alberta and a member of the Neuroscience and Mental Health Institute.

A microglial cell stained with Rio Hortegas silver carbonate method under the microscope.

Plemel said that more research is required to ascertain why this is happening, but they found that both the immune cells that protect the CNS, microglia and the immune cells of the peripheral immune system, macrophages, are present early after demyelination and microglia continue to accumulate at the expense of macrophages.

When we removed the microglia to understand what their role was, the macrophages entered into uninjured tissue. This suggests that when there is injury, the microglia interfere with the macrophages in our CNS and act as a barrier preventing their movement.

The scientists said that this observation was only possible because they were able to distinguish between microglia and macrophages, which has historically not been possible. Using this technique, they established than one type of microglia responded to demyelination. The results were published in Science Advances.

The indication of at least two different populations of microglia is an exciting confirmation for us, said Plemel. We are continuing to study these populations and hopefully, in time, we can learn what makes them unique in terms of function. The more we know, the closer we get to understanding what is going on (or wrong) when there is neurodegeneration or injury and being able to hypothesise treatment and prevention strategies.

Researchers suggest subpially-injecting neural precursor cells (NSCs) may reduce the risk of further injury associated with current spinal cell delivery techniques.

NSCs have the potential to differentiate into many neural cell types depending on the environment and have been the subject of investigation in both the field of SCI repair and neurodegenerative disease therapies.

subpially-injected cells are likely to accelerate and improve treatment potency in cell-replacement therapies for several spinal neurodegenerative disorders

However, the senior author of this study Dr Martin Marsala, professor in the Department of Anesthesiology at University of California (UC) San Diego School of Medicine, US, explained the current delivery techniques involve direct needle injection into the spinal parenchyma the primary cord of nerve fibres running through the vertebral column, so there is an inherent risk of (further) spinal tissue injury or intraparenchymal bleeding.

The novel technique Dr Marsala proposed in a paper published in Stem Cells Translational Medicine, is to inject these cells into the spinal subpial space an area between the pial membrane and the superficial layers of the spinal cord.

This injection technique allows the delivery of high cell numbers from a single injection, Dr Marsala explained. Cells with proliferative properties, such as glial progenitors, then migrate into the spinal parenchyma and populate over time in multiple spinal segments as well as the brain stem. Injected cells acquire the functional properties consistent with surrounding host cells.

The research collaborators suggest that subpially-injected cells are likely to accelerate and improve treatment potency in cell-replacement therapies for several spinal neurodegenerative disorders. This may include spinal traumatic injury, amyotrophic lateral sclerosis and multiple sclerosis, said study senior author Dr Joseph Ciacci, a neurosurgeon at UC San Diego Health.

The team now intend to move their experiments from rats to larger pre-clinical animal models, more anatomically similar to humans. The goal is to define the optimal cell dosing and timing of cell delivery after spinal injury, which is associated with the best treatment effect, concluded Dr Marsala.

Dr Mohamad Khazaei is the recipient of the STEM CELLS Translational Medicines (SCTM) Young Investigator Award for his work on SCI.

The award recognises advancements in the field of stem cells and regenerative medicine made by young researchers. The recipient is the principal author of an article published in SCTM that, over the course of a year, is deemed to have the most impact.

Dr Khazaeis work focuses on bringing cell-based strategies, such as NSC transplantation, into the therapeutic pipeline through generating and differentiating novel cell types using genetic and cell engineering approaches.

While we currently lack effective regenerative medicine treatment options for spinal cord injuries, Dr Khazaeis work to create a cell transplantation therapy utilising neural precursor cells is novel and provides a promising approach, said Dr Anthony Atala, Editor-in-Chief of SCTM and director of the Wake Forest Institute for Regenerative Medicine.

His winning paper details how Dr Khazaei and his team used neurons and oligodendrocytes to obtain better functional recovery after SCI.

Related topicsCell Regeneration, CNS, Disease research, Drug Delivery, Drug Discovery, Drug Targets, Neurons, Neurosciences, Regenerative Medicine, Research & Development, Therapeutics

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Exploring future spinal cord injury therapies - Drug Target Review

Experts discover toolkit to repair DNA breaks associated with ageing, cancer and Motor Neurone Disease – University of Sheffield News

9 March 2020

A new toolkit to repair damaged DNA that can lead to ageing, cancer and motor neurone disease (MND) has been discovered by scientists at the Universities of Sheffield and Oxford.

