Microbiology
10 questionsPseudomonas is which type of bacteria?
Which of the following is not a sporicidal agent?
Which of the following agents is most effective in destroying bacterial spores?
All of the sterilization methods are properly matched except?
What is the commonly used percentage of glutaraldehyde for high-level disinfection in healthcare settings?
Glass vessels and syringes are best sterilised by -
Which of the following is an intermediate level disinfectant?
In blood culture the ratio of blood to reagent is?
Which anticoagulant is used when blood is sent for blood culture?
Which of the following statements regarding resistance of penicillin in Staphylococcus aureus is false?
NEET-PG 2013 - Microbiology NEET-PG Practice Questions and MCQs
Question 631: Pseudomonas is which type of bacteria?
- A. Anaerobic
- B. Aerobic (Correct Answer)
- C. Microaerophilic
- D. Obligate anaerobe
Explanation: ***Aerobic*** - **Pseudomonas aeruginosa** is a classic example of an **aerobic bacterium**, meaning it requires oxygen for growth and metabolism. - Its ability to thrive in aerobic environments contributes to its prevalence in hospital settings and its capacity to cause a wide range of infections. *Anaerobic* - Anaerobic bacteria grow in the absence of oxygen and often die in its presence. **Pseudomonas** does not exhibit this characteristic. - Examples of anaerobic bacteria include *Clostridium* species. *Microaerophilic* - Microaerophilic bacteria require oxygen but only in low concentrations (5-10%), higher concentrations are inhibitory. - **Pseudomonas** grows optimally in atmospheric oxygen levels, not restricted to low concentrations. *Obligate anaerobe* - Obligate anaerobes are severely inhibited or killed by oxygen. - This is the opposite of **Pseudomonas**, which strictly requires oxygen for survival.
Question 632: Which of the following is not a sporicidal agent?
- A. Formaldehyde
- B. Glutaraldehyde
- C. Ethylene oxide
- D. Isopropyl alcohol (Correct Answer)
Explanation: ***Isopropyl alcohol*** - Isopropyl alcohol is an **antiseptic** and **disinfectant** that works by denaturing proteins and dissolving lipids, but it is not effective against bacterial spores. - Its efficacy against microbes is primarily for **vegetative bacteria**, fungi, and enveloped viruses. *Formaldehyde* - Formaldehyde is a potent **sporicide** that cross-links proteins and nucleic acids, making it effective for high-level disinfection and sterilization. - It is often used in solutions or as a gas for sterilizing heat-sensitive medical equipment. *Glutaraldehyde* - Glutaraldehyde is a **high-level disinfectant** and **sterilant** that works by alkylating protein and nucleic acid components, effectively killing spores. - It's commonly used for sterilizing endoscopic instruments and other heat-sensitive devices. *Ethylene oxide* - Ethylene oxide is a gaseous sterilant that **alkylates proteins** and nucleic acids, making it highly effective against all microorganisms, including spores, bacteria, and viruses. - It is frequently used for sterilizing heat-sensitive and moisture-sensitive medical devices.
Question 633: Which of the following agents is most effective in destroying bacterial spores?
- A. Ethanol
- B. Sodium hypochlorite
- C. Gamma radiation (Correct Answer)
- D. Chlorine
Explanation: ***Gamma radiation*** - **Gamma radiation** is the **most effective agent** for destroying **bacterial spores** among all the options listed - It achieves **complete sterilization** by causing irreversible DNA damage through ionization - Gamma radiation penetrates deeply and destroys all forms of microbial life, including the most resistant spores like *Bacillus* and *Clostridium* species - Used for **industrial sterilization** of medical equipment, pharmaceuticals, and heat-sensitive materials - Provides absolute reliability in spore destruction without the need for heat or prolonged contact time *Sodium hypochlorite* - **Sodium hypochlorite** does have **sporicidal activity** at high concentrations (5000-10000 ppm) with prolonged contact time - However, it requires **specific conditions** (high concentration, adequate contact time, organic matter removal) to be effective against spores - While useful as a chemical disinfectant, it is **less effective and less reliable** than gamma radiation for spore destruction - Commonly used for surface disinfection and water treatment *Chlorine* - **Chlorine gas** or aqueous chlorine solutions have limited sporicidal activity - Less effective than sodium hypochlorite at practical concentrations - More commonly used for water disinfection rather than spore destruction *Ethanol* - **Ethanol** is primarily **bactericidal** and **fungicidal** but **not sporicidal** - Cannot penetrate the resistant spore coat and cortex layers - Effective for vegetative bacteria but ineffective against bacterial spores
Question 634: All of the sterilization methods are properly matched except?
