General Biology
Carbohydrates •
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Carbohydrates are molecules formed principally of three types of atoms: carbon, hydrogen hydrogen and oxygen oxygen Most Most carbohy carbohydr drat ates es are are soluble soluble in water
Carbohydrates •
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Carbohydrates are molecules formed principally of three types of atoms: carbon, hydrogen hydrogen and oxygen oxygen Most Most carbohy carbohydr drat ates es are are soluble soluble in water
Simple sugars •
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A single carbohydrate unit is called a monosaccharide or simple sugar or examp e: g ucose, ruc ose
p. 330
Double and Complex Sugars •
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More complex carbohydrates are built by hooking monosaccharides together in groups of two (dissaccharides) or many (polysaccharadides) For example: lactose or milk sugar and sucrose or table sugar are double sugars (dissaccharides); starch, cellulose and glycogen are complex sugars (polysaccharides)
p. 330
Digestion of the Carbohydrates •
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In the gut, all carbohydrates are digested into simple sugars such as glucose or fructose , their further processing is essentially the same regardless of which carbohydrate was initially present or which simple sugar was absorbed
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Complex sugars are digested longer than simple sugars For example, starches generally take a few hours to be digested into absorbable sugars, while simple sugars are capable of being absorbed within minutes
Carbohydrates as a source of energy •
In terms of caloric content, all carbohydrates, both sugars and starches, kilocalories per gram (kcal/g)
Common Sources of Carbohydrates •
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Plants store energy as carbohydrates, so they are a good dietary source of them , , , products, most vegetables, table sugar, etc.
Lipids •
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Lipids are molecules formed principally of two types of atoms: carbon and hydrogen, organized into nonpolar hydrocarbon chains Lipids do not dissolve in water
Lipids •
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Dietary lipids are mostly triglycerides Triglycerides are molecules in which glycerol long chains of carbons and hydrogens called fatty acids
p. 332
Lipids •
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Triglycerides that are solid at room temperature are commonly called fats (bacon fat, butter, etc.) Triglycerides that are liquid at room temperature are commonly called oils (olive oil, corn oil, etc.)
Digestion of fats (oils) •
In the gut, all fats (oils) are digested into glycerol and fatty acids
p. 332
Proteins •
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In humans, all proteins are synthesized from 20 standard amino acids Eight of the 20 amino acids cannot be synthesized by the human body and are diet;
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The human body can make the remaining amino acids from these essential amino acids
Proteins •
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Our body needs proteins in many ways: for muscles, blood, skin, bones, hair, tissue growth and repair, cell membranes, enzymes, etc. Dietary proteins include both animal and plant sources
Proteins as a source of energy •
In terms of caloric content, proteins provide 4 kilocalories per gram (kcal/g)
Conversion of macronutrients into cellular energy •
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Proteins
amino acids
Krebs Cycle
Carbohydrates simple sugars Gl col sis Krebs C cle Fats glycerol and fatty acids Cycle Krebs Cycle
Lipolysis
Glycolysis/Lypolysis- within cell, in citoplasmic fluid Krebs Cycle- within cell, inside mitochondria
ATP (adenosine triphosphate) •
Energy-rich molecule
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The principle molecule in which chemical
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It is made during Glycolysis, Krebs Cycle and other cycles
p. 339
Micronutrients: Vitamins •
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Vitamins are complex nutrients that the body needs but cannot make Vitamins are needed in very small quantities Most vitamins are coenzymes, the nonprotein portions of enzymes needed for the enzymes to function as catalysts
Vitamins •
Water-soluble vitamins
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Fat-soluble vitamins
Water-soluble Vitamins • • •
B-group (B1, B2, B3, B6, B12) Folic acid Pantothenic acid
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Vitamin C (ascorbic acid) Water-soluble vitamins do not accumulate in the body. When you eat more than you need, the excess is simply excreted in the urine
Fat-soluble Vitamins •
Vitamin A
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Vitamin D
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Vitamin E