Published in Nature Communications, the research shows that a protein called TEX264, together with other enzymes, is able to recognise and eat toxic proteins that can stick to DNA and cause it to become damaged. An accumulation of broken, damaged DNA can cause cellular ageing, cancer and neurological diseases such as MND.

Until now, ways of repairing this sort of DNA damage have been poorly understood, but scientists hope to exploit this novel repair toolkit of proteins to protect us from ageing, cancer and neurological disease.

The findings could also have implications for chemotherapy, which deliberately causes breaks in DNA when trying to kill cancerous cells. Scientists believe targeting the TEX264 protein may offer a new way to treat cancer.

Professor Sherif El-Khamisy, Co-Founder and Deputy Director of the Healthy Lifespan Institute at the University of Sheffield and a professor from the Department of Molecular Biology and Biotechnology and the Neuroscience Institute at the University of Sheffield, who co-led the research said: Failure to fix DNA breaks in our genome can impact our ability to enjoy a healthy life at an old age, as well as leave us vulnerable to neurological diseases like motor neurone disease (MND).

We hope that by understanding how our cells fix DNA breaks, we can help meet some of these challenges, as well as explore new ways of treating cancer in the future.

Professor Kristijan Ramadan from the University of Oxford, who co-led the research, said: Our finding of TEX264, a protein that forms the specialised machinery to digest toxic proteins from our DNA, significantly changes the current understanding of how cells repair the genome and so protect us from accelerated ageing, cancer and neurodegeneration. I believe this discovery has a great potential for cancer therapy in the future and we are already pursuing our research in this direction.

Professor Ramadan added: I am very proud of my research team who initially discovered the involvement of TEX264 in DNA repair.

Oxfords research was supported by funding bodies, including the Medical Research Council. Backing was also received from the Oxford Institute for Radiation Oncology and Department of Oncology.

Professor El-Khamisys lab is funded by the Wellcome Trust and the Lister Institute of Preventative Medicine.

The work forms part of the research taking place at the University of Sheffields Healthy Lifespan Institute and the Neuroscience Institute.

The Healthy Lifespan Institute brings together 120 world-class researchers from a wide range of disciplines with the aim of slowing down the ageing process and tackling the global epidemic of multi-morbidity the presence of two or more chronic conditions in a bid to help everyone live healthier, independent lives for longer and reduce the cost of care.

The Neuroscience Institute aims to translate scientific discoveries from the lab into pioneering treatments that will benefit patients living with neurodegenerative disorders.

The next step of the research will be to test if the behaviour and properties of protein TEX264 is altered in ageing and in neurological disorders such as MND.

The University of SheffieldWith almost 29,000 of the brightest students from over 140 countries, learning alongside over 1,200 of the best academics from across the globe, the University of Sheffield is one of the worlds leading universities.

A member of the UKs prestigious Russell Group of leading research-led institutions, Sheffield offers world-class teaching and research excellence across a wide range of disciplines.

Unified by the power of discovery and understanding, staff and students at the university are committed to finding new ways to transform the world we live in.

Sheffield is the only university to feature in The Sunday Times 100 Best Not-For-Profit Organisations to Work For 2018 and for the last eight years has been ranked in the top five UK universities for Student Satisfaction by Times Higher Education.

Sheffield has six Nobel Prize winners among former staff and students and its alumni go on to hold positions of great responsibility and influence all over the world, making significant contributions in their chosen fields.

Global research partners and clients include Boeing, Rolls-Royce, Unilever, AstraZeneca, Glaxo SmithKline, Siemens and Airbus, as well as many UK and overseas government agencies and charitable foundations.

For further information please contact:

Shemina DavisMediaRelations ManagerThe University of Sheffield0114 222 5339shemina.davis@sheffield.ac.uk

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Experts discover toolkit to repair DNA breaks associated with ageing, cancer and Motor Neurone Disease - University of Sheffield News

Study: Cough That Spreads Tuberculosis Has Pain-Linked Trigger – University of Texas at Dallas

Mycobacterium tuberculosis, which causes TB, produces a fatty acid called sulfolipid-1 that triggers a pain-response cough to spread the disease, according to a study published March 5 in the journal Cell. M. tuberculosis bacteria are shown in the close-up view.

Tuberculosis is distinguished primarily by the persistent cough that serves to spread the disease. Stopping whatever triggers that cough could greatly reduce the transmission of the disease, which annually kills more than 1.3 million people worldwide.

