gms | German Medical Science

GMS Hygiene and Infection Control

Deutsche Gesellschaft für Krankenhaushygiene (DGKH)

ISSN 2196-5226

Indications and the requirements for single-use medical gloves

Indikationen und die sich daraus ergebenden Anforderungen an medizinische Einmalhandschuhe

Review Article

Search Medline for

  • corresponding author Axel Kramer - Institute of Hygiene and Environmental Medicine, University Medicine Greifswald, Germany
  • Ojan Assadian - Institute for Skin Integrity and Infection Prevention, University of Huddersfield, United Kingdom

GMS Hyg Infect Control 2016;11:Doc01

doi: 10.3205/dgkh000261, urn:nbn:de:0183-dgkh0002611

Published: January 12, 2016

© 2016 Kramer et al.
This is an Open Access article distributed under the terms of the Creative Commons Attribution 4.0 License. See license information at http://creativecommons.org/licenses/by/4.0/.


Abstract

Aim: While the requirements for single-use gloves for staff protection are clearly defined, the conventional medical differentiation between “sterile surgical gloves” used during surgical procedures and “single-use medical gloves” used in non-sterile medical areas does not adequately define the different requirements in these two areas of use. Sterilization of single-use medical gloves is not performed if sterility is not required; thus, another terminology must be found to identify the safety quality of non-sterile single-use medical gloves. Therefore, the labeling of such gloves should reflect this situation, by introducing the term “pathogen-free” single-use glove. The hygienic safety of such a glove would be attainable by ensuring aseptic manufacturing conditions during manufacturing and control of pathogen load of batch controls after fabrication.

Proposed recommendation: Because single-use gloves employed in non-sterile areas come into contact not only with intact skin but also with mucous membranes, no potential pathogens should be detectable in 100 mL of rinse sample. In order to declare such gloves as pathogen-free we suggest absence of the indicator species S. aureus and E. coli. In addition, the total CFU count should be evaluated, since a high load indicates lack of optimal hygiene during the manufacturing process. Based on the requirements for potable water and findings obtained from investigations of the bacterial load of such gloves after manufacturing, the here suggested limit for the total bacterial count of <102 CFU/mL of rinse sample per glove seems realistic.

Keywords: single-use medical gloves, indications, requirements, definitions, “germ-poor” single-use gloves, pathogen-free single-use gloves

Zusammenfassung

Problemstellung: Während die Anforderungen an Einmalhandschuhe für den Personalschutz definiert sind, trägt die in der Medizin gängige Unterscheidung zwischen „sterilen chirurgischen Operations- (OP)- Handschuhen“ und „medizinischen Einmalhandschuhen“ zur Anwendung in nicht sterilen Bereichen den unterschiedlichen Anforderungen bezüglich der Erregerbelastung nur ungenügend Rechnung. Da aus Kostengründen, aber auch aufgrund fehlender hygienischer Notwendigkeit keine abschließende Sterilisation medizinischer Einmalhandschuhe durchgeführt wird, sofern keine Sterilität benötigt wird, muss eine andere Lösung gefunden werden, um die Unbedenklich nicht abschließend sterilisierter medizinischer Einmalhandschuhe zu gewährleisten und auszuweisen. Zugleich sollte die Bezeichnung der Handschuhe diesem Umstand Rechnung tragen. Letzteres wäre durch die Einführung des Terminus „pathogenfreier“ Einmalhandschuh gegeben. Die hygienische Unbedenklichkeit eines derartigen Handschuhs wäre durch die Gewährleistung aseptischer Herstellungsbedingungen erreichbar und durch eine Chargenkontrolle nach der Herstellung in Bezug auf die Erregerbelastung nachweisbar.

Anforderungen: Da Einmalhandschuhe zur Anwendung in nicht sterilen Bereichen nicht nur mit intakter Haut, sondern auch mit Schleimhäuten in Kontakt kommen, sollten in 100 mL Sammelflüssigkeit keine potentiell pathogenen Erreger nachweisbar sein. Für die Deklarierung der Eigenschaft pathogenfrei („keimarm“) wird die Beschränkung auf die Indikatorspecies S. aureus und auf E. coli vorgeschlagen. Obwohl die Gesamtkoloniezahl für den Patientenschutz nicht relevant ist, erscheint auch ihre Bestimmung sinnvoll, weil eine hohe Belastung auf hygienische Mängel im Herstellungsprozess hinweist. Unter Berücksichtigung der Anforderungen an Trinkwasser sowie der erzielten Befunde erscheint ein Grenzwert von <102 KbE/mL Sammelflüssigkeit bezogen auf einen Handschuh realistisch.