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Vitamin K Fat-soluble vitamins accumulate in the body’s fat tissues and can build up over time
Micronutrients: Minerals •
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Minerals are inorganic (noncarbon containing) ions and atoms necessary for proper physiological functioning Sodium (Na+), Potassium (K+), chloride (Cl-) are principle electrolytes of the body
Micronutrients: Minerals •
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Other minerals important for human health are calcium, phosphorus, magnesium, iron, iodine, fluorine, zinc, copper, and selenium ee e y t e o y on y n very sma quantities
Genes, Chromosomes, and DNA
What is our genetic material? •
DNA = deoxyribonucleic acid
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DNA is made of nucleotides
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Nucleotide consists of:
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- , Guanine- G, Cytosine- C, Thymine- T
- phosphate group - Deoxyribose (simple sugar)
Phosphate group Deoxyribose (sugar) Nitrogenous base
DNA structure can be summarized in the following principles:
1. Nucleotide is a major unit of DNA
2. The phosphate group of one nucleotide is connected to the deoxyribose sugar of the next nucleotide. The alternation of phosphates and sugar units thus forms a backbone that holds the entire strand together, while the nitrogenous bases point inward
3. Each strand is a linear sequence of bases (it does not branch) that is twisted in the shape of a corkscrew (a helix)
4. DNA has two strands wound around each other, forming a double helix, with the bases arranged in the interior, like steps in a spiral staircase
5. The strands run in opposite directions and are so arranged arranged that an adenine on one strand strand is alwa always ys pair paired ed with with a thymine thymine on the other strand, strand, and vice versa. Also, cytosine on one strand is always paired with with guanine guanine on the othe otherr str strand, and and vice vice versa. versa. Such pairing is called complementary A-T G-C
6. Each DNA strand contains all the information information necessary to determine the struct structur ure e of the complem complemen enttary DNA strand
DNA replication -
DNA replication is a process by which DNA molecules make copies of themselves
(1) Unwinding (2) Pairing (3) Joining
P. 60
DNA specifies making of protein - Gene - does not build protein directly - Gives instructions in the form of RNA - Genes are portions of a DNA strand that contain the necessary information to make different proteins
p. 62
Transcription- genetic info. transfer from DNA to mRNA •
During transcription, a portion of DNA is used as a template to make a singlestranded mRNA (messenger RNA)
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DNA, nitrogen-containing bases: A, G, C, T
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RNA- nitrogen-containing bases: A, G, C, U
Translation- info. transfer from mRNA to protein •
Transcription to mRNA is followed by translation, during which the mRNA sequence of nitrogenous bases is translated into sequence of amino acids that can be combined in different orders to make polypeptide chains (proteins)
- Translation uses groups of three successive nitrogenous bases on the mRNA (A, G, C, U) as coding units, or codons. Each codon corresponds to one amino acid
- Each mRNA codon pairs with a complementary three-base sequence called an anticodon which is part of tRNA (transfer RNA)
- Transcription and translation together are called gene expression
Mutations (mistakes) - DNA sequences sometimes undergo sudden but permanent heritable changes known as mutations - Often, during DNA replication - Most immediately fixed by self-correcting - Somatic (body) cells - Gametes
Point Mutations - Single – base mutation - Change mRNA codon May: - Result – wrong a.a. inserted into protein - Alter protein shape, impair protein function - Consequences range from undetectable to fatal
Frameshift Mutations - 1 or 2 extra nitrogenous bases inserted into or deleted - Reading frame is shifted - a.a. added are different - Most result in nonfunctional proteins
- CAT-ATE-BAT-AND-HAT (no mutation) - CAT-BTE-BAT-AND-HAT (point-mutation) -
mutation)
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e et on- rame-s
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- CAT-GAT-EBA-TAN-DHA-T (insertion- frameshift mutation)
Body made up of cells - Cells contain a central portion called the nucleus and a surrounding portion called the cytoplasm - Most cells in body are somatic cells - Eggs and sperm cells are called gametes
DNA is packed in chromosomes - Rod-shape body - Usually paired (two identical copies) - Haploid set of chromosomes (gametes) - Diploid set of chromosomes somatic cells
Mitosis or how does a body grow? - Produces more somatic cells- mitosis - 5 stages of mitosis - Result of mitosis: 2 identical daughter cells with a diploid set of chromosomes
Meiosis or how does a body sexually reproduce?
