For Discussion (2-3 paragraphs) • What was the concentration of your pre-diluted NPs? • Determine the effect of NPs on brine shrimp lethality. • Determine the effect of NPs on cell viability. • What is (are) the control(s) in this experiment? What is its purpose? • Based on your data in this lab, what is a safe concentration for brine shrimp Threshold Level of Toxicity (TTL)? • Often indicator species are used to study the overall health of an ecosystem. If you were to study an ecosystem containing brine shrimp, would you use it as an indicator species? Why or Why not? Explain your reasoning. • What possible sources of error were present in this experiment?

Introduction

LD50 is a commonly used term to describe acute toxicity: LD stands for Lethal Dose and 50 is used because the dose could kill 50% of the animals exposed to the chemical. For LD50 tests, the animals are given specific amounts of the chemical, orally, by injection or dermally. The value is then reported along with the method of administration and the type of animal used in the test. LD50 is typically reported in milligrams or grams per kilogram of body weight of the animal. The lower the LD50 is, the higher the toxicity of the chemical would be. This information is always provided in Safety Data Sheet (SDS) of chemicals in the “toxicity data” category. A similar measure, the LC50 is usually used to describe the ecological hazards of chemicals. LC stands for lethal concentration that could kill 50% of the animals after 24-96 hours. This value is always provided in Safety Data Sheet (SDS) of chemicals in the “Ecological Data” category. In this lab, you will be measuring LC50 or LD50 of iron oxide nanoparticles using brine shrimp. Iron oxide nanoparticles are magnetic. Application of magnetic nanoparticles ranges from magnetic storage media to medical industry where they can be used for targeted drug delivery or as contrast agents in MRI. Thus, measuring environmental and biological toxicity of these nanoparticles is crucial. To test toxicity of any such reagents on small organisms, Daphnia and brine shrimps (also known as Artemia) can be used. Artimia are found in salt lakes around the world. They are important live food for aquarium fish. In this lab, you will use brine shrimp to measure toxicity of the nanoparticles. Trypan blue is a stain used to assess cell viability. It is able to diffuse through cell membranes of dead cells but is unable to permeate live cells. This stain can be used to assess cell survival 1 Fall 2017 following exposure to chemicals, nanoparticles and experimental drugs. The ratio of live: dead cells can be used as a preliminary assessment of cytotoxicity and translated to tissue viability.

Methods Part A: Serial Dilution of NP Solution 1) Label 5 test tubes as 0, 1:1, 1:10, 1:100, 1:1000 2) Add 2mL of seawater to tube 0 3) Add 2mL of specific group stock solution to tube 1:1 and add 2mL of seawater to it. 4) Transfer 1mL of stock solution to tube 1:10 and add 9mL of seawater to this tube 5) Transfer 1mL of 1:10 solution to the tube labeled as 1:100 and add 9mL of seawater to 
this tube 6) Transfer 1mL of 1:100 solution to the test tube labeled as 1:1000 and add 9mL of 
seawater to this tube Part B: Preparation of test environments 1) Label 5 wells of 6-well plate as control (0), 1:1, 1:10, 1:100 and 1:1000 2) Label 3 petri dishes as: control (0), 1:1 and 1:1000 
NOTE: Be sure to include your initials on all plates 3) Transfer 2mL of each solution from the corresponding test tube to the respective wells on your six-well plate and each petri dish Part C: Preparing specimens for the Trypan blue cell viability test 1) Transfer 2 brine shrimp into each of the pre-labeled petri dishes containing the solution of NPs and seawater (0, 1:1 & 1:1000) and set a timer for 30 minutes. 2) Transfer a single brine shrimp into the unlabeled petri dish with a drop (~50ul) of seawater and use the dissecting microscope to make observations related to the behavior and morphology of untreated brine shrimp.
Make observations in lab notebook of all samples Part D: Preparation of specimens for the toxicity assay 1) 2) 3) 4) 5) Add 10 brine shrimp into each well in the 6 -well plate Make observations in lab notebook Using a dissecting microscope (if needed), count the number of brine shrimp in each well (alive shrimps).
Record your data in your notebook using the graphic below as a template. Close the plate and store it for next observation.
Observations must be done within 24h-96h
Note: There will be times allocated and a sign up paper for observations Part E: Trypan blue viability test 2 Fall 2017 1) Label 3 glass slides to match the petri dishes prepared in Part C. 2) Transfer 1 brine shrimp from each petri dish onto the corresponding slide. 
Make observations in your lab notebook 3) Add a drop (~60 μl) of PBS on top of each specimen 4) Add 60 μl of Trypan blue to your shrimp and incubate for 1-2 minutes at room 
temperature. 5) Wick away excess liquid 6) Add 100 μl PBS to sample and observe (while alive!), looking for blue cells, using the 
dissecting scope 
Make observations in your lab notebook 7) Label 3 microfuge tubes to align with each sample. 8) Transfer each brine shrimp from the slide into the corresponding microfuge tube 9) Add 50 μl of PBS to the tube and use the mechanical disruption tool to homogenize the 
sample for ~2 minutes until a cell suspension has been generated. 10) Load 30-50 μl of your sample onto a new glass slide and add a cover slip. 11)Observe the sample on high power and use the scale below to qualitatively assess cytotoxicity” 0-no blue 1-some blue 2-fairly blue 3-totally blue.

