Lack of influence of body exhaust gowns on aerobic bacterial surface counts in a mixed-ventilation operating theatre. A study of 62 hip arthroplasties.

Aerobic bacterial surface contamination was studied with and without the use of body exhaust gowns in an operating room equipped with mixed/turbulent ventilation and separate operating and anaesthetic areas during 62 hip joint arthroplasties. In 31 operations conventional gowns were used, and 31 were performed with body exhaust gowns. Bacterial surface contamination was monitored in the operating and anaesthetic area using 9 cm diameter settle plates (1+1) and nitrocellulose membranes (2+2) transferred after sampling to nutrient pads. Compared with conventional clothing, the use of body exhaust gowns did not significantly reduce the microbial contamination (P=0.1-0.7). On the settle plates 1 m from the patient 279+/-326 cfu/m(2)/h were observed with conventional clothing compared with 142+/-227 cfu/m(2)/h with body exhaust gowns. The first membrane located on the patient in the sterile area detected 250+/-590 cfu/m(2)/h with conventional clothing and 210+/-320 cfu/m(2)/h with exhaust gowns. For the second membrane on the floor, the counts were 1790+/-2700 and 1590+/-1590 cfu/m(2)/h. For all operations the settle plates yielded 210+/-287 cfu/m(2)/h in the operating area and 720+/-564 cfu/m(2)/h in the anaesthetic area (P=0.01). Compared with the membrane placed on the anaesthetic equipment the counts on the membrane placed on patient were also significantly lower (P=0.01) while the membranes placed on the floor in each area showed no difference in counts. In conclusion, compared with conventional clothing, the use of body exhaust gowns could not be proven to provide more protection against microbial contamination. The low number of colony forming units found in the operating area was similar to that expected from an ultraclean laminar airflow unit, although achieved with a cheaper and more energy saving system.

[1]  J. Tinkler,et al.  The importance of airborne bacterial contamination of wounds. , 1982, The Journal of hospital infection.

[2]  M. Dykstra,et al.  The effect of a portable HEPA-filtered body exhaust system on airborne microbial contamination in a conventional operating room. , 1996 .

[3]  C Pasquarella,et al.  The index of microbial air contamination. , 2000, The Journal of hospital infection.

[4]  O M Lidwell,et al.  Suggested bacteriological standards for air in ultraclean operating rooms. , 1983, The Journal of hospital infection.

[5]  J. Charnley,et al.  SECTION II GENERAL ORTHOPAEDICS Postoperative Infection after Total Hip Replacement with Special Reference to Air Contamination in the Operating Room , 1972, Clinical orthopaedics and related research.

[6]  G. J. Taylor,et al.  Wound disinfection with ultraviolet radiation. , 1995, The Journal of hospital infection.

[7]  Ruth B. Kundsin,et al.  Architectural design and indoor microbial pollution , 1988 .

[8]  D. Vesley,et al.  Bacterial dispersion in relation to operating room clothing , 1976, Journal of Hygiene.

[9]  O M Lidwell,et al.  Airborne contamination of wounds in joint replacement operations: the relationship to sepsis rates. , 1983, The Journal of hospital infection.

[10]  J H Scheibel,et al.  Bacterial contamination of air and surgical wounds during joint replacement operations. Comparison of two different types of staff clothing. , 1991, The Journal of hospital infection.

[11]  M. Madeo The role of air ventilation and air sampling in reducing the incidence of surgical wound infection rates. , 1996, The British journal of theatre nursing : NATNews : the official journal of the National Association of Theatre Nurses.

[12]  A P MacGowan,et al.  Importance of air quality and related factors in the prevention of infection in orthopaedic implant surgery. , 1998, The Journal of hospital infection.

[13]  G. Bannister,et al.  Clothing in laminar-flow operating theatres. , 1996, The Journal of hospital infection.

[14]  B Friberg,et al.  Surgical area contamination--comparable bacterial counts using disposable head and mask and helmet aspirator system, but dramatic increase upon omission of head-gear: an experimental study in horizontal laminar air-flow. , 2001, The Journal of hospital infection.

[15]  W C Noble,et al.  Dispersal of skin microorganisms * , 1975, The British journal of dermatology.

[16]  J. Charnley,et al.  Postoperative infection in total prosthetic replacement arthroplasty of the hip‐joint with special reference to the bacterial content of the air of the operating room , 1969, The British journal of surgery.

[17]  H. Humphreys,et al.  Air sampling: settle plates or slit samplers? , 2001, The Journal of hospital infection.

[18]  N. Dalén,et al.  Air contamination during hip and knee arthroplasties. Horizontal laminar flow randomized vs. conventional ventilation. , 1995, Acta orthopaedica Scandinavica.

[19]  G. Laurell,et al.  Protection of the patient in the operating suite. , 1980, The Journal of hospital infection.

[20]  W Whyte,et al.  In support of settle plates. , 1996, PDA journal of pharmaceutical science and technology.

[21]  M. Ritter,et al.  The surgeon's garb. , 1980, Clinical orthopaedics and related research.

[22]  H. Humphreys Infection control and the design of a new operating theatre suite. , 1993, The Journal of hospital infection.

[23]  B Friberg,et al.  Inconsistent correlation between aerobic bacterial surface and air counts in operating rooms with ultra clean laminar air flows: proposal of a new bacteriological standard for surface contamination. , 1999, The Journal of hospital infection.

[24]  J. Shaw,et al.  Efficacy of the Steri-Shield filtered exhaust helmet in limiting bacterial counts in the operating room during total joint arthroplasty. , 1996, The Journal of arthroplasty.

[25]  O M Lidwell,et al.  Effect of ultraclean air in operating rooms on deep sepsis in the joint after total hip or knee replacement: a randomised study. , 1982, British medical journal.

[26]  O M Lidwell,et al.  Air, antibiotics and sepsis in replacement joints. , 1988, The Journal of hospital infection.