Dengue

Dengue is a mosquito borne infectious disease caused by the dengue virus which is mainly found in the tropical regions. Dengue fever, also known as breakbone fever, because produces body pains as one feels when his/ her bones break.

About 40% of the world’s population is at risk and there are 50–100 million cases every year. An estimated 500 000 people with severe dengue require hospitalization each year and about 2.5% of those affected die. In India, dengue is widespread and endemic in most major cities.

There are four Dengue viruses (DENV) that cause Dengue fever, all of which are spread by a species of mosquito known as the Aedes aegypti mosquito, and more rarely by the Aedes albopictus mosquito. Aedes aegypti is the main carrier, responsible for approximately two-thirds of the world’s dengue. The virus is transmitted from an infected mosquito to human. The process begins when a person who is infected with the Dengue virus is bitten by a mosquito, the virus is then passed on when someone else is then bitten by the infected mosquito.

The dengue virus is divided into four viral serotypes, DEN1, DEN2, DEN3, and DEN4, which are closely related but differ in their antigens.

The Aedes aegypti species of mosquito breeds in stagnant water and usually bites during daylight hours. The virus circulates in the blood for 27 days after the human is affected, during which the mosquito may acquire the virus by biting the infected human and spread it to another unsuspecting victim.

Symptoms: of dengue includes fever, headache, bone or joint pain, muscular pain, rash, pain behind the eyes, petechial hemorrhagic complications. Low platelets count (<100,000 platelets mm⁻³) leads to hemorrhagic complications such as bleeding from the gums, nosebleeds, and bruising.

Diagonosis: Laboratory confirmation of dengue infection is crucial as the broad spectrum of clinical presentations, ranging from mild febrile illness to several severe syndromes, can make accurate diagnosis difficult.

Methods for dengue diagnosis:

Virus isolation: The detection of the viral genome or viral antigens provides the evidence infection. Sera that have been collected from suspected dengue cases in the first 3–5 days of fever (the viraemic phase) can be used for virus isolation. After an incubation period permitting virus replication, viral identification is performed using dengue-specific monoclonal antibodies in immunofluorescence and PCR assay.

Serological testing: When a dengue infection occurs in individuals who have experienced a previous dengue infection, a secondary immune response occurs, which generates high levels of IgG through the stimulation of memory B cells from the previous infection as well as an IgM response to the current infection. Because high levels of IgG compete with IgM for antigen binding, an IgM capture assay can be used.

Polymerase Chain Reaction (PCR): detects viral genomic sequence from Serum or Cerebro Spinal Fluid (CSF) samples collected from the patient.

Nucleic acid-sequence based amplification assay (NASBA): The NASBA assay is an isothermal RNAspecific amplification assay that has been adapted for dengue virus.

Antigen detection: Dengue antigens can be detected in tissues such as liver, spleen and lymph nodes using an enzyme and a colorimetric substrate with antibodies that target dengue-specific antigens.

Haemagglutinationinhibition test: This test is based on the ability of dengue antigens to agglutinate red blood cells (RBC) of ganders or trypsinized human O RBC. Antidengue antibodies in sera can inhibit this agglutination and the potency of this inhibition is measured in an HI test

Haematological tests: Platelets and haematocrit values are commonly measured during the acute stages of dengue infection. These should be performed carefully using standardized protocols, reagents and equipment.

A drop of the platelet count below 100 000 per μL may be observed in dengue fever. Thrombocytopaenia is usually observed in the period between day 3 and day 8 following the onset of illness.

Increase in hematocrit i.e., the volume percentage of Red Blood Cells (RBS), by 20% should be a caution as it occurs due to rise in the vascular permeability of the plasma.

Treatment:

There are no specific antivirals that can eliminate the virus from an infected individual. However, supportive care and treatment can be effective in treating Dengue fever. Paracetamol and other antipyretics can be used to treat fever. Bone pain should be treated by analgesics or painkilling tablets.

The patient can also be treated with natural home remedies such as papaya leaves, kiwi and other food items that have been proven to help in the increase of platelet count, which gets affected during dengue

During episodes of Dengue hemorrhagic fever/Dengue shock syndrome, the mortality rate in the absence of hospitalization can be as high as 50%. With proper treatment, such as intravenous fluid replacement, the mortality rate is greatly reduced.

Patients should drink plenty of fluids, as dehydration is prevalent among those affected with Dengue. Vaccines for all of the serotypes are being developed, which will be the most effective way to cure the disease.

Prevention of Dengue:

Since the vaccine is under development for treating dengue, the best method of prevention is to avoid being bitten by mosquitoes.