I'm working on the following problem and would like some help. The current expert answer on here does not even match the problem:

Situation

Native Americans use forest plant species for food and ceremonial purposes. What is the risk to them if some areas of the US national forests and wildernesses where they collect these plants are sprayed with L7, a broadleaf and shrub herbicide?

Background

L7 is a systemic herbicide used to control deeply rooted herbaceous weeds and woody plants in rights-of-ways, forestry, rangelands, pastures, and small grains. L7 has been used for nearly 40 years. In forestry applications, as much as 1 lb active ingredient/acre of liquid is sprayed broadcast on foliage to open wildlife areas and rights-of-way. Only 1 treatment per year is allowed. Reentry into sprayed areas is allowed immediately after drying. Aerobic soil half-life is about 100 days.

Steps: Tier 1 Hazard and Dose-response Data

An acute oral LD50 evaluation was conducted in the rat. The LD50 was greater than 5000 mg/kg BW, so acute exposures are considered practically nontoxic. In a chronic toxicity feeding study conducted in the F344 rat, L7 was evaluated at 0, 20, 60 or 200 mg/kg BW/day for 2 years. The chronic toxicity LOEL was 60 mg/kg BW/day as evidenced by altered size and tinctorial properties of centrilobular hepatocytes and increased absolute and/or relative liver weights in both sexes. The Agency has classified L7 as Group E (evidence of non-carcinogenicity for humans). There is no evidence, based on the available data, to suggest that the chemical was associated with significant reproductive or developmental toxicity under the testing conditions.

A reference dose (RfD) for L7 was calculated to be 0.20 mg/kg BW/day based on a NOEL of 20 mg/kg BW/day from a two-year rat chronic feeding study. An uncertainty factor of 100 was used to account for the inter-species extrapolation and intra-species variability. The L7 chronic dietary exposure/risk estimates are extremely low. Because the dietary exposure/risk is so low, about 1/200th of the RfD, there are no concerns regarding chronic dietary exposure to L7.

Residue

Based on the application rate and the foliage type, the highly conservative estimated environmental residue is 135 mg/kg dry weight immediately after application.

Dietary Exposure

Consumption data on these forest plant species by Native Americans are lacking.

Risk Characterization Assumptions

• Max rate = 1 lb active ingredient/acre

• Body Weight = 70 kg (standard adult male weight used by US EPA)

• Chronic reference dose (RfD) = 0.2 mg/kg BW/d (this is the acceptable daily intake)

• Residue estimate = 135 mg/kg dry weight

• Adult enters the area immediately after spray dries

• Dietary Risk Quotient = Exposure ÷ Toxic Endpoint, so for this example Dietary Risk = (Residue * Consumption Rate) ÷ RfD

• Remember that a risk quotient (RQ) of 1 is where the exposure equals the toxic endpoint.

Questions

a. Given that specific consumption data are lacking for the treated plants, how would you estimate risk to Native Americans from consuming plants containing L7 residue?

b. The total vegetable consumption estimate per day in the US = 0.294 kg/70 kg adult (wet weight), or 0.06 kg/70 kg adult (dry weight). How can you use these numbers to help characterize the risk?

c. What refinements could be made to this dietary assessment?

d. What data elements are needed for higher-tiered aggregate assessments? Aggregate exposures include all possible routes and pathways of exposure to one chemical.

1.. Polymorphisms for a given trait are relatively common in most species. Discuss the possible advantages or polymorphisms in terms of evolutionary fitness. Be sure to relate your discussion to a specific example. It is also possible that organisms showing more heterozygosity may actually be less fit. Describe one such possible scenario.