- Gametes – haploid – 1 chromosome from each pair - Gametes produced by meiosis from spec a ze ce s - Result of meiosis- 4 haploid cells (gametes)
- In all species that reproduce sexually, two haploid gametes (produced by meiosis) join to form a diploid cell called a zygote - After the gametes fuse to form a zygote, undergoes repeated mitosis to become an adult
Karyotype- chromosomal makeup of an individual
- Nearly every person- karyotype of 46 chromosomes arranged in 23 pairs
Autosomal chromosomes- 22/23 - Same in both sexes - Homologous- the 2 chromosomes in each pair carry same set of genes (although may . Sex chromosome- the 23rd pair - Different in males & females - Role in determining sex
Sex determination in humans - Females- typically 2 similar sex chromosomes- XX - Males- typically have 1X and 1Y chromosome - However, translocation of part of sex chromosome can occur
- The International Olympic Committee now uses the presence or absence of the functional sry gene to decide the sex of Olympic athletes
Disorders based on chromosomal variation
Most result from abnormal cell division Klinefelter’s syndrom – XXY - Ma e p enotype, ut steri e
Turner’s syndrom – XO – only 1 X chromosome - Female phenotype, but infertile
Dow Down’s n’s syn syndr drom om – triso risom my 21 21 – 3 (no (nott 2) 2) copies of chromosome 21 - facia aciall cha charract acteris eristtics ics - Heart ab abnormalities -
Mendel’s law of segregation - Durin During g mei meios osis is each each gamet amete rec recei eive vess only only one allele of each gene
Albinism - Albi Albinis nism m is is a tot total al lack lack of mel melan anin in pigme pigment nt in the skin, eyes and hair - One One of of the the funct functio ions ns of mela melanin nin is to bloc block k
- Forms of gene: alleles - Alleles: dominant or recessive - Genotype: homozygous or heterozygous - Allele A (dominant)- melanin present - Allele a (recessive)- melanin absent
AA (genotype)- melanin present (phenotype) Aa (genotype)- melanin present (phenotype) -
p. 80
Pedigree analysis
In pedigree analysis, by knowing phenotypes we can determine genotypes
Sex-linked traits - Genes that are on the X chromosome and not on the Y chromosome, such as the gene for red-green colorblindness, are said - Genes that are on the Y chromosome: Ylinked (much less common)
p. 75
- A blood spot was found at the scene of a murder. The District Attorney believes the blood sample is not from the victim, but from the attacker. Police arrested two suspects but both of them deny their fault. How could we solve this case? - Compare DNA!
Forensic DNA technology - Each person has a unique DNA sequence - Instead of sequencing the whole genome of an individual, it is more practical to use DNA markers with the help of restriction enzymes
- Restriction enzymes cut DNA at specific sites - Each restriction enzyme has a unique DNA recognition site (genetic marker)
p. 95
- Two different people at identical region on a chromosome will occasionally differ in a single base pair, for example, CCGG at a site in one person’s DNA ma be CAGG at the same site in another person’s DNA
- Since a specific restriction enzyme recognizes CCGG but not CAGG, the enzyme will cut DNA from the two people at different sized fragments of DNA restriction fragment length polymorphisms, or RFLPs
p. 93
- Gel electrophoresis banding patterns - DNA fingerprints
- Then, the probability is calculated that indicates how likely it is that a randomly chosen person, other than the one tested, could have the same band pattern
Genetic engineering
Three major tools in genetic engineering:
Three major tools in genetic engineering: 1. Enzymatic scissors- restriction enzyme, a protein that can cut DNA at specific place
Three major tools in genetic engineering: 1. Enzymatic scissors- restriction enzyme, a protein that can cut DNA at specific place 2. Molecular glue- DNA ligase, a protein that can join DNA strands together to create a new, artificially recombined DNA molecule
Three major tools in genetic engineering: 1. Enzymatic scissors- restriction enzyme, a protein that can cut DNA at specific place 2. Molecular glue- DNA ligase, a protein that can join DNA strands together to create a new, artificially recombined DNA molecule 3. Molecular vehicle- plasmid, virus, etc. that can transfer DNA from one organism to another
Application of Genetic Engineering 1. Mass-producing proteins - We can use microorganisms to manufacture virtually any protein we want desired protein - Cheap and fast! - For example, growth hormone, insulin hormone, etc.