Schlüsselwörter: medizinische Einmalhandschuhe, Indikationen, Anforderungen, Definitionen, keimarmer Einmalhandschuh, pathogenfreier Einmalhandschuh


Introduction

In health-care facilities, medical staff uses gloves for the following indications:

  • Protection of the wearer from contamination with blood, secretions, and excretions and the associated risk of contamination with pathogens capable of reproduction
  • Prevention of pathogen release from the hand into the sterile work area during aseptic duties
  • Protection from chemicals
  • Defined pathogen barrier as protection from biological agents
  • Radiation protection
  • Textile undergloves employed to reduction of amount of sweat produced in the glove.

These various indications demand different qualities of the gloves.

For the first four indications, single-use gloves made of latex or synthetic material are employed single or double. In contrast, to reduce the amount of sweat produced by prolonged wearing of such gloves, textile (e.g. cotton) undergloves are worn which, after wearing, can be processed for further use by performing a disinfection wash cycle [1]. However, sterile undergloves must be worn under sterile surgical gloves.

While the requirements for single-use gloves for staff protection are clearly defined, the conventional differentiation between “sterile surgical gloves” used for surgical procedures and “single-use medical gloves” used in non-sterile areas does not adequately define the different requirements in the two areas of use. In particular, the currently used German description of non-sterile single-use gloves as “germ-poor” disposable gloves is merely a broad qualitative description, and not quantitatively objectified. The term “germ poor” used in German speaking countries only means that no risk of infection emanates from such “germ-poor” objects. However, it is not clear whether this property – should it exist at all – is ensured by low levels of pathogens or the possible presence of largely non-virulent microorganisms, and which requirements result from this, since the infection risk depends on multiple factors, such as glove use, pathogen load, and the virulence of microorganisms present. Moreover, the term “germ-poor” is used only in German; it does not occur in other languages. Nevertheless, the English term “clean single-use gloves” or the French term “gants d’examen” (examination gloves) also do not solve the problem. Even the expression “not sterile”, used by Hughes et al. [2], says nothing about the contamination risk of such gloves. Because – in analogy to the other descriptions mentioned here – the term “germ-poor single-use glove” says nothing about the actual microbial load or possible risks of infection upon employment in the various areas of use, this article suggests and explains a new proposed terminology “pathogen-free single-use gloves” which shall better reflect the required properties of such gloves.


Distinction between gloves as a medical device (MDD) and gloves as personal protective equipment (PPE), and resulting requirements

Requirements for single-use gloves declared as MDD

In terms of protection against infection, sterile surgical gloves should meet infection protection requirements in both directions, i.e., protection of the patient and the wearer.

In contrast, single-use gloves that are not intended for sterile use serve only to protect the wearer from contamination. It is a common misconception that these non-sterile single-use gloves, used correctly, also serve to protect the patient. However, they do provide some indirect protection by preventing massive contamination, so that conventional hand disinfection after removing the gloves is sufficient to guarantee that any residual pathogens on the skin will be killed. For instance, after artificial massive contamination with E. coli approximately 2 log10 remained on the hands after hand disinfection [3]. Analogous data exist for MRSA, where 2–3 log10 residual contamination of the hands remained after hand disinfection [4]. Thus, single-use gloves can also facilitate the interruption of infection transmission [5], [6], [7], if used adequately. Based on their intended function, both types of gloves are classified as medical devices.

In addition to the physical requirements, surgical gloves must also be sterile [8]. Furthermore, the endotoxin content must not exceed 20 endotoxin units per pair of gloves if gloves are labeled as having “low endotoxin content” [9], [10]. The content of powder must not exceed 2.0 mg per glove to qualify them as powder-free gloves [11]. The manufacturer shall monitor the leachable protein in finished gloves containing natural rubber latex by the method specified in EN 455-3 [10].

Single-use gloves intended for use in non-sterile areas must meet the following requirements in order to fulfill their physical protection function [12]:

  • Labeled as “MDD 93/42/EEC”
  • AQL (accepted quality assurance level) of ≤1.5 in accordance with EN 455-1 [13]
  • Tearing strength during production of at least 9 Newton in accordance with EN 455-2 [14]
  • Biocompatibility in terms of chemicals, endotoxins, and freedom from powder and leachable proteins in accordance with EN 455-3 [10]
  • Shelf life of at least 3 years in accordance with EN 455-4 [15].