2. In the peppered moth (Biston betularia), black individuals may be either homozygous (A1A1) or heterozygous(A1A2), whereas the pale gray moths are homozygous (A2A2). Suppose that in a sample of 250 moths from one locality, 108 are black, and 142 are gray.

3. Retrace the history of primate evolution from early primates to monkeys, apes and hominins. When did some ofthe significant divergences occur (such as between the prosimians and the monkeys or between the chimps and hominins)? What was happening with the continents and the major climatic conditions during these times?What are the major species (including the extinct species) along the human lineage after the split with the chimps and bonobos? Where did many of these events occur on the globe and when?

4. Spencer Wells described his study how the genetic markers in humans are being used to infer the historical geographical distribution of humans and the dispersal of our ancestors. Explain how the genetic markers on our DNA (from blood samples) helps us understand that history. What are the techniques he is using? What is the nature of the evidence? What are the major conclusions about the journey of our ancestors out of Africa?What were the major migrations of humans to all the other continents? Approximately when did each migration occur and what were the major paths? How does the evidence support these conclusions? What Supporting evidence besides the DNA evidence is being used to support these conclusions?

5. Provide an adaptive and a non adaptive hypothesis for the evolutionary loss of useless organs, such as eyes in many cave-dwelling animals. How might these hypotheses be tested?

6. Directional selection is one of the models of natural selection. Describe this type of selection in terms of the frequencies of advantageous alleles over time. What is the trend over time? What is the eventual outcome for this allele as long as no other evolutionary factors intervene? Describe at least one good example of directional selection.

7. Consider the first copy of an allele for insecticide resistance that arises by mutation in a population of insects exposed to an insecticide. Is this mutation an adaptation? If, after some generations, we find that most of the population is resistant, is the resistance an adaptation? If we discover genetic variation for insecticide resistance in a population that has had no experience of insecticides, is that variation an adaptation? If an insect population is polymorphic for two alleles, each of which confers resistance against one of two pesticides that are alternately applied, is that variation an adaptation? Or is each of the two resistance traits an adaptation?Explain your reasoning thoroughly.

8. Suppose that a mutation in a species of annual plant increases allocation to chemical defenses against herbivores, but decreases production of flowers and seeds (i.e., there is an allocation trade-off). What would you have to measure in a field study in order to predict whether or not the frequency of the mutation will increase?

9. In many socially monogamous species of parrots and other birds, both sexes are brilliantly colored or highly ornamented. Is sexual selection likely to be responsible for the coloration and ornaments of both sexes? How can there be sexual selection in pair-bonding species with a 1:1 sex ratio, since every individual presumably obtains a mate? Which of the models of sexual selection described in the book might account for these species characteristics?

10. Kin selection explains why organisms may provide benefits to relatives. Is there a conflict between the principle of kin selection and the evolution of siblicide and abortion?

11.Many species of albatrosses and other seabirds nest in colonies on islands. The adult search for food at sea,sometimes over great distances. Some ecologists who study seabirds turn to their favorite topic of discussion in a bar one evening, and one says, “I can imagine an albatross genotype that destroys the eggs of nestlings of its colony mates when the parents are away foraging, and leaves them dead without eating them. Do you think such a behavior would evolve?” One of his companions says, “Yes, because it would make more food available for the albatross and its offspring.” Another says, “No, because it would threaten the survival of the population.” The fourth says, “You’re both wrong. I have a different explanation for why albatrosses don’t kill others’ chicks.” What is the fourth ecologist’s explanation, and why does she think her companions are wrong?

12. The concept of a species is fundamental to understanding biology, yet there may not be one definition that fits all “types” of organisms (e.g. animals, plants, fungi, bacteria, slime mold, lichens, etc.). Discuss several of the definitions of a species as presented in class and present your own definition for a species. Compare the strengths and weaknesses of each definition. Ernst Mayr is strong proponent of the biological species concept.How does he justify his position? Do you agree or disagree? If we employ the biological species concept, when did species first exist? What were organisms before then, if not species? What might the consequences of the emergence of species be for processes of adaptation and diversification? Be sure to explain your reasoning thoroughly.

13. The process of speciation ultimately involves the development of reproductive isolation between two related populations of organisms. Describe the various types of both prezygotic and postzygotic reproductive isolation and give an example of each.

