Reach Us +1-217-403-9671
Effect of Humidity on Sterilization Using Photocatalyst | OMICS International
ISSN: 2167-7689
Pharmaceutical Regulatory Affairs: Open Access
Make the best use of Scientific Research and information from our 700+ peer reviewed, Open Access Journals that operates with the help of 50,000+ Editorial Board Members and esteemed reviewers and 1000+ Scientific associations in Medical, Clinical, Pharmaceutical, Engineering, Technology and Management Fields.
Meet Inspiring Speakers and Experts at our 3000+ Global Conferenceseries Events with over 600+ Conferences, 1200+ Symposiums and 1200+ Workshops on Medical, Pharma, Engineering, Science, Technology and Business
All submissions of the EM system will be redirected to Online Manuscript Submission System. Authors are requested to submit articles directly to Online Manuscript Submission System of respective journal.

Effect of Humidity on Sterilization Using Photocatalyst

Hideharu Shintani*

Faculty of Science and Engineering, Chuo University, Tokyo, Japan

*Corresponding Author:
Hideharu Shintani
Faculty of Science and Engineering
Chuo University, 1-13-27, Kasuga, Bunkyo
112-8551, Tokyo, Japan
Tel: +81425922336
Fax: +81425922336
E-mail: [email protected]

Received date: October 08, 2014; Accepted date: October 09, 2014; Published date: October 13, 2014

Citation: Shintani H (2014) Effect of Humidity on Sterilization Using Photocatalyst. Pharmaceut Reg Affairs 3:e141. doi:10.4172/2167-7689.1000e141

Copyright: © 2014 Shintani H. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Visit for more related articles at Pharmaceutical Regulatory Affairs: Open Access

The photocatalyst equipment consists of a titanium dioxlde (TiO2) plate and an ultraviolet lamp. The authors studied if the photocatalyst equipment is practically applicable in sterilizing environmental microorganisms in the health care facility. The number of microorganisms was compared among no sterilization (control), UV alone and the photocatalyst sterilization. As a result, a statistical difference was observed between control and the photocatalyst sterilization against airborne microorganisms (p<0.01) but not against surface microorganisms (p>0.2). In addition, no significant difference between UV alone and photocatalyst (p>0.2), indicating the major function of photocatalyst is not OH radicals, but UV exposure, however OH radicals also contribute when humidity increased because OH radicals increased when water increased. OH radicals are from water.

The photocatalyst uses an air sucking system, so it may be ineffective against microorganisms tightly attached to surfaces. However, the effectiveness of the photocatalyst to sterilize airborne microorganisms in the health care facility was successfully confirmed.

Concerning the humidity effect on the photocatalyst sterilization, the authors compared the number of airborne microorganisms in cases of the control, UV alone and photocatalyst sterilization when humidity was changed. A statistical difference was observed between UV alone and the photocatalyst sterilization (p<0.01) when humidity was increased to 60-70%, but not observed between UV and the photocatalyst sterilization (p>0.2) when humidity was around 10- 20%. This indicates that maintaining high humidity levels will present satisfactory sterilization results due to a greater production of OH radicals from exposed TiO2 by UV. Furthermore, no effect of the adsorption of sucked airborne microorganisms on the TiO2 membrane may be speculated.

Nosocomial infection recently collects a great attention in the health care facilities. Nosocomial infections have been reported mostly due to cross-transmission via hands from health care employees to immunodeficient patients. It is confirmed that washing hands frequently is important ways to prevent nosocomial infections in the health care facility. In addition it is indispensable to sterilize airborne and falling microorganisms to diminish nosocomial infections. These airborne and falling microorganisms mostly come from humans. The representative microorganisms related to nosocomial infections have been presented [1,2].

According to reports, several sorts of microorganisms and viruses in plates were exposed to the photocatalyst in a model experiment and satisfactory sterilization results were obtained [1,2]. The sterilization efficiency of the photocatalyst in the practical use with regard to environmental microorganisms in places such as in the health care facility, however the validation study of the photocatalyst sterilization has not yet been conducted so far. It is keenly required to keep the relatively dirty environment of the health care facility clean to prevent nosocomial infections. Prior to maintaining cleanliness within the health care facility with the use of the photocatalyst, it is necessary to confirm whether the photocatalyst equipment may or may not be practically useful for sterilizing the environmental microorganisms in the health care facility.

In addition the effect of humidity on the photocatalyst sterilization has not been reported, so it must be confirmed the efficiency of the photocatalyst. As one of factor of photocatalyst efficiency, humidity is thought to play an important role with regards to OH radical production.

The photocatalyst equipment in general consists of an ultraviolet (UV) lamp and an anatase type titanium dioxide (TiO2) plate [1,2]. With UV irradiation to the TiO2 plate, 0H radicals are produced [1,2]. The produced OH radicals is of major importance in this sterilization system, The O, OOH, H or OH radicals (Figure 1) produced from the irradiated TiO2 plate, but the sterilization efficiency of the OH radicals is superior to other radicals (Figure 1). The role of the OH radical in sterilization is the proton removal from the microorganisms, which causes the oxidation of the microorganisms and results in successful sterilization. The OH radical itself changes to H2O by the reaction of OH·+ H+ [1].


Figure 1: Comparison Efficiency of Sterilization among OH, OOH, H and O radicals.

When the air of the environment contaminated with microorganisms is sucked into the photocatalyst equipment, the microorganisms within the photocatalyst will be sterilized with the combined effect of UV irradiation and OH radical exposure produced from the irradiated TiO2. The major UV sterilization mechanism was known as the thymine dimmer, thymine-cytosine, cytosine-cytosine dimer formation (Figure 2), which depends on wavelength. However UV sterilization efficiency with regard to fungi was not satisfactory, especially Aspergillus niger or Rhizopus nigricans, Thus it is speculated that when UV and OH radical treatment are combined, the synergistic effect can produce more successful sterilization effects with regard to bacteria and fungi. To confirm this, the authors compared the number of the airborne and falling microorganisms receiving no sterilization, control, UV alone (no TiO2 plate) and photocatalyst (TiO2 + UV) sterilization treatment, the results were analyzed using several statistical procedures. The results were as mentioned in advance. TiO2 plate effect was not significant, but humidity effect is significant.


Figure 2: Model Figure of Thymine Dimers by UV Exposure.

It has not yet additionally been confirmed how photocatalyst function in sterilization may change when the humidity around the photocatalyst equipment changes. However, it was speculated that it would be important to maintain relatively high level of humidity (60-70%) to attain satisfactory and reproducible sterilization results with the photocatalyst equipment. That is because the OH radicals from water (humidity, so it can be speculated that the photocatalyst efficiency might increase when humidity increases. To confirm this, the author studied the sterilization efficiency of the photocatalyst against airborne microorganisms with different levels of humidity around the photocatalyst equipment. As an example, sterilization of ozone gas, peracetic acid gas or dichlorooxide gas requires high humidity such as 90-99%. Hydrogen peroxide does not require such a high humidity, but requires at least more than 70%, indicating Aw (water activity) is an essential factor in sterilization. Photocatalyst sterilization is not exception as it requires at least 60-70%, probably more than 60-70%. It will be clarified by the further experiment.


Select your language of interest to view the total content in your interested language
Post your comment

Share This Article

Article Usage

  • Total views: 12312
  • [From(publication date):
    December-2014 - Nov 18, 2019]
  • Breakdown by view type
  • HTML page views : 8475
  • PDF downloads : 3837