However, this list does not mention requirements for the microbiological safety of single-use gloves employed in non-sterile applications.

Both in the Recommendations of the Commission for Hospital Hygiene and Infection Prevention of the Robert Koch Institute (KRINKO) Berlin and in the Guidelines of the Association of the Scientific Medical Societies in Germany (AWMF), the term “germ-poor single-use medical gloves” is used for single-use medical gloves employed for non-sterile applications. This characterization, however, is inadequate, since the qualitative term “germ poor” has neither been defined nor tested. To date, although these products are certified based on the MDD or PPE regulations, the pathogen load limit of these single-use gloves has not been tested.

Because it is hygienically unnecessary and would incur needless expenses, final sterilization of single-use medical gloves is not performed if sterility is not required; thus, another solution must be found to ensure the safety of single-use medical gloves that do not undergo final sterilization. At the same time, the labeling of these gloves should reflect this situation, for instance, by introducing the term “pathogen-free” single-use glove, i.e., a glove that does not have to be sterile but must not be contaminated with pathogens. The hygienic safety of such a glove would be attainable by ensuring aseptic manufacturing conditions, and provable in terms of pathogen load by batch control after fabrication.

To investigate the current microbiological quality of single-use gloves employed in non-sterile applications, a microbiological examination of a representative sample (Ansell® single-use glove, glove age 3–6 months, from each of 6–8 different factories and 4 different countries, total n=30) was conducted by an independent external laboratory (BMA, Bochum, Germany). A total of 11 different glove models were tested, comprising 2 ethylene-vinyl-acetate models, one neoprene model, 3 latex models, and 5 nitrile glove models. In accordance with DIN EN ISO 11737-1 [16], the gloves were examined for bacteria and fungi as well as total microbial count in 15 mL of each rinse sample. The total microbial count showed an average of 5 CFU/15 mL of rinse sample (minimum = 0 KbE/15 mL, maximum = 36 KbE/15 mL), and thus was 100 times lower than the threshold value for potable water. Similar results were obtained in a second investigation of a different premium glove manufacturer (SafeDon®, 3 different latex models and one nitrile model). The testing following the same methodology as described in the DIN EN ISO 11737-1 [16] yielded a mean microbial total count of 8.4 CFU/15 mL (maximum: 13.5 CFU/15 mL) and for the nitrile model a mean total microbial count of 4 CFU/15 mL auf (maximum: 14.1 CFU/15 mL). Again, not only the mean values, but also the maximum CFU/mL counts ranged more than 100 times below the microbiological recommendations for potable water in Europe.

Upon aseptic removal of gloves (n=38) from their boxes at an orthopedic ward [2], the total load varied between 0 and 9.6×103 CFU/glove. Bacillus spp. were present on 82% of samples, skin commensals on 50% with coagulase-negative staphylococci (CoNS) as the predominant species, and E. faecalis, K. pneumoniae, Pseudomonas spp. or S. aureus were recovered from 13% of samples. Significantly more skin commensals and pathogens were recovered from samples from days 3, 6, 9 than samples taken upon box opening [2].

Because single-use gloves employed in non-sterile areas come into contact not only with intact skin but also with mucous membranes – e.g., when performing oral hygiene in ventilated patients or during vaginal or rectal examinations – they should be free of potentially pathogenic microorganisms; the quantitative requirements can be based on drinking water limits as well as on requirements for non-sterile medical preparations used in the oral cavity, nose, and ear. For non-sterile medical preparations, the limit is 102 CFU of total aerobic microorganisms/g or mL and 101 CFU of total yeast and moulds/g or mL. S. aureus and P. aeruginosa should not be detectable in 1 g or 1 mL [17]. For P. aeruginosa in drinking water, the requirements are not as strict, i.e., not detectable in 100 mL [18], because as opposed to freshly sampled tap water, the risk of further increase exists in medical preparations. The limit for drinking water, 102 CFU of aerobic bacteria/mL, is also higher. With reference to the requirements for non-sterile medical preparations used in the oral cavity, nose, or ear and to drinking water requirements, the safety of single-use gloves in terms of patient protection can be assumed if no potential pathogens are detectable in 100 mL of rinse sample. Despite the fact that E. faecalis, K. pneumoniae, Pseudomonas spp., and S. aureus were detected on gloves aseptically taken from their box for actual applications [2], we suggest restricting the declaration as pathogen-free (previous term in German: “germ-poor”) to one indicator species each as a typical representative of skin or intestinal flora, i.e., S. aureus and E. coli, respectively. If future studies should demonstrate that this selection is insufficient, the scope of the examination can be broadened at any time. If no potentially pathogenic microorganisms are among the total CFU, the latter is not relevant for patient protection. Nevertheless, it still makes sense to identify the microorganisms in the total CFU because a high load indicates lack of optimal hygiene during the manufacturing process. Taking the requirements for potable water and the findings obtained here into account, the suggested limit of <102 CFU/mL of rinse sample per glove seems realistic.