14. Respond to the following quote from the character named Mr. Spock in “Star Trek”:“A truly successful parasite is commensal, living in amity with its host, or even giving it positive advantages, as for instance, the protozoans who live in the digestive system of your termites and digest for them the wood they eat. A parasite that regularly and inevitably kills its host cannot survive long, in the evolutionary sense, unless it multiplies with tremendous rapidity ... it is not pro-survival.”From what you have learned in this course, do you agree or disagree with Spock? How can you apply your reasoning to the relative “fitness” of HIV which causes AIDS, the Ebola virus which causes hemorrhagic fever,fleas which suck blood from dogs, or the prokaryotic ancestors of mitochondria and chloroplasts?

15. In many species of birds and mammals, clutch size is larger in populations at high latitudes than in population sat low latitudes. Species of lizards and snakes at high latitudes often have smaller clutches, however, and are more frequently viviparous (bear live young rather than laying eggs), than low-latitude species. What selective factors might be responsible for these patterns? Explain your reasoning.

16. The popular media often presents evolution as being a predictable process with a definite goal. For instance, in one “Star Trek: Voyager” episode, the captain instructs the ship’s computer to extrapolate the “probable course” of evolution of hadrosaurs (a bipedal dinosaur), if hadrosaurs had been removed from Earth before the Cretaceous-Tertiary (K-T) Extinction and allowed to evolve on another planet. What information about the hadrosaurs’ new environment would have been useful in developing the best possible prediction? Given what you know on genetic drift and selective agents, is it possible to accurately predict the long-term course of evolution?

17. Young children often develop strong food preferences that sometimes seem bizarre to their parents --- such as wanting to eat only a certain food prepared in a familiar way, or being reluctant to each new foods or foods with strong or bitter tastes (like coffee and some vegetables). Develop an evolutionary explanation for such preferences. What evidence would you gather to investigate your hypothesis and rule out alternative explanations?

18. Many organisms, such as mammals, only reproduce by sexual means. Other organisms are exclusively asexual,such as many of the bacteria and fungi. And still others have ways of propagating by both sexual and asexualmeans. Discuss the relative advantages and disadvantages of each mode of reproduction. Why aren’t all organisms sexual critters? Why are many asexual organisms still very successful as evidenced by the pure abundance and diversity? What is the adaptive significance of having different genders (e.g. male and female)?In other words, why sex?

19. How might differential expression and regulation by Hox genes contribute to mosaic evolution in which different segments of an animal body plan evolve different morphology?

20. Development of a morphological structure involves many different types of gene products, including transcription factors, signaling proteins, and “effector” genes such as enzymes. When a morphological change occurs in a single mutational step, which of these types might be more or less likely to be involved? Within a gene, would such single-step events be more likely to involve coding or non-coding sequences, and what characteristics of the gene’s function might affect this likelihood?

21. Since 2001, the complete DNA sequences of the genomes of many people have been determined. If humans,along with other forms of life, have evolved from a common ancestor, what evidence of this would be expected in the human genome? In what ways might the history and processes of evolution help us interpret and make sense of the human genome sequence data?

22. Paleontologists and some biologists commonly infer function, and even behavior, from anatomical details.Skeletal features, for example, are often used to infer that an extinct mammal (such as an early hominid) was highly, somewhat, or not at all arboreal. This inference assumes a good fit of form to function (i.e., optimal form). Can this assumption be justified?

23. Stephen Jay Gould (1989) and others have argued that the evolution of self-conscious, intelligent species (i.e.humans) was historically contingent: it would not have occurred had any of a great many historical events been different. The philosopher Daniel Dennett (1995) and others have disagreed, arguing that convergent evolution is so common that if humans had not evolved, some other lineage would probably have given rise to a species with similar mental abilities. What do you think, and why? If Gould’s position is right, what are its philosophical implications, if any?

24. Explain how Intelligent Design was determined as a religious view rather than a scientific view in the court casein Dover, PA. Should a scientific explanation of evolution be included in a science curriculum in K-12 schools?How is science and religion different in how they seek answers to questions? How is term "theory" used differently in science than in everyday English use? What is biological evolution? What evidence is used to support the scientific explanation of evolution? Is it possible to accept scientific explanations without rejecting religious faith?

25. Discuss how a creationist versus an evolutionary biologist might explain some human characteristics and the implications of their differences. Sample characteristics: eyes; wisdom teeth; individually unique friction ridges(fingerprints); five digits rather than some other number; susceptibility to infections; fever when infected;variation in sexual orientation; limited life span.