p. 98
At present, cancer is the second leading cause of death in most industrialized countries, second only to heart disease
At present, cancer is the second leading cause of death in most industrialized countries, second only to heart disease Cancers of all types result from the : of control
The Cell Cycle and Cancer When cells grow, they soon reach the size at which their ratio of surface area to volume makes them inefficient
The Cell Cycle When cells grow, they soon reach the size at which their ratio of surface area to volume makes them inefficient Instead of becoming increasingly inefficient, the cells divide
The Cell Cycle When cells grow, they soon reach the size at which their ratio of surface area to volume makes them inefficient Instead of becoming increasingly inefficient, the cells divide However, a cell spends most of its time in a resting stage, or Go, between cell divisions
p. 364
Cell Division When an individual animal or plant is developing, the rate of increase in the number of cells can be very rapid and cells s end little or no time in Go
Cell Division When an individual animal or plant is developing, the rate of increase in the number of cells can be very rapid and cells s end little or no time in Go In adult organisms, cells do not divide unless a previous cell has died or been damaged, opening space for a new cell
- Differentiated cell contains all the genes needed for the development of a complete organism new individual having the complete genome of another individual
Regulation of Cell Division - Contact inhibition (with neighboring cells)
Regulation of Cell Division - Contact inhibition (with neighboring cells)
- Anchorage dependence: cells divide only when they are attached to a surface
Regulation of Cell Division Normal differentiated cells have a limit to the number of times that they can divide
Regulation of Cell Division Normal differentiated cells have a limit to the number of times that they can divide The maximum number of times that a cell can divide is called the doubling number, or the Hayflick limit
Regulation of Cell Division Normal differentiated cells have a limit to the number of times that they can divide The maximum number of times that a cell can divide is called the doubling number, or the Hayflick limit After a certain number of divisions the cells die rather than divide
Average life spans of human differentiated cell types
Intestinal lining- 1.3 days Stomach lining- 2.9 days E idermis: cheek- 10 da s Lung bronchus- 167 days Liver- 450 days Brain nerve- 27,375 + days (75 + years)
Who keeps track of the number of cell divisions?
Telomere- the end portion of each chromosome thought to function to maintaining the the integrity of c romosomes
Who keeps track of the number of cell divisions?
Telomere- the end portion of each chromosome thought to function to maintaining the the integrity of c romosomes Each time a cell divides, a few dozen base pairs are lost from the telomere
Who keeps track of the number of cell divisions?