Properties of single-use gloves declared as PPE

If the wearer is to be protected from chemical and physical risks as well as biological agents (e.g., during work in a microbiological laboratory or care of patients harboring highly pathogenic microorganisms), gloves declared as PPE must be used. To ensure sufficient personal protection of staff, single-use gloves must meet the following requirements [12]:

  • Protective gloves as PPE against chemicals and microorganisms must meet not only the general requirements given in ISO 11193-1 [19], EN 420 [20] – especially in terms of innocuity, ergonomics, resistance to water penetration and pH values between 3.5–9.5 – and EN 455-3 [10] with a protein content <10 µg/g, but also the special requirements related to purpose, e.g., protection from chemicals and microorganisms in accordance with EN 374 [21], [22], [23] and EN 388 [24], as well as mechanical resistance.
  • ASTM F1671-07 provides information on resistance to blood-borne pathogens, e.g., viruses [25].
  • ASTM D6978-05 regulates testing the barrier function against cytostatic agents [26].
  • If protection against chemicals is to be achieved, gloves for high-risk situations (category III of RL 686, recognizable by the CE labeling followed by a 4-digit number) are indicated [27]. For clinical applications, a minimum of PPE category II for protection against moderate risks must be selected. However, PPE category III provides greater protection as well as replicable quality (AQL), which is decisive for the protection expected.

It is recommended to demand a PPE-CE certificate from the manufacturer when acquiring PPE. Labeling as “PPE 89/656/EEC” identifies the product as PPE.

Up to 2010, single-use gloves in healthcare facilities could only be classified according to either the EU Directive on medical products 93/42/EEC or the EU Directive on PPE for Users 89/656/EEC, despite similar properties. Since 2010, the revised EU Directive 2007/47/EC allows dual labeling of products for dual purposes as MDD and PPE, as well as the respective dual CE labeling. Dual-purpose single-use gloves thus bear the CE label “PPE 89/686/EEC” and “MDD 93/42/EEC”. Single-use gloves that are neither MDD nor PPE, and thus do not meet the quality criteria of EN 455 and EN 374, should not be used in the vicinity of patients.


Further considerations for safe usage of hygienic single-use gloves

Even if hygienic single-use gloves fulfill the requirements described above, they do not guarantee patient safety if the following factors are not taken into consideration during and after use:

  • A single-use glove may only be used during care of one and the same patient and must be removed after the given task has been completed. Changing gloves is usually correlated with the indications for hand disinfection, e.g., when switching from contaminated (suctioning secretions) to uncontaminated (operation of infusion system) tasks [28], [29].
  • Disinfecting gloved hands should be the exception, for instance, in situations which demand frequent changing of gloves but experience shows that it is difficult to realize, or in which a change gloves interrupts the work flow, e.g., when switching back and forth between contaminated to uncontaminated tasks on the same patient. In the latter situation, the skin can be damaged if time is short and fresh gloves are put onto hands still moist with alcohol.
  • After taking off the glove, hand disinfection must always be performed; wearing gloves does not guarantee complete protection of hands from contamination, because glove perforation may occur unnoticed and a risk of contamination may arise if the glove is improperly removed from the hand [29], [30].
  • Due to the risk of damaging the skin and an increased risk of perforation [31], single-use medical gloves should only be put on clean, completely dry hands [32].
  • Hand disinfection must be performed if gloves are not available in an automatic glove dispenser or a specially designed cardboard box which, upon removal of a glove, partially exposes the subsequent glove to an extent that enables it to be taken without touching the box or the other gloves.