ü  If you live or travel to an area where dengue exists, there a number of ways to avoid being bitten

ü  The Aedes mosquito prefers to breed in clean, stagnant water. It is important to frequently check and remove stagnant water in your home/premises. Water should be stored in closed containers

ü  Bleaching powder may be used in water sources that are not meant for drinking, as it prevents the development of mosquito eggs

ü  The female mosquito feeds on blood as it requires the blood protein to produce eggs, hence it is better to use mosquito repellents, even when indoors

ü  It is advised to reside in a well screened or air conditioned house. If not, mosquito nets may be attached to the windows

ü  Usage of long sleeved shirts, boots, socks and long pants is advised when outdoors

ü  It is healthier to avoid being outdoors during dawn, dusk or early evenings when mosquitoes tend to roam around in the open.

ü  Mosquitoes are attracted to dark colored clothing hence it is better to wear bright and light colored clothes

ü  Avoid strong perfumes, as mosquitoes are drawn towards strong body odor’s.

References:

1.      http://www.medindia.net/patients/patientinfo/dengue.

2.      Cecilia D: Dengue and chikungunya in India. WHO South-East Asia Journal of Public Health ; 2014 |:3 (1) : 22-27.

3.      Maria g. guzman, scott b, halstead. Dengue: a continuing global threat. Nature reviews | microbiology.2010;16-17.

4.      Viroj Wiwanitkit. Dengue fever: diagnosis and treatment .Expert Rev. Anti Infect. Ther. 8(7), 841–845 (2010).

5.      Ted M. Ross. Dengue Virus.Elsevier; 2010: 149-160.Dengue

Vast virus

Battle with bacteria

Fatal fungi

Dread microorganisms

Microbes in our body

Enzymes in our body

Knowing our food

Health benefit of curcumin

How to kill cancer?

Health insurance for all

Health insurance: What it covers and what it does not cover?

Green planet: who cares?

How to wash out pollutant from water

Living with polluted air

Pressing issues of high blood pressure

Dealing with diabetes

Importance of excercise

Immune system

Life minus heart, brain, liver, lungs and liver

Tissue: making cells work together

Tissue is the junction of similar cell having a common origin, structure and function. The study of tissue is known as histology

Human body is made up four different types of tissues, which differ among themselves in composition and function.

The four basic types of tissues are:

·         Epithelium tissue

·         Connective tissue

·         Muscular tissue, and

·         Nervous tissues

Epithelium tissue:

Epithelial tissue covers the outer surface of the some parts of the body, lines internal cavities, and many other glands. The cells are closely arranged with little intercellular spaces and rest on a basement membrane.

There are two types of epithelial tissues namely:

·         Simple epithelium

·         Stratified epithelium

Simple epithelium is composed of single layer of cells and present as lining for body cavities, ducts, and tubes.

On the basis of structure of cells found in simple epithelium, the epithelium is categorized into three types:

Squamous- made up of polygonal and flattened cells with irregular boundaries. Squamous epithelium is also called as pavement epithelium because cells look like tiles on the floor. It is found in walls of blood vessels, alveoli of lungs and kidney and forms a diffusion boundary and regulates the diffusion of material through it.

Cuboidal- made up of cube shaped cells and commonly found in tubular parts of nephrons and ducts of gland and regulates secretion and absorption.

Columnar- made up of elongated/tall and slender cells and found in the lining of stomach and intestine and like cuboidal epithelium is involved secretion and absorption.

If the columnar and cuboidal cells bear cilia on their free surface they are called ciliated epithelium.

These ciliated epithelium is found in inner surface of bronchioles and fallopian tubes, where it is involved in removal of particulate matter or mucus.

Stratified epithelium is made up of more than one layer of cells and provide protection against chemical and mechanical stresses. They are present on dry surface of skin, buccal cavity, pharynx, inner lining of ducts of salivary glands and of pancreatic ducts.

The stratified epithelium is named by the shape of the most apical layer of cells, closest to the free space. For ex; if the cell shape is columnar (elongated/tall and slender cells) then it is called as stratified columnar epithelium and if the cell shape is polygonal/flattened then it is called as stratified squamous epithelium.

Pseudo stratified epithelium: is made up of single layer of cells but appears to be multi-layered due to variance in height and location of the nuclei in the cells.

The pseudo stratified columnar epithelium is found in respiratory tract where some of the cells have cilia.