Researchers from The University of Texas at Dallas Center for Advanced Pain Studies worked with colleagues from UTSouthwestern Medical Center to pinpoint a molecule that the tuberculosis bacterium manufactures to induce coughing.

Their findings, published online March 5 in the journal Cell, could help reduce the impact of tuberculosis, which remains one of the top 10 causes of death worldwide, according to the World Health Organization.

Tuberculosis deaths have been greatly reduced in the United States, but it is still a huge issue in many parts of the world, and we would love to have an impact on stopping the spread of the disease, said Dr. Ted Price BS97, Eugene McDermott Professor of neuroscience in the School of Behavioral and Brain Sciences (BBS) and one of five UTDallas authors of the Cell paper. Discovering the mechanism through which TB causes cough affords just such an opportunity, and our collective team has the appropriate expertise to tackle this problem, which we have started to accomplish through this work.

From left: School of Behavioral and Brain Sciences faculty members Drs. Ted Price, Gregory Dussor and Michael Burton were among the authors of the paper published March 5 in Cell.

The idea that nociceptors the nerve cells that respond to pain stimuli cause the coughing associated with TB runs counter to existing suppositions that link the cough to infection-induced lung inflammation or irritation.

No one had ever shown that TB produces an irritant that acts directly on the sensory innervation of the lungs, Price said. We have now shown this directly through our collaborative work on this project.

In testing on rodents, researchers sought to identify the components or products of the Mycobacterium tuberculosis that cause coughing or trigger nociceptors. Ultimately, they identified a fatty acid called sulfolipid-1 (SL-1) as a pain-response trigger. They then reproduced that response in isolated human nociceptor cells. Finally, the researchers altered a strain of Mycobacterium tuberculosis to not produce SL-1. Rodents infected with this version developed other tuberculosis symptoms, but not coughing.

If researchers can show that suppressing cough does not worsen the condition of tuberculosis patients, the spread of the disease might be prevented by developing a drug that inhibits SL-1 production, Price said.

No one had ever shown that TB produces an irritant that acts directly on the sensory innervation of the lungs. We have now shown this directly through our collaborative work on this project.

Dr. Ted Price BS97, Eugene McDermott Professor of neuroscience in the School of Behavioral and Brain Sciences

People with active tuberculosis can cough for months and spread disease even when they are receiving appropriate treatment, said corresponding author Dr. Michael Shiloh, associate professor of internal medicine and microbiology at UTSouthwestern. Someday, doctors may give antibiotics in conjunction with a medication that prevents coughing, which in turn could prevent spread.

Additional UTDallas authors were Dr. Gregory Dussor, associate professor of cognition and neuroscience and Fellow, Eugene McDermott Professor; Dr. Michael Burton, assistant professor in BBS; Dhananjay Naik, a doctoral student in cognition and neuroscience; and Galo Mejia, a graduate student in innovation and entrepreneurship and a research assistant in BBS. Other UTSouthwestern authors included Dr. Connie Hsia, professor of internal medicine; Dr. Tian Qin, assistant professor of biochemistry and a Eugene McDermott Scholar in Biomedical Research; Dr. Laurent Gautron, assistant professor of internal medicine; and first author Cody Ruhl, a graduate student and member of Shilohs lab.

The work of UTDallas researchers was supported in part by grants from the National Institute of Neurological Disorders and Stroke, a component of the National Institutes of Health (R01NS104200, R01NS065926). The Burroughs Wellcome Fund and The Welch Foundation also supported the study.

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Study: Cough That Spreads Tuberculosis Has Pain-Linked Trigger - University of Texas at Dallas

Anatomy & Physiology: Current Research

PubMed NLM ID: 101576822Index Copernicus Value:84.15

Anatomy andPhysiology: Current Research is an international open access, peer-reviewed, academic journal that aims to publish original research articles, clinical trials, reviews, case report, editorials, letter to the editor, short communication, opinion, book review, commentaries, short reviews and other special featured articles related to anatomy & physiology.

