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So, you’re looking to shed a pound or two. Time to cut back on those pesky calories, right?
Not so fast. According to Michelle Adams-Arent, a sports nutrition consultant and the Director of Science and Education for Metabolic Precision, reducing your food intake might not work like you originally thought. In fact, it might actually backfire.
'Your body is built for survival,' Adams-Arent told Business Insider. 'It doesn’t care what you want to look like.'
The minute you start cutting back on your caloric consumption, your body goes into full-on starvation mode. Translation? Your metabolic rate will actually decrease as your body tries to preserve what little nutrition it has. A lower metabolism means fewer calories burned. What’s more, research even shows burning more calories than you consume over a long period of time can increase your body fat. Not exactly the outcome you were hoping for.
HIV stands for human immunodeficiency virus, which is the virus that causes HIV infection. The abbreviation “HIV” can refer to the virus or to HIV infection.
AIDS stands for acquired immunodeficiency syndrome. AIDS is the most advanced stage of HIV infection.
HIV attacks and destroys the infection-fighting CD4 cells of the immune system. The loss of CD4 cells makes it difficult for the body to fight infections and certain cancers. Without treatment, HIV can gradually destroy the immune system and advance to AIDS.
How is HIV spread?
HIV is spread through contact with certain body fluids from a person with HIV. These body fluids include:
Blood
Semen
Pre-seminal fluid
Vaginal fluids
Rectal fluids
Breast milk
The spread of HIV from person to person is called HIV transmission. The spread of HIV from a woman with HIV to her child during pregnancy, childbirth, or breastfeeding is called mother-to-child transmission of HIV.
In the United States, HIV is spread mainly by having sex with or sharing drug injection equipment with someone who has HIV. To reduce your risk of HIV infection, use condoms correctly and consistently during sex, limit your number of sexual partners, and never share drug injection equipment.
Mother-to-child transmission is the most common way that children become infected with HIV. HIV medicines, given to women with HIV during pregnancy and childbirth and to their babies after birth, reduce the risk of mother-to-child transmission of HIV.
You can’t get HIV by shaking hands or hugging a person who has HIV. You also can’t get HIV from contact with objects such as dishes, toilet seats, or doorknobs used by a person with HIV. HIV does not spread through the air or through mosquito, tick, or other insect bites.
The HIV Life Cycle
HIV attacks and destroys the CD4 cells of the immune system. CD4 cells are a type of white blood cell that play a major role in protecting the body from infection. HIV uses the machinery of the CD4 cells to multiply (make copies of itself) and spread throughout the body. This process, which is carried out in seven steps or stages, is called the HIV life cycle.
What is the connection between the HIV life cycle and HIV medicines?
Antiretroviral therapy (ART) is the use of HIV medicines to treat HIV infection. HIV medicines protect the immune system by blocking HIV at different stages of the HIV life cycle.
HIV medicines are grouped into different drug classes according to how they fight HIV. Each class of drugs is designed to target a specific step in the HIV life cycle.
ART combines HIV medicines from at least two different HIV drug classes, making it very effective at preventing HIV from multiplying. Having less HIV in the body protects the immune system and prevents HIV from advancing to AIDS. ART also reduces the risk of HIV drug resistance.
ART can’t cure HIV, but HIV medicines help people with HIV live longer, healthier lives. HIV medicines also reduce the risk of HIV transmission (the spread of HIV to others).
What are the seven stages of the HIV life cycle?
The seven stages of the HIV life cycle are: 1) binding, 2) fusion, 3) reverse transcription, 4) integration, 5) replication, 6) assembly, and 7) budding. To understand each stage in the HIV life cycle, it helps to first imagine what HIV looks like.
Now follow each stage in the HIV life cycle, as HIV attacks a CD4 cell and uses the machinery of the cell to multiply.
This video explains how HIV targets human immune cells, and uses immune cell machinery to make copies of itself. By comparing an analogy to the life cycle of HIV, this presentation will help you understand how HIV systematically reduces immunity within the body.
A new study has investigated how mothers and fathers cause new genetic mutations in their children, and how some of these mutations may lead to negative outcomes.
Characteristics that we inherit from our parents - starting with very basic features such as eye color or hair texture - shape not just our identity, but also the state of our health, both earlier and later in life.
That being the case, the study of genetics has become central to understanding who and what we are, as well as how our bodies are likely to develop in time, and how we might respond to internal or external factors.
For instance, recent studies have revealed the importance of genetic factors to conditions including Alzheimer's disease, brain cancer, and diabetes.
Given the importance of understanding the role of genetic factors to our health profile, scientists are constantly striving to decipher the mysteries of the human genome.
Researchers are looking at how the parents' age and sex determine new genetic mutations in the offspring.
Middle-aged women can choose which test to undergo for cervical cancer screening, according to a draft recommendation from an influential group backed by the U.S. government.
Women ages 30 to 65 can choose to receive a Pap test every three years or a human papillomavirus (HPV) test every five years, according to the U.S. Preventive Services Task Force (USPSTF). The group did not previously recommend HPV testing without a Pap test.
"Women and providers should continue to recognize that cervical cancer is a serious disease that can be prevented," said Dr. Maureen Phipps, a member of the USPTF.
