The Fischer projection of glucose is shown. How man chiral centers does glucose have? How many stereoisomers of glucose can exist (including glucose, itself)? Define the absolute configurations (R or S) for carbons 2 and 3. H12 H-C-OH HO-C-H H-C-OH H C-OH CH,OH glucose

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**Fischer Projection of Glucose** The Fischer projection of glucose is shown below. **Questions:** 1. How many chiral centers does glucose have? 2. How many stereoisomers of glucose can exist (including glucose itself)? 3. Define the absolute configurations (R or S) for carbons 2 and 3. **Fischer Projection Diagram:** Here is the representation of glucose in a Fischer projection: ``` H | H-C=O | H-C-OH | HO-C-H | H-C-OH | H-C-OH | H-C-OH | CH2OH ``` **Explanation:** - The Fischer projection shows the arrangement of the atoms and groups around the carbon backbone of the glucose molecule, with vertical lines representing bonds going into the plane of the paper, and horizontal lines representing bonds coming out of the plane. - Each intersection of lines (except the terminal CH2OH group) represents a chiral center. **Notes:** - Glucose has 4 chiral centers. - The number of possible stereoisomers is determined by \(2^n\), where \(n\) is the number of chiral centers. For glucose, \(2^4 = 16\) stereoisomers are possible. - To define the absolute configurations (R or S), you must prioritize the substituents around the carbon centers according to Cahn-Ingold-Prelog rules and determine the direction (clockwise or counterclockwise) of priority, but the specific configurations for carbons 2 and 3 are not provided here.