- A. Culture media - Autoclaving
- B. Glassware & syringes - Hot air oven
- C. Catgut suture - Radiation
- D. Bronchoscope - Autoclaving (Correct Answer)
Explanation: ***Bronchoscope - Autoclaving*** - **Autoclaving** uses high temperature and steam, which can damage the delicate heat-sensitive components and lenses of a bronchoscope. - **Bronchoscopes** are typically sterilized using **low-temperature sterilization methods** such as **ethylene oxide**, hydrogen peroxide plasma, or glutaraldehyde. *Catgut suture - Radiation* - **Radiation** (e.g., gamma irradiation) is a suitable and common method for sterilizing **heat-sensitive materials** like catgut sutures, ensuring sterility without compromising material integrity. - This method effectively destroys microorganisms by damaging their DNA. *Culture media - Autoclaving* - **Autoclaving** is the standard and most effective method for sterilizing **culture media**, which requires complete elimination of all microbial forms including spores. - The high heat and pressure achieved in an autoclave denature proteins and destroy microbial structures. *Glassware & syringes - Hot air oven* - A **hot air oven** is appropriate for sterilizing **heat-stable items** like glassware and metal syringes, as it provides dry heat that penetrates well and kills microorganisms by oxidation. - This method is particularly useful for items that can be damaged by moisture or steam.
Question 635: What is the commonly used percentage of glutaraldehyde for high-level disinfection in healthcare settings?
- A. 1%
- B. 2% (Correct Answer)
- C. 3%
- D. 4%
Explanation: ***2%*** - A **2% concentration of glutaraldehyde** is the most common and effective formulation used for **high-level disinfection** of heat-sensitive medical instruments. - This concentration achieves sporicidal activity after prolonged exposure and is effective against a broad spectrum of microorganisms including bacteria, viruses, and fungi. *1%* - A **1% concentration of glutaraldehyde** is generally considered too low for reliable **high-level disinfection** in healthcare settings. - While it may have some antimicrobial activity, it typically does not meet the necessary efficacy standards for disinfecting critical or semi-critical medical devices. *3%* - While a **3% concentration of glutaraldehyde** can be effective for disinfection, it is not the most commonly used, and the increased concentration can lead to **higher toxicity** and potential for skin and respiratory irritation for healthcare workers. - The slight increase in efficacy over 2% often does not outweigh the increased risks and cost associated with its use. *4%* - A **4% concentration of glutaraldehyde** is generally considered unnecessarily high for routine **high-level disinfection** and is not commonly used in clinical practice. - This higher concentration significantly increases the risk of **toxicity and occupational exposure issues**, with little additional benefit in terms of disinfection efficacy compared to 2%.
Question 636: Glass vessels and syringes are best sterilised by -
- A. Dry heat sterilization in a hot air oven (Correct Answer)
- B. Steam sterilization in an autoclave
- C. Ethylene oxide sterilization
- D. Radiation sterilization
Explanation: **Dry heat sterilization in a hot air oven** - **Dry heat sterilization** (160-180°C for 1-2 hours) is the **traditional and preferred method** for **glassware and glass syringes**. - **Hot air ovens** achieve sterilization by oxidative destruction and protein denaturation, leaving items completely **dry** and free from moisture. - **Advantages**: No corrosion, no rusting, items remain dry, ideal for **powders, oils, and glassware** that can withstand high temperatures. - **Note**: This question refers to **glass syringes** (historically used, now largely replaced by disposable plastic syringes which are pre-sterilized by radiation). *Steam sterilization in an autoclave* - **Autoclaving** uses **moist heat** (121°C at 15 psi for 15 minutes) and is highly effective for most medical instruments. - **Disadvantage for glassware**: Rapid temperature changes and steam exposure can cause **thermal shock, cracking, or etching** of delicate glassware. - Items emerge **wet** and require drying, which is undesirable for certain laboratory applications. - **Modern context**: Standard method for surgical instruments and heat-stable plastics. *Ethylene oxide sterilization* - **Ethylene oxide (ETO)** is a **low-temperature chemical sterilization** method (50-60°C) for heat-sensitive items. - Used for plastics, rubber, electronics, and endoscopes that cannot tolerate heat. - Requires **long exposure** (12-24 hours) and **aeration period** (up to 7 days) to remove toxic residues. - **Not preferred** for routine glassware sterilization when heat methods are suitable. *Radiation sterilization* - **Gamma radiation or electron beam** sterilization is used for **pre-packaged disposable medical devices**, pharmaceuticals, and plastic syringes. - Highly effective but **expensive** and requires specialized facilities. - Not practical for **routine laboratory glassware** sterilization in clinical or research settings.
Question 637: Which of the following is an intermediate level disinfectant?