Anatomy and physiology: current research focuses on publishing scholarly articles from the areas such as:

Journal is open to original research articles and clinical cases as well studies covering clinical and applied topics on anatomy and physiology on areas such as:

Editorial board members of Anatomy & Physiology: Current Research or outside experts review manuscripts; at least two independent reviewers approval followed by the editor is required for the acceptance of any citable manuscript

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Anatomy & Physiology: Current Research

The Basics of Drawing Anatomy for Artists – Artists Network

Drawing Anatomy

The study of human anatomy, for artists, can be as simple and straightforward as learning about proportions and working from life, or as involved and complex as mastering an understanding of the skeletal, muscular, and surface structure of the human body. Artists pursue anatomy drawing to learn how to draw a human form as it appears in various positions or postures. Oftentimes, anatomy for the artist revolves around creating detailed anatomy drawings and anatomy sketches that can be referred back to in the studio.

This topic page will guide you towards links, resources and youtube tutorials to help you on your way to mastering drawing the human body. For more inspiration, follow Artist Dailys Anatomy board on Pinterest.

Drawing male vs female hips Many artists who focus exclusively on the female form struggle to translate their talent to drawing men. Thats why its important to study the two forms and practise drawing people and their different forms.

Drawing feetA quarter of our bones are in our feet, which can make feet among the most difficult things parts of the body to draw. A good way to master the foot structure is to study medical drawings of the bones and work from there to muscles and skin.

Anatomy drawing inspirationMedical books are a great place to start when discovering the human form. After all, Da Vinci himself drew directly from cadavers. Learning the position of ligaments and tendons will teach you the right way that muscles sit on the body, and avoid any awkard positioning of muscle structure.

Drawing gesturesBy learning how to draw gestures even by means of simple stick drawing at first you can expand your understanding of how the body looks when creating those movements. By mastering common poses, you can improve your anatomy drawing dramatically.

Common anatomy drawing mistakesForgetting about the natural variations in skin can result in inaccuracies when drawing live models. Always take into account a models sun tan and natural pigmentation when youre coding the values of the skin tones, since that will cause certain parts of the body to appear more forward or backward than others.

For body drawings that look real and are incredibly satisfying to know that YOU are capable of drawing, learn alongside Brent Eviston in this drawing lesson.

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The Basics of Drawing Anatomy for Artists - Artists Network

The Sexual Anatomy Of Women: Vulva and Vagina

FEMALE EXTERNAL GENITALIA: VULVA, LABIA, and CLITORIS

The Vulva is the external sexual organ of women. The above view (A)shows the external view of the female vulva as normally seen when the womanis standing up. View (B) shows the vulva when it is opened, and from thetop down one can clearly see the Veneris Mons, clitoral hood, clitoris,and labia minora. There are many questions about the vulva on alt.sex,and this FAQ will begin to attempt to answer some of these.

The above illustrations show the area between the labia minora. Fromtop to bottom can be clearly seen the clitoris, urethral opening, and vaginalopening. A, B, and C show vaginal openings with a normal hymen,a membrane that partially covers the opening. The hymen is the traditional"symbol" of virginity, although being a very thin membrane, itcan be torn by vigorous exercise or the insertion of a tampon. IllustrationD shows an imperforate hymen that completely closes the vagina; this rarecondition requires surgical intervention to provide for a normal flow ofblood once menstruation begins. Illustration E is of a vagina in a post-partumwoman (one who has given birth).

The Grafenberg spot, or G-spot, is an area located within the anterior(or front) wall of the vagina, about one centimetre from the surface andone-third to one-half way in from the vaginal opening (see illustrationand text). It is reported to consist of a system of glands (Skene's glands)and ducts that surround the urethra (Heath, 1984). Some authors write thatyou must press "deeply" into the tissue with two fingers to reachit with any effectiveness.

The significance of the G-spot is that some women (about half) reportthat it is a highly sensitive area that under the right conditions canbe very pleasurable if stimulated. For some women, it can be a primarysource of stimulation leading to orgasm during intercourse. Other womenreport no particular stimulation, and some say that it feels as if theyneed to urinate.

The G-Spot has been linked to the phenomenon known as female ejaculation.To date, there is little data about female ejaculation, although thereis some speculation that it is the product of the Skene's glands.

Toxic Shock Syndrome (TSS) is a rare but serious illness which can occurin men, women and children. About half the number of cases reported areassociated with using tampons and affect a tiny number of women every year--only about 1 out of every 1.5 million women who have periods. TSS can occasionallybe fatal.

Toxic Shock Syndrome can be treated successfully providing it is recognisedquickly, and most young people make a full recovery. Younger people maymore at risk from the bacteria which are believed to cause this rare condition,because their immune system may not be fully developed.