Telomere- the end portion of each chromosome thought to function to maintaining the the integrity of Each time a cell divides, a few dozen base pairs are lost from the telomere When the telomere has shortened to a certain length, the cell can no longer divide
p. 376
The 30 trillion cells of the normal , healthy body live in a complex, interdependent condominium, regulating one another’s proliferation
The 30 trillion cells of the normal , healthy body live in a complex, interdependent condominium, regulating one another’s proliferation
instructed to do so by other cells in their vicinity
The 30 trillion cells of the normal , healthy body live in a complex, interdependent condominium, regulating one another’s proliferation
to do so by other cells in their vicinity This ensures that each tissue maintains a size and architecture appropriate to the body needs
How Cancer Arises
How Cancer Arises
In cancer cells, control of cell division has been lost
How Cancer Arises
In cancer cells, control of cell division has been lost The process that a cell undergoes in unregulated is called transformation
How Cancer Arises
In cancer cells, control of cell division has been lost The process that a cell undergoes in changing transformation The transformed state is caused by changes in DNA and is therefore passed on to all progeny cells
Properties of Cancer Cells
- cancer cells (c.c.) do not have Hayflick limit and continue to divide indefinitely
Properties of Cancer Cells
- cancer cells (c.c.) do not have Hayflick limit and continue to divide indefinitely - c. c. are not inhibited by contact with
Properties of Cancer Cells
- cancer cells (c.c.) do not have Hayflick limit and continue to divide indefinitely - c. c. are not inhibited by contact with other
- c. c. grow without the need to be attached
Properties of Cancer Cells
- c. c. grow this way inside organisms, and the growing piles of cells are called tumors
Genetic basis of Cell Transformation
Two gene classes play major roles in triggering cancer: - When mutated, proto-oncogenes can excessive cell multiplication - Tumor supressor genes, in contrast, contribute to cancer when they are inactivated by mutations
Genetic basis of Cells Transformation
The transformation of cells may require a combination of changes in several protooncogenes and tumor supressor genes rather than a change in just one It is estimated that five or six such mutations must occur in a single cell before it becomes transformed to a cancer cell
How Cancer Spreads
Metastasis, the spread of cancer to distant sites in the body, this is what makes cancer so lethal , to detach from their original location, invade a blood vessel, travel in the circulation to a distant site and establish a new cellular colony
- Melanoma often spreads to lungs - Colorectal cancer often spreads to liver - ros a e cancer o en spreads to bones
Genetic basis of Cells Transformation
- Mutations in somatic cells - Mutations in reproductive cells Is the cancer inheritable?
Twelve Major Cancers - Skin (melanoma) - Breast - Kidney - Ovary - Uterus - Lymph glands
- Lung - Pancreas - Bladder - Prostate - Bone marrow (leukemia)
Why Cancer Appears Early?
It normally takes decades for potential tumor cells to collect all the mutations required for cancer development , , tumor development is clearly compressed; they contract cancer decades before the typical age of onset of these cancers
Why Cancer Appears Early?
How can tumor/cancer formation be accelerated?
Why Cancer Appears Early?
How can tumor/cancer formation be accelerated? - inheritance of “bad” (mutated genes that
Why Cancer Appears Early?
How can tumor/cancer formation be accelerated? - inheritance of “bad” (mutated genes that – responsible for the development of fewer than 5 percent of fatal cancer cases
Why Cancer Appears Early?
How can tumor/cancer formation be accelerated? - inheritance of more general physiological For example, fair skin or inefficient by the body elimination of certain carcinogens
Why Cancer Appears Early?