The glove must meet the following conditions to be able to undergo disinfection [32]:

  • The glove must be certifiably disinfectable (frequency, material tolerance, make of glove, disinfectant) or resistant to chemicals in accordance with EN 374 [22]. If the manufacturer does not provide such information, the user him/herself can test this using one of the intended gloves and the disinfectant by determining the wear perforation rate, for instance, after 5 rounds of hand disinfection as described in [13].
  • The glove exhibits no visible perforations.
  • The glove is not visibly contaminated with blood, secretions, or excretions.
  • Because the perforation rate increases with duration of wear or after physically demanding tasks, gloves worn in the intensive-care area should be changed after a maximum of 15 min and every time a patient is washed, even if all other above-mentioned safety measures have been performed/criteria have been met [33].

Notes

Competing interests

The authors declare that they have no competing interests.


References

1.
Hübner NO, Rubbert K, Pohrt U, Heidecke CD, Partecke LI, Kramer A. Einsatz wiederaufbereitbarer textiler Unterziehhandschuhe für medizinische Tätigkeiten: eine Machbarkeitsstudie [Use of Reusable Textile Undergloves for Medical Procedures: A Feasibility Study]. Zentralbl Chir. 2014 Apr 25. DOI: 10.1055/s-0034-1368205 External link
2.
Hughes KA, Cornwall J, Theis JC, Brooks HJ. Bacterial contamination of unused, disposable non-sterile gloves on a hospital orthopaedic ward. Australas Med J. 2013 Jun 30;6(6):331-8. DOI: 10.4066/AMJ.2013.1675 External link
3.
Kampf G, Ostermeyer C. Intra-laboratory reproducibility of the hand hygiene reference procedures of EN 1499 (hygienic handwash) and EN 1500 (hygienic hand disinfection). J Hosp Infect. 2002 Nov;52(3):219-24. DOI: 10.1053/jhin.2002.1299 External link
4.
Guilhermetti M, Hernandes SE, Fukushigue Y, Garcia LB, Cardoso CL. Effectiveness of hand-cleansing agents for removing methicillin-resistant Staphylococcus aureus from contaminated hands. Infect Control Hosp Epidemiol. 2001 Feb;22(2):105-8. DOI: 10.1086/501872 External link
5.
Donskey CJ. The role of the intestinal tract as a reservoir and source for transmission of nosocomial pathogens. Clin Infect Dis. 2004 Jul 15;39(2):219-26. DOI: 10.1086/422002 External link
6.
Johnson S, Gerding DN, Olson MM, Weiler MD, Hughes RA, Clabots CR, Peterson LR. Prospective, controlled study of vinyl glove use to interrupt Clostridium difficile nosocomial transmission. Am J Med. 1990 Feb;88(2):137-40. DOI: 10.1016/0002-9343(90)90462-M External link
7.
Tenorio AR, Badri SM, Sahgal NB, Hota B, Matushek M, Hayden MK, Trenholme GM, Weinstein RA. Effectiveness of gloves in the prevention of hand carriage of vancomycin-resistant enterococcus species by health care workers after patient care. Clin Infect Dis. 2001 Mar 1;32(5):826-9. DOI: 10.1086/319214 External link
8.
DIN EN 556-1. Sterilization of medical devices - Requirements for medical devices to be designated "STERILE" - Part 1: Requirements for terminally sterilized medical devices. Berlin: Beuth; 2006.
9.
EU Standards for Gloves for Protection against Workplace Hazards. Available from: http://www.chemicalhazardsatwork.co.uk/index.php?option=com_content&view=article&id=17&Itemid=18 External link
10.
EN 455-3. Medical gloves for single use - Part 3: Requirements and testing for biological evaluation. Berlin: Beuth; 2006.
11.
U.S. Food and Drug Administration. Medical Glove Powder Report. September 1997. Available from: http://www.fda.gov/medicaldevices/deviceregulationandguidance/guidancedocuments/ucm113316.htm External link
12.
Arbeitskreis für Hygiene in Gesundheitseinrichtungen des Magistrats der Stadt Wien MA 15 – Gesundheitsdienst der Stadt Wien. Richtlinie Nr. 11: Anforderungen an die Qualität von Einmalschutzhandschuhen in Gesundheitseinrichtungen; Stand: 21. November 2014. Available from: https://www.wien.gv.at/gesundheit/strukturen/hygiene/pdf/hygiene-nr11.pdf External link