In the unlikely event that you have these symptoms during your period--ahigh fever (over 102F or 39C), rash, vomiting, diarrhoea, sore throat,dizziness or fainting - you must remove your tampon and consult yourdoctor immediately. These symptoms can be early warning signs of TSS,which can develop very quickly and may seem like flu to begin with.

Do not worry about wasting the doctor's time and remember to say youhave been wearing a tampon. Do not use tampons again without checking firstwith your doctor.

By using tampons correctly and following the advice below, you willreduce the risk of developing TSS.

The alt.sex FAQ is hosted by SACRED SEX|ALT SEX FAQ HOME | INDEX | POLICY | DEFINITION OF SEXUAL TERMS | |THE PENIS | THE VULVA, CLITORIS, AND VAGINA | FIRST TIME SEX | GREAT TIME SEX | |ORAL SEX FOR MEN (FELLATIO) | ORAL SEX FOR WOMEN (CUNNILINGUS) | |ANAL SEX AND ANALINGUS | SEX TOYS | CONTRACEPTION (BIRTH CONTROL) | |SEXUALLY TRANSMITTED DISEASES | LEGALITY (SODOMY LAWS, AGE OF CONSENT) |

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The Sexual Anatomy Of Women: Vulva and Vagina

Anatomy of the fall (an update) – Marcus Padley – Livewire Markets

You are supposed to use a log scale on a share price chart if looking at charts over a long period of time. The basic explanation is that a log chart shows two equivalent percentage price changes represented by the same vertical distance on the scale and to accommodate that the distance between the numbers on the scale decreases as the price of the asset increases.

I read one article this morning talking about the Historic coronavirus correction. This is a 100-year chart of the Dow Jones using a normal price scale. The 1929 Crash and the 1987 Crash, because they were so long ago when the index was just a few hundred points, are now considered, on this chart, irrelevant.

But if you lived through 1929 or 1987 they were not irrelevant, they were disastrous. To illustrate that you use a log chart. Here is the same chart using a log scale. Suddenly the 1929 Crash and the 1987 Crash are in perspective to how devasting it was. And suddenly the Coronavirus Correction is in perspective.

Sorry, but the Coronavirus Correction is hardly historic. Not yet anyway.

ANATOMY OF THE FALL

I wrote an article at the beginning of last week called the Anatomy of the Bounce which included a look at the stocks that had fallen the most and were (presumably) likely to bounce the most on a relief rally.

At the time the ASX 200 had dropped 13.23% from top to bottom and was clearly about to bounce. It bounced 4.47% from the low that day to the top the next day. Since then it has fallen another 15.10% to yesterdays low.

As of Trumps speech yesterday the markets have bounced for the second time in this correction. He has belittled the coronavirus saying 25,000 to 70,000 people die in the US from influenza every year and the countrys infrastructure doesnt have to grind to a halt because of it, so why now for a few hundred cases. His speech started to turn things glass half full. When he started speaking our market rallied 7.23% from the low yesterday to the high yesterday.

With a little bit of optimism we start focusing on the better news. Things start to look more glass half full for the first time in three weeks. The cases in China have (apparently) peaked and fallen, Xi is brave enough to visit Wuhan, and the publication of the mortality rates so far suggest the problem is minor for those without pre-existing medical conditions that are under 70.

And the US market rallied 5.5% from its low the day before to the close last night.

Here is the anatomy of the fall using daily candles on the ASX 200:

PERSONAL OPINION

Personal opinion (guesswork) is that we have a typical Trump inspired moment of groundless confidence, another moment of hollow market manipulation. And thats the depth of this bounce. Its hollow, its short term and its not fundamental.

Looking at the real news we have the Qantas impact, the oil war, Italy closed (a whole country closed). And we have a host of downgrades in the pipeline. Theyre coming. BHP have told us they are coming.

BHP said in its recent results statement For 12 months ahead, we assess directional risks to prices across our portfolio are mixed, with the coronavirus outbreak a major source of uncertainty If this viral outbreak is not demonstrably well contained within the March quarter, we expect to revise expectations for economic and commodity demand growth downwards. BHP is warning us that it is cum a profit warning if coronavirus doesnt disappear by the end of this Q (it hasnt). And if BHP is on alert you can imagine the earnings issues for other companies that are more directly exposed.

