State how penicillins may be modified to increase their effectiveness.

State how penicillins may be modified to increase their effectiveness.

State how aspirin can be converted to water-soluble aspirin.

A student prepares aspirin from salicylic acid in the laboratory, extracts it from the reaction mixture, ensures the sample is dry and determines its melting point.

Suggest why the melting point of the student’s sample is lower and not sharp compared to that of pure aspirin.

Organic molecules can be characterized using infrared (IR) spectroscopy.

Compare and contrast the infrared peaks above 1500 cm⁻¹ in pure samples of aspirin and salicylic acid using section 26 of the data booklet.

Deduce the structural formula of the by-product of this reaction.

Predict one absorption band present in an infrared (IR) spectrum of aspirin, using section 26 of the data booklet.

A student prepares aspirin from salicylic acid in the laboratory, extracts it from the reaction mixture, ensures the sample is dry and determines its melting point.

Suggest why the melting point of the student’s sample is lower and not sharp compared to that of pure aspirin.

Explain why aspirin is not stored in a hot, humid location.

The widespread use of penicillin and its derivatives has led to the appearance of resistant S. aureus strains.

Outline how these bacteria inactivate the antibiotics.

Outline how the structure of penicillin has been modified to overcome this resistance.

(i) Outline what is meant by the term “ring strain”.

(ii) On the diagram above, label with asterisk/s (*) the carbon atom/s that experience ring strain.

Formulate an equation for the conversion of aspirin to a more water soluble derivative.

State why aspirin should not be taken with alcohol.

Identify the feature in penicillin responsible for its antibiotic activity.

State two techniques, other than IR spectroscopy, which could be used to confirm the identity of aspirin.

Compare and contrast the IR spectrum of aspirin with that of salicylic acid, using section 26 of the data booklet.

Describe how penicillin combats bacterial infections.

Determine the percentage purity of the synthesized aspirin.

Organic molecules can be characterized using infrared (IR) spectroscopy.

Compare and contrast the infrared peaks above 1500 cm⁻¹ in pure samples of aspirin and salicylic acid using section 26 of the data booklet.

Unreacted salicylic acid may be present as an impurity in aspirin and can be detected in the infrared (IR) spectrum.

Name the functional group and identify the absorption band that diff erentiates salicylic acid from aspirin. Use section 26 of the data booklet.

Name:

Absorption band:

Aspirin can be obtained from salicylic acid.

Unreacted salicylic acid may be present as an impurity in aspirin and can be detected in the infrared (IR) spectrum.

Name the functional group and identify the absorption band that differentiates salicylic acid from aspirin. Use section 26 of the data booklet.

Name: 

Absorption band:

Outline how the bioavailability of aspirin may be increased.

Suggest why aspirin is slightly soluble in water. Refer to section 37 of the data booklet.

State two techniques which could be used to confirm the identity of aspirin.

The widespread use of penicillin and its derivatives has led to the appearance of resistant S. aureus strains.

Outline how these bacteria inactivate the antibiotics.

State the type of reaction used to synthesize aspirin from salicylic acid.

State why aspirin should not be taken with alcohol.

Determine the percentage purity of the synthesized aspirin.

Outline how aspirin can be chemically modified to increase its solubility in water.

Outline how the structure of penicillin has been modified to overcome this resistance.

Determine the mass of aspirin which reacted with 16.25 cm³ of 0.100 mol dm⁻³ NaOH solution.

Identify the feature in penicillin responsible for its antibiotic activity.

Describe how penicillin combats bacterial infections.

Determine the mass of aspirin which reacted with 16.25 cm³ of 0.100 mol dm⁻³ NaOH solution.

Aspirin is often taken to reduce pain, swelling or fever. State one other use of aspirin.

Predict one absorption band present in an infrared (IR) spectrum of aspirin, using section 26 of the data booklet.

Aspirin, C₆H₄(OCOCH₃)COOH, is only slightly soluble in water.

Outline, including an equation, how aspirin can be made more water-soluble. Use section 37 in the data booklet.

(i) Some antibiotic-resistant bacteria produce a beta-lactamase enzyme which destroys penicillin activity. Suggest how adding clavulanic acid to penicillin enables the antibiotic to retain its activity.

(ii) Populations of antibiotic-resistant bacteria have increased significantly over the last 60 years. Outline why antibiotics such as penicillin should not be prescribed to people suffering from a viral infection.

Outline how aspirin can be chemically modified to increase its solubility in water.

The solubility of aspirin is increased by converting it to an ionic form. Draw the structure of the ionic form of aspirin.

Suggest why aspirin is slightly soluble in water. Refer to section 37 of the data booklet.

Deduce the structural formula of the by-product of this reaction.

Explain, with reference to the action of penicillin, why new penicillins with different side-chains need to be produced.

Explain how IR spectroscopy can be used to distinguish aspirin from salicylic acid.

Explain, with reference to the action of penicillin, why new penicillins with different side-chains need to be produced.

The solubility of aspirin is increased by converting it to an ionic form. Draw the structure of the ionic form of aspirin.