13.
EN 455-1. Medical gloves for single use. Part 1: Requirements and testing for freedom from holes. Berlin: Beuth; 2001.
14.
EN 455-2. Medical gloves for single use - Part 2: Requirements and testing for physical properties. Berlin: Beuth; 2011.
15.
EN 455-4. Medical gloves for single use - Part 4: Requirements and testing for shelf life determination. Berlin: Beuth; 2009.
16.
DIN EN ISO 11737-1. Sterilisation von Medizinprodukten - Mikrobiologische Verfahren - Teil 1: Bestimmung der Population von Mikroorganismen auf Produkten. Berlin: Beuth; 2009.
17.
Europäisches Arzneibuch (Pharm Eur). Grundwerk 6.0 (2008) mit Nachträgen 6.1 bis 6.6. Stuttgart: Deutscher Apotheker Verlag; 2010.
18.
Empfehlung des Umweltbundesamtes nach Anhörung der Trinkwasserkommission des Bundesministeriums für Gesundheit. Hygienisch-mikrobiologische Untersuchung im Kaltwasser von Wasserversorgungsanlagen nach § 3 Nr. 2 Buchstabe c TrinkwV 2001, aus denen Wasser für die Öffentlichkeit im Sinne des § 18 Abs. 1 TrinkwV 2001 bereit gestellt wird. Bundesgesundheitsblatt Gesundheitsforschung Gesundheitsschutz. 2005;49(7):693-6. DOI: 10.1007/s00103-006-1294-8 External link
19.
ISO 11193-1. Single-use medical examination gloves - Part 1: Specification for gloves made from rubber latex or rubber solution; Amendment 1. 2012.
20.
EN 420. Protective gloves - General requirements and test methods. Berlin: Beuth; 2010.
21.
DIN EN 374-1. Schutzhandschuhe gegen Chemikalien und Mikroorganismen - Teil 1: Terminologie und Leistungsanforderungen. Berlin: Beuth; 2003.
22.
DIN EN 374-2. Schutzhandschuhe gegen gefährliche Chemikalien und Mikroorganismen - Teil 2: Bestimmung des Widerstandes gegen Penetration. Berlin: Beuth; 2015.
23.
DIN EN ISO 374-5. Schutzhandschuhe gegen Chemikalien und Mikroorganismen - Teil 5: Terminologie und Leistungsanforderungen für Risiken durch Mikroorganismen. Berlin: Beuth; 2015.
24.
DIN EN 388. Schutzhandschuhe gegen mechanische Risiken. Berlin: Beuth; 2014.
25.
ASTM F1671/F 1671M. Standard Test Method for Resistance of Materials Used in Protective Clothing to Penetration by Blood-Borne Pathogens Using Phi-X174 Bacteriophage Penetration as a Test System. West Conshohocken, PA: ASTM International; 2013.
26.
ASTM D6978. Standard Practice for Assessment of Resistance of Medical Gloves to Permeation by Chemotherapy Drugs. West Consohocken, PA: ASTM International; 2013.
27.
DIN EN 374-4. Schutzhandschuhe gegen Chemikalien und Mikroorganismen - Teil 4: Bestimmung des Widerstandes gegen Degradation durch Chemikalien. Berlin: Beuth; 2014.
28.
Pittet D, Dharan S, Touveneau S, Sauvan V, Perneger TV. Bacterial contamination of the hands of hospital staff during routine patient care. Arch Intern Med. 1999 Apr 26;159(8):821-6. DOI: 10.1001/archinte.159.8.821 External link
29.
Doebbeling BN, Pfaller MA, Houston AK, Wenzel RP. Removal of nosocomial pathogens from the contaminated glove. Implications for glove reuse and handwashing. Ann Intern Med. 1988 Sep 1;109(5):394-8. DOI: 10.7326/0003-4819-109-5-394 External link
30.
Korniewicz DM, Laughon BE, Butz A, Larson E. Integrity of vinyl and latex procedure gloves. Nurs Res. 1989 May-Jun;38(3):144-6. DOI: 10.1097/00006199-198905000-00011 External link
31.
Pitten FA, Herdemann G, Kramer A. The integrity of latex gloves in clinical dental practice. Infection. 2000 Nov-Dec;28(6):388-92. DOI: 10.1007/s150100070011 External link
32.
Pitten FA, Müller P, Heeg P, Kramer A. Untersuchungen zur wiederholten Desinfizierbarkeit von Einweghandschuhen während des Tragens. [The efficacy of repeated disinfection of disposable gloves during usage]. Zentralbl Hyg Umweltmed. 1999 Feb;201(6):555-62.
33.
Hübner NO, Goerdt AM, Mannerow A, Pohrt U, Heidecke CD, Kramer A, Partecke LI. The durability of examination gloves used on intensive care units. BMC Infect Dis. 2013 May 20;13:226. DOI: 10.1186/1471-2334-13-226 External link