There are hundreds of companies globally that are yet to publish specific COVID-19 affected earnings guidance, and in Australia we can expect a rash of earnings downgrades as companies get to the end of March and confess to the impact. Downgrades are in the pipeline not just in the travel, tourism, education and cyclical sectors, but in the US, Europe and the rest of the world. Apple, German car manufacturers, its significant and unquantified, the extent of the profit cost is yet to be exposed.

Meanwhile, in Australia, since the results season all the research is brand new and up to date for the February results but is coronavirus unaffected. Its out of date already. At the moment, out of 417 stocks covered by broker research in Australia 286 are trading more than 10% below the average broker target price (over 10% 'cheap'). 94 are trading more than 30% below the average broker target price. Broker research generally does tend to be optimistic but this is out of whack - the research is behind reality and the earnings numbers and target prices need updating.

In which case this Trump bounce appears to be an injection of hollow confidence rather than the representation of a factual improvement in the coronavirus outlook. A real negative economic impact in the first Q is now in the bag, inevitable, the RBA and FOMC rate cuts make that clear, and the debate is not about blind confidence its about how long and deep the economic damage ends up being beyond Q1. And thats still an unknown. In which case any market buying today is speculative at best.

The Marcus Today Team (we run around $40 million of client funds) discussed selling into it this morning (we already have 56% cash and are definitely not buying yet) but decided wed see if it could develop some momentum first, we are due a more material reversal than the last one.

ANATOMY OF THE FALL

Here is a table showing the performance of the ALL ORDS and ASX 200 compared to other international markets in this correction. They are listed in order of worst falls first. The three right hand columns show:

Australian sectors are in grey.

Observations:

STOCKS TO BUY FOR A BOUNCE

(if you are so inclined we arent yet)

For those that want to buy something here is an update of the WHAT TO BUY IF YOU WANT TO BUY lists.

It highlights the stocks that have fallen the most and (mindlessly) suggests that these are the stocks that will bounce the most when market sentiment improves which is did yesterday.

Again I have broken this down into the TOP 50, the NEXT 50 and the WORST OF THE REST. Again the three right hand columns show:

The stocks are listed in order of worst performers since the recent highs first.

TOP 50

Observations Stocks to buy for a bounce:

THE NEXT 50

Observations Stocks to buy for a bounce:

WORST OF THE REST

Observations Stocks to buy for a bounce:

Marcus Padley is the author of the Marcus Today stock market newsletter. To sign up for a 14-day free trial please click here.

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Anatomy of the fall (an update) - Marcus Padley - Livewire Markets

The anatomy of the new bear market – Livemint

For stock market investors, it is turning bad to worse. The resulting risk-off taking place as the coronavirus epidemic escalates was an unforeseen event just a few months ago. Now with the World Health Organisation declaring it a pandemic, stock markets have entered into bear territory in quick time. In fact, this is one of the quickest collapses of the bull market since the global financial crisis in 2009.

For investors, now the question is how long will this bear run continue.

While the financial crisis was due to a few banks going belly up and the resultant lack of trust in credit markets, the markets took as much as two years to recover. But now the risk to the market is even higher as the potential damage to economies around the world due to the coronavirus still unfurls.

In fact, the outbreak of the coronavirus comes at a time when the Indian economy is growing at its slowest pace in years with the GDP print for the third-quarter coming in at a mere 4.7%.

The market volatility is also heightened by the fact that governments across the world are taking unprecedented measures to stop the virus from spreading. The Indian government just restricted foreigners access to India, sending travel, hotel and airline stocks into tailspin. Besides, shutting down factories and world production to contain the virus adds another blow to the bear market.

This time the bear market may be much different compared to even the 2009 global financial crisis, and some others that hit the Indian markets in the past. Usually, bear markets see a demand squeeze while credit markets do their best to restart the growth engines. But this time, the bear market is more of a supply as well as a demand shock. Besides, experts say, its more of a psychological shock as well.

This is evident from the fact that despite more central banks cutting policy rates, stocks still took a knock into bear territory. The market will be relieved if a cure or a vaccine is found for the coronavirus. Stimulus and other measures will hardly have an impact till we see the infection rate coming down drastically. Hence, this is a bear market more driven by fear than actual economics," said a market expert.

So even as more central banks responded by cutting policy rates, stock markets turned bearish due to a consumption slowdown. For now, much will hinge on when the coronavirus is contained than anything else.

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The anatomy of the new bear market - Livemint