Science have shown that in most cases the environment (including lifestyle factors) plays a major role in causing the cancer
Causes of Cancer
The major tool: epidemiology Epidemiology- identify factors that are common in cancer victims’ history and way current biological understanding Observed patterns indicate possible risk factors that can suggest hypotheses that can be further tested in other ways
Summary of various causes of cancer Cause
Relative % of cancer death
Smoking
30%
Diet
30%
Salt
1%
Sedentary lifestyle Radiation Genetic susceptibility
3% 2% (but…) <10%
Cancer Treatment
Most of the present-day treatments of cancer use one or more of three types of treatments: surgery surgery,, radiation, and chemotherapy
Viruses, HIV and AIDS
AIDS: Acquired ImmunoDeficiency Syndrom
Aquired- means that the ilness is not genetically inherited ImmunoDeficiency- means that some part of e mmune sys em s no unc ona Syndrom- means that a wide range of symptoms are associated with the disease
People who are immunodeficient get sick more more often often than than people people with with health healthy y immune systems, systems, and their illnesses last longe longerr and ar are more more seve severre
AIDS is long lasting; the immune system system does not recover, recover, and the disease is fatal fatal What would be a minor infection infection in a person with a healthy immune system can quickly becom become e lif life-th e-thrreat eatenin enin in a erso erson n with with AIDS
AIDS Target AIDS damages the lymphocytes lymphocytes called helper (CD4) T cells These cells and the interleukin-2 that they lymphocyte and cytotoxic (CD8) T cell responses of the immune system
p. 538
HIV: Human Immunodeficiency Virus At present, the majority of scientists agree that HIV is a necessary cause of AIDS; that is, someone who is not infected with HIV will not get AIDS
HIV: Human Immunodeficiency Virus However, not all scientists agree that HIV is the sole or sufficient cause of AIDS (that is, no other factors are required)
Viruses Viruses are bits of either DNA or RNA that cannot reproduce by themselves but can replicate inside a cell (called the host cell) by using the biochemical machinery of the host
Viruses Biologists define a living organism as one that can reproduce itself, which viruses cannot; yet once inside a host, viruses can cause the host to replicate the virus
Viruses For each virus there are only certain species that can serve as its host, and within an individual of the host species only certain types of cells can be host cells
The structure of HIV p. 546
HIV HIV is a virus whose genome consists of two copies of a single strand of RNA
p. 547
HIV The final stage of the viral life cycle consists of the release of viruses from the cell by the rupturing (also called lysis) of the cell or by the budding out viruses through the host cell membrane
At present, as many as 1 million may be HIV infected and 300,000 are currently living with AIDS in the United States
Progression from HIV Infection to AIDS The progression from HIV infection to AIDS follows three stages: - first, the initial infection - second, an asymptomatic phase - third, disease progression
First Stage: Initial Infection - HIV level in the blood high - helper T-cell count begins to drop - fever, swollen lymph nodes, fatigue - an increase in HIV-specific antibodies and cytotoxic T cells
Second Stage: Carrier - viruses in blood decrease - helper T-cell count returns to normal - the immune system keeps the infection un er contro t e person oes not ee but it does not eliminate the virus - may last from a few months to many years (with 10 years being typical)
Third Stage: AIDS - viruses in blood increase - helper T cells decrease - opportunistic infections occur
A person is defined as having progressed to AIDS when his helper T-cell count (also called the T4 count) falls from a normal value of 1000 cells per microliter of blood to less than 200
Does everyone infected with HIV get AIDS? A long-term study of HIV-infected men in San Francisco showed that, after 12 years, 65% had progressed to AIDS, but 35% had not
Diagnostic Tests For every diagnostic test there exist two possibilities: - false positives - a se negat ves
Diagnostic Tests False positives is when the test results are positive when the person does not really have the condition Specificity- the frequency of false positives
Diagnostic Tests False negatives is when the test results are negative when the person really does have the condition Sensitivity- the frequency of false negatives
The reliability of a given test depends on both its sensitivity and its specificity. The more sensitive a test, the less often it will miss a truly positive case The more specific a test, the fewer will be the cases that are truly negative but that are reported as positive
Tests for HIV Infection Two the most common tests for HIV: - ELISA - Western blot test Both of these tests detect antibodies to HIV HIV-positive person- is a person that contains HIV-specific antibodies in his blood
Tests for HIV Infection For HIV testing, the ELISA test is done first: - sensitivity high (less than 1% false negatives) -
eaper
- Not very specific (there can be as many as 2 to 3% false positives)
Tests for HIV Infection If ELISA result is positive, the result is rechecked with a Western blot which rarely gives false positives - technically more difficult
Tests for HIV Infection A second generation of tests are based on the polymerase chain reaction (PCR) - detect HIV directly (viral RNA) - can give results soon after infection
PCR = amplification of DNA or RNA
p. 101
Worldwide HIV/AIDS incidence
How is HIV transmitted from one person to another?
HIV can pass from one person to another only in certain fluids: blood, semen, and vaginal fluids