"Women who can be identified early through screening can have effective treatment for cervical cancer and go on to lead robust lives," said Phipps, who is also chair of obstetrics and gynecology at the Warren Alpert Medical School of Brown University in Providence, Rhode Island.
Cervical cancer was once a leading cause of cancer death for women in the U.S., but the death rate has been cut in half thanks mostly to screening, according to the American Cancer Society (ACS).
A tumor marker is a biomarker found in blood, urine, or body tissues that can be elevated by the presence of one or more types of cancer. The vast majority of tumor marker tests in primary and secondary care may not be necessary as the tests assisted with a cancer diagnosis in just 2% of patients.
Tumor markers are molecules, which may be present in higher than usual concentrations in the tissue, serum or other body fluids of patients with cancer. There are many different tumor markers, each indicative of a particular disease process, and they are used in oncology to help detect the presence of cancer. A tumor marker can be used to aid diagnosis in specific situations but testing for more than one marker is not recommended.
Scientists at South West Wales Cancer Centre (Cardiff, UK) examined the number of multiple tumor marker requests from primary and secondary care over a six-month period within Abertawe Bro Morgannwg University Health Board (Bagain, Neath Port Talbot, Wales). Multiple requests were defined as more than one tumors marker for a patient in a two-week period. The team looked at how many patients with multiple tumor markers measured were subsequently diagnosed with cancer, and whether the markers assisted with the diagnosis.
Common tumor markers used in the diagnosis of cancer
Diabetes, or diabetes mellitus (DM), is a metabolic disorder in which the body cannot properly store and use sugar.
It affects the body's ability to use glucose, a type of sugar found in the blood, as fuel. This happens because the body does not produce enough insulin, or the cells do not correctly respond to insulin to use glucose as energy.
Insulin is a type of hormone produced by the pancreas to regulate how blood sugar becomes energy. An imbalance of insulin or resistance to insulin causes diabetes.
Diabetes is linked to a higher risk of cardiovascular disease, kidney disease, vision loss, neurological conditions, and damage to blood vessels and organs.
There is type 1, type 2, and gestational diabetes. They have different causes and risk factors, and different lines of treatment.
This article will compare the similarities and differences of types 1 and 2 diabetes.
People with type 1 diabetes will require supplemental insulin on an
ongoing basis. People with type 2 will likely only need this for the later
stages of the condition. A healthcare specialist will be able to test
a patient for diabetes, even if type 2 diabetes shows no symptoms.
According to a comprehensive new report from the Food and Agriculture Organization of the United Nations, one in 10 of the world's 7.5 billion inhabitants is obese. At the same time, rates of people who are starving or malnourished is on the rise.
According to Business Insider, nutritionists and public health experts say both issues can be traced to our diet.
Today, food that is more highly processed and calorie-dense is available worldwide. And it's relatively cheap, too.
National DNA Day is not only a celebration of the structure and sequence of the double-helix, but also the tireless commitment of researchers to understand the complexities of our genetic blueprint. As we revel in all things DNA, the GEN editorial staff has assembled a brief video timeline highlighting significant dates in DNA discovery.
Genetic analysis has come a long way; we now have an ever-expanding collection of analytical tools in the diagnostic laboratory. So why do we still need a technique that usually only looks at one or two loci? The simple answer is that results from fluorescence in-situ hybridization (FISH) can quickly confirm diagnoses, guide clinicians’ judgements regarding differential diagnoses, and correlate results with clinical risk—thus enabling an informed choice of treatment type and intensity.
FISH employs fluorescently-labeled DNA probes to bind complementary DNA sequences within an interphase cell, or onto metaphase chromosomes. These sequences can then be visualized using fluorescent microscopy. The number, location and relative positions of the probe signals indicate chromosomal changes in a particular cell (Figure 1).
Many clinical trials use cytogenetic and FISH data to stratify patients according to specific risk factors. FISH is often used as a stand-alone technique for investigating abnormalities and following-up such patients, which, alongside its relatively low expense, makes it a very convenient investigative tool.
In this article we will explore the utility of FISH in today’s clinical laboratory and the future of the technique in the evolution of molecular testing.
Figure 1. The FISH process.
Figure 2. Interphase cell showing amplified HER2 signal pattern.
Mosquito-borne Zika virus (ZIKV) was the cause of the recent large outbreak of Zika disease in America. Despite fever, Zika is a mild disease, although epidemics in recent years have demonstrated an association with the appearance of severe congenital malformations (microcephaly). Owing to ZIKV serology cross-reactivity with other tropical flaviviruses, the final diagnosis relies on nucleic acid amplification. Pregnant women in endemic areas should be investigated to follow infection and sequelae.
Background
Zika virus (ZIKV) belongs to the Flavivirus genus and is related to other viruses that are also transmitted by the bite of mosquitoes, such as dengue virus (DENV), yellow fever virus (YFV) and West Nile virus (WNV). The Flaviviridae family comprises single-strand RNA, membrane-enveloped viruses that frequently use Aedes aegypti as a vector. Despite ZIKV being discovered over 60 years ago, only since 2014 (in the French Polynesia Islands) and 2015 (Brazil and America) has it been evident that the virus can cause large outbreaks and epidemics that lead to a global public health emergency.