- A. Ethylene oxide
- B. Hypochlorite (Correct Answer)
- C. 2% glutaraldehyde
- D. None of the options
Explanation: ***Hypochlorite*** - **Hypochlorite** (e.g., sodium hypochlorite, bleach) is an effective **intermediate-level disinfectant** commonly used for surface disinfection and water purification. - It works by **oxidizing cellular components** and disrupting membrane function in microorganisms, effective against a wide range of bacteria, viruses, and some fungi. *2% glutaraldehyde* - **2% glutaraldehyde** is a **high-level disinfectant** and **sterilant** often used for heat-sensitive medical equipment like endoscopes. - It is effective against bacterial spores, mycobacteria, fungi, and viruses, which exceeds the scope of intermediate-level disinfection. *Ethylene oxide* - **Ethylene oxide** is a **gaseous sterilant** used for heat-sensitive and moisture-sensitive medical devices, making it a high-level modality. - It works by **alkylating proteins and nucleic acids**, effectively killing all forms of microbial life, including spores. *None of the options* - This option is incorrect because **Hypochlorite** is indeed an intermediate-level disinfectant. - The classification of disinfectants is based on their ability to kill different types of microorganisms, with hypochlorite falling squarely into the intermediate category.
Question 638: In blood culture the ratio of blood to reagent is?
- A. 1:5
- B. 1:20
- C. 1:10 (Correct Answer)
- D. 1:100
Explanation: ***1:10*** - A 1:10 ratio of **blood to reagent (culture media)** is recommended for optimal growth of microorganisms in blood cultures. - This dilution minimizes the inhibitory effect of **human antimicrobial factors** present in the blood, while still providing sufficient blood volume for pathogen detection. *1:5* - A 1:5 ratio would mean a relatively **higher concentration of blood** in the culture. - This higher concentration could lead to increased inhibition of bacterial growth by **host defense mechanisms** or **antibiotics** present in the patient's blood, potentially causing false-negative results. *1:20* - A 1:20 ratio implies a **lower concentration of blood** relative to the culture media. - While it further dilutes inhibitory factors, it also reduces the total number of microorganisms sampled, possibly leading to **false-negative results** if the bacterial load is low. *1:100* - A 1:100 ratio would result in an **extremely low concentration of blood** in the culture. - This significantly reduces the likelihood of detecting microorganisms, especially when the **bacteremia is sparse**, due to insufficient bacterial inoculum, leading to a high rate of false negatives.
Question 639: Which anticoagulant is used when blood is sent for blood culture?
- A. Sodium citrate
- B. EDTA
- C. Oxalate
- D. SPS (Correct Answer)
Explanation: ***SPS*** - **SPS (Sodium Polyanethol Sulfonate)** is the preferred anticoagulant for blood cultures because it inhibits phagocytosis and complement activation, allowing microorganisms to survive and grow. - It also neutralizes the bactericidal effect of aminoglycoside antibiotics, which might be present in the patient's blood. *Sodium citrate* - **Sodium citrate** works by binding to calcium ions, preventing blood coagulation, and is typically used for coagulation studies. - It is not suitable for blood cultures as it does not have the anti-phagocytic or antibiotic-neutralizing properties of SPS. *EDTA* - **EDTA (Ethylenediaminetetraacetic acid)** is a strong chelator of calcium and is primarily used for hematology tests like complete blood counts (CBC) as it preserves cell morphology. - It can be toxic to some bacteria and would inhibit microbial growth, making it unsuitable for blood cultures. *Oxalate* - Various **oxalates** (e.g., potassium oxalate) also act as anticoagulants by precipitating calcium, and are commonly found in tubes for glucose testing when combined with a glycolytic inhibitor. - Oxalates are generally unsuitable for blood cultures because they can inhibit the growth of certain microorganisms.
Question 640: Which of the following statements regarding resistance of penicillin in Staphylococcus aureus is false?
- A. Methicillin resistance is due to alterations in penicillin-binding proteins (PBPs).
- B. Penicillinase production is mediated by plasmids.
- C. Hospital strains predominantly produce a unique type of penicillinase. (Correct Answer)
- D. Penicillinase production can be transmitted by transduction.
Explanation: ***Hospital strains predominantly produce a unique type of penicillinase*** - This statement is **false** because hospital strains do not produce a truly "unique type" of **penicillinase** compared to community strains. - **Penicillinase (beta-lactamase)** is a common resistance mechanism found across various *S. aureus* strains, not exclusive to hospital environments. *Methicillin resistance is due to alterations in penicillin-binding proteins (PBPs)* - This statement is **true** as **MRSA** resistance involves the **mecA gene** encoding **PBP2a**. - **PBP2a** has low affinity for **beta-lactam antibiotics**, allowing cell wall synthesis despite antibiotic presence. *Penicillinase production is mediated by plasmids* - This statement is **true** because **penicillinase genes** are typically located on **plasmids**. - **Plasmids** facilitate horizontal transfer of resistance genes between bacterial populations. *Penicillinase production can be transmitted by transduction* - This statement is **true** as **transduction** via **bacteriophages** can transfer resistance genes. - **Plasmid-borne penicillinase genes** can spread through this horizontal gene transfer mechanism.