Connective Tissue:-

Connective tissue is made up of cells (fibroblasts, plasma cells, macrophages, adipose cells and mast cells) which are dispersed in the matrix. The cells are loosely arranged with large amount of intercellular spaces. The matrix consist of extracellular material which is produced by the connective tissue cells. It consists of cells and fibers enclosed in a ground substance. The matrix can be hard or soft or liquid.

The connective tissue provide support and connect the tissues.

Based on the nature of matrix, the connective tissue is classified into three types:

Ø  Loose Connective Tissue

Ø  Dense Connective Tissue

Ø  Fluid  Connective Tissue

Loose Connective tissue:  consists of cells and fibres loosely arranged in a semi-fluid ground substance. It is found between many organs such as the dermis and subcutaneous layers of the skin as well as surrounding muscles where, it absorbs shock and provide protection. It allows diffusion of salt, water and various nutrients to adjacent cells and tissues. The adipose tissue and reticular tissue are include under this group.

Areolar tissue:

It has cells and fibres loosely arranged in a semi-fluid ground substance, present beneath the skin and serve as support frame work for epithelium.

Adipose tissue:

Adipose tissue is found around some organs and joints. It forms a cushion for shock absorption.

Adipose tissue also insulates the body. Adipose tissue consists of cells containing lipid (fat) called adipocytes. The lipid is used to store energy to be used by the body if needed.

Reticular tissue:

It is mesh like and provides supportive frame work for organs such as liver, spleen, and bone marrow.

Dense connective tissue:

It consist cells embedded in hard matrix/dense matrix which is composed of calcium carbonate and calcium phosphate. It forms the skeletal system of the body in all vertebrates.

The two major dense connective tissues are cartilage and bone that allow the body to maintain its posture and protect internal organs.

Fluid connective tissue:

Consist of various specialized cells circulating in a watery fluid containing salts, proteins and nutrients.

Blood and lymph are fluid connective tissues.

Blood contains fluid matrix called plasma, and cell formed elements such as erythrocytes (RBC-red blood cells), Leucocytes (WBC-white blood cells) and platelets.

RBC transport oxygen and some carbon-di-oxide. WBCs are responsible for defending against infections and platelets are involved in blood clotting.

Muscular tissue:

Muscular tissue is made up of elongated cells, these cells are called muscle fibres or myo-fibres.

The muscle fibres are specialized cells capable of contraction and relaxation. This property is responsible for movement of limbs and bending of the body.

Based on structure, function and location, there are three types of muscular tissue:

Ø  Striped muscles

Ø  Unstriped muscles

Ø  Cardiac muscles

Striped muscles/Skeletal muscles:

Striped muscles are made up of elongated, cylindrical, multi-nucleated, unbranched muscle fibres with characteristics striations or cross brands. Hence, they are also known as striated muscles. The striped muscles are usually attached to bones and hence are also known as skeletal muscles. They are voluntary muscles which are responsible for locomotion, facial expression, body posture and other voluntary movements of body.

Unstriped muscles:

Unstriped muscles are made up of spindle shaped, elongated, uninucleated muscle fibres without striations. Hence, they are also known as smooth muscles. Smooth muscle contraction is responsible for involuntary movements of internal organs. They are found in the wall of body cavity and in kidneys, blood vessels and glands.

Cardiac muscles:

Cardiac muscles are made up of elongated, cylindrical and branched muscle fibres. It is involuntary muscle which is found only in heart and are involved in rhythmic contractions and relaxation.

Nervous Tissue:

Neural tissue exerts greatest control over the body’s responsiveness to changing condition. Nervous tissue is involved in sending and receiving electrochemical signals that provide the body with information. It is made up of two classes of cells i.e. neuron and neuralgia.

Neurons are the conducting cell with three main parts.

·         The cell body

·         Dendrities

·         Axon

The cell body contains cell cytoplasm, organelles, and nucleus. Dendrities branch off the cell body which appear like extensions and axon is the tail which extends from the neuron body. Neuralgia act as supporting cell to the neuron, and modulate their information propagation.

References:

1.      Text book of Anatomy and physiology by open stax college, vol 1: pg no-131-155.

2.      Text book of Human Anatomy and Physiology by Dr. Bruce Forciea, pg no-89-103.

Cell: The basis of life

To be written

Raising money for orphan disease

Orphan diseases are the diseases those affect a very less number of people (say 100-5000 person in a country). 

Generally, pharmaceutical companies spend few billion dollars to conduct pre-clinical (using animals) and clinical (using healthy human and patients) research for develop a new medicine. Drug development generally take about 10 years. Before approving any new medicine for marketing, food and drug administration review all experimental data to confirm that medicine is safe and effective in managing/curing a disease. Generally pharmaceutical companies obtain patent (say for 10-20 years) to sale the a new medicine (and other companies can not sell same medicine till patent expires) as per patent agreement) for recovering research cost. 

In case of developing orphan drugs (the medicine used to treat orphan disease) pharmaceutical companies have difficulty to conduct extensive research  that requires lot of money and they may not get back money from few patients those use these medicine. Therefore US government passed orphan drug act in 1983 to relax few stringent criteria set to develop new medicine. Even though this effort decreases financial burden for pharmaceutical companies and few pharmaceutical companies are committed to develop medicine are orphan diseases, these efforts are not enough because the number of orphan diseases are increases every year. 

To void this gap, researchers at academic institutes are conducting research to develop new medicine. As research grants from National Institute of Health (NIH) and National Science Foundation (NSF) declined and became competitive, researchers from academic institutes and small pharma/biotech companies had been looking for alternative source of funding.

BeneFunder,  is an nonprofit organization which is raising money from wealthy Americans to fund for drug development for rare diseases apart from research on environment and computer science.  Founders of this philanthropic research funding platform realized that Americans donate 10 times more than grants issued by NIH for scientific research. Therefore the founders developed this organization to collect donation for research and donation to this organization is exempted from tax. Professor Gert Lanckrit, Ph.D., department of Computer Science and Engineering, University of California, San Diego co-founded BeneFunder. Dr. Lanckrit spoke about his experience at 1st Rare disease conference at University of California, Davis on March 5, 2015. Professor Lanckrit told that they invited financial adviser (from financial institutes like Merrill Lynch)  to visit different research lab working on innovative product. Informed financial adviser than help donors to decide in which research their money should be spent. Few donors also visit research lab to learn about latent technologies available to fight orphan disease and meet patients of orphan diseases to realize how their donations are improving life of patients. BeneFunder has employees who develop easy and attractive tools to teach financial adviser and donors.  

     

Taking care of teeth and gum

Brush two times in a day to keep gum and teeth clean. If teeth is not cleaned properly after eating food, bacteria grow and acid is released that decays teeth. Improperly cleaned teeth support development of tartar that facilitate loosening of gum. This in long run can loosen your teeth and teeth will fall early. Very hard brush can damage enamel while very soft brush can not remove dart from teeth. For many people, brushing can not remove food particles between teeth. In such case dental flush should be used to keep teeth and gum healthy.  Many times unhealthy and inflamed gum is responsible for bad breath.  

Weak teeth is sensitive to cold and hot drinks. Special medicated tooth paste are available to treat such condition, but teeth must be kept clean to get benefit of such medicated products.

Chewing gum can be helpful to keep mouth moist, but persons having deep bite problem must avoid regular use of chewing gum. 

Demerit of mercury filling...


Important website(s).
1. http://www.ada.org/en/science-research/ada-seal-of-acceptance/product-category-information/toothpaste

How animals are useful in drug development?

Before any drug is tested on humans it has to be tested on animals.

As a preliminary study, companies test the effect of new chemicals on animals. After the new chemical passes safety and efficacy standards then companies obtain permission from food and drug administration (FDA) for testing the effect of chemical on interested human subjects.   

FDA (and/ other relevant authorities) scrutinize the data of animal study to analyse the beneficial effect of new chemical on animals. After FDA is satisfied with the data then it permit to test chemicals on humans as per set standards and protocols. 

Suppose a company wants to market a new medicine to treat diabetes. It select a suitable animal model of mice/rat, and induce diabetes by administering streptozotocin and then administer new chemical to test if it decreases blood sugar. Some time isolated animal tissues are also helpful to test the effect of new chemical. When FDA is satisfied with the fact that new chemical decrease blood sugar level and safe to animal, FDA permits to test the effect of new chemicals on healthy and diabetes patients. If the new chemical meets safety and efficacy standard then company gets FDA nod to market it and now the new chemical becomes a medicine.

For science research, animal study protocol need to be approved by ethics committee. Animals are treated humanly and are maintained under standard laboratory conditions (room temperature, suitable humidity,  environment with minimal noise, sufficient food and water). 

References:

1. Mark Mathieu. New Drug Development: A regulatory overview. Parexel Intl Corp. 

2. Goswami SK, Manikanta V, Suma KG, Razdan R, Inmadar MN. Efficacy of Ellagic acid and sildenafil in Diabetes induced sexual dysfunction. Pharmacog Mag 2014; 10(Suppl S3): 581-7. 

3. Goswami SK, Inamdar MN. Screening of new compounds for the management of erectile dysfunction. J Young Pharm 2014; 6(4):51-55.