RESULTSThe mean cutaneous pressure threshold was 0.0680 ± 0.0923 g for skin, 0.411 ± 0.661 g for Ansell gloves and 0.472 ± 0.768 g for Biogel gloves. Skin was significantly more sensitive than Ansell (P. Subjects and MethodsThe primary outcome measures of hand sensitivity were cutaneous pressure thresholds, static and moving two-point discrimination.
Cutaneous pressure threshold was determined using Touch Test™ Semmes-Weinstein Monofilaments (Richardson Products Inc., IL, USA) shown to be an objective and reproducible way of applying pressure., Static and moving two-point discrimination were determined with the Disk-Criminator® (Richardson Products Inc.)., Previously validated techniques were employed, as described by Novak et al.The data were collected between 1 June 2010 to 01 August 2010. The subjects were staff working at the Chelsea and Westminster Hospital in London. All participants gave informed consent; patients were not involved or affected by the study and, therefore, Local Research and Ethics Committee assessment was waived. Measurement of fingertip sensitivity.Pressure thresholds for cutaneous sensitivity were measured using Touch Test™ Semmes-Weinstein Monofilaments (Richardson Products Inc.) applied to the index finger of non-dominant hand. The monofilaments vary with respect to their diameter, which represents the log 10 value of the applied force.
The subject's eyes were covered and the monofilament was gently applied to the fingertip pulp, perpendicular to its surface, until the filament bowed. The smallest monofilament to elicit a response was determined by serial testing, with monofilaments of varying sizes applied in a random order determined by a computerised random number generator.The MacKinnon-Dellon Disk-Criminator® (Richardson Products Inc.) was used to assess both static and moving two-point discrimination. The Disk-Criminator® is a plastic disc with pairs of metal prongs around the circumference; each pair is set with a different distance separating the two prongs. The separation distance of individual pairs of prongs ranged from 8 mm apart to 2 mm apart, each pair varying by a 1 mm increment. Static two-point discrimination was assessed by application of one pair of metal prongs to the fingertip pulp until the subject recognised the stimulus.
The process was repeated for each pair in a random sequence and the smallest gap that could be distinguished as two distinct points was recorded. Moving two-point discrimination was assessed by application of the metal prongs to the fingertip pulp so that the stimulus was felt, then the device was moved proximally in a longitudinal fashion. The smallest interval between metal prongs recognised as two distinct points was recorded.
Cutaneous pressure thresholdsThe cutaneous pressure threshold for skin was 0.0680 ± 0.09231 g (mean ± SD). Cutaneous pressure threshold for Ansell gloves was 0.4107 ± 0.661 g (mean ± SD) and cutaneous pressure threshold for Biogel gloves was 0.4723 ± 0.768 g (mean ± SD).Skin was significantly more sensitive than Ansell ( P. DiscussionThe aim of this study was to provide objective assessment of hand sensitivity and discrimination between comparable single models of sterile surgical glove made at variable cost by competing manufacturers. Two alternative gloves were compared; Gamm ex PF HyGrip® and Gammex PF Sensitive® with Biogel® glove and Biogel Skinsense®.
A mixed multidisciplinary team was used as test subjects, to minimise the potential for bias introduced by surgeons who may have been able to recognise their preferred glove whilst blindfolded. Cutaneous pressure threshold analysis revealed skin was significantly more sensitive than both gloves, but there was no difference between the Biogel and Ansell gloves.
Tests of static and moving 2-point discrimination revealed no significant difference between skin or either glove. Therefore, in the primary outcome measures assessed, the performance of these two surgical gloves was similar. Furthermore, it was not possible to demonstrate a deficit with either glove compared to ungloved skin in terms of 2-point discrimination (static and moving). This demonstrates high levels of tactile feedback available using modern glove technology.Cutaneous pressure threshold was better for skin than for either of the two glove types tested. Deficits in cutaneous pressure threshold could be a risk factor in glove perforation, which has become an area of concern as a number of blood-borne pathogens pose a significant risk to the health of operating surgeons.
In many different specialities, surgeons have advocated using double gloving techniques to limit the danger posed by glove perforation and blood-borne pathogens. The safety advantages incurred are offset by presumed disadvantages including reduced manual dexterity and tactile sensation. However, these disadvantages have been the subject of much debate with a recent paper by Fry et al. Failing to show any significant differences in manual dexterity or tactile sensation associated with double gloving.
The merits and disadvantages of double gloving were not the focus of the present study. However, the relative risk of single glove perforation with competing surgical gloves requires further study. It is likely that this represents one of the many factors differentiating the alternative gloves in the present study that were not analysed.
In addition to cutaneous sensibility and resistance to perforation, other glove characteristics require objective assessment and correlation with surgeon preference, such as grip strength. Such factors are likely to underlie the discrepancy in glove preference seen amongst study subjects despite the lack of a demonstrable difference in the studied outcome measures of cutaneous sensibility or two-point discrimination.Currently, Biogel gloves are more expensive than the Ansell gloves used in this analysis (£1.11 per glove versus £0.71 per glove, personal communication). For a box of standard surgical gloves as used in the present study, the Biogel model is almost twice the cost of the Ansell model (£55.55 versus £28.34).
This represents an important economic consideration, as there was no demonstrable difference between the two glove types in the studied outcome measures. However, the views of surgeons and theatre staff must be taken into account prior to purchasing surgical gloves, and the study revealed a clear discrepancy in favour of the more expensive Biogel model. It is likely that more subtle indices of performance are required to investigate objective differences in performance that underlie the subjective prejudice between these models of glove. Future studies should, therefore, focus on assessment of composite surgical skills rather than isolated measures of sensitivity, to assess the economy of movement and efficiency of operative tasks performed using competing gloves.
Validated operative simulation techniques have been used to generate objective measures of surgical proficiency; the use of these methods may offer a more sophisticated measurement tool for the appraisal of competing surgical gloves. Further research should seek to address this weakness of the present study, which employed relatively crude outcome measures that may not accurately reflect differences underlying the discrepancy in surgeons’ preferences between surgical gloves.Nonetheless, the present study provides the first objective assessment of hand sensitivity between otherwise comparable models of sterile surgical glove made at variable cost by competing manufacturers. The choice of surgical glove remains a balance between cost and clinician preference. Objective data are required to ensure that improvements in cost-efficiency through the use of inexpensive surgical gloves do not compromise patient care through the provision of technically inferior equipment and disregard for clinician preference. ConclusionsNo demonstrable objective difference was found between competing gloves in the outcome measures of cutaneous sensibility and two-point discrimination. However, a difference in subjective preference was noted. Subjective preference is clearly an important factor, which must be taken into account when deciding on bulk purchasing.
Untested factors are likely to underlie this discrepancy, and investigation of a wider range of outcome measures is required to analyse differences between surgical gloves, as measures of cutaneous sensibility alone may not limit surgical performance. Further study is needed to identify more complex objective differences in performance between competing surgical gloves, to ensure cost-savings are not delivered at the expense of patient care.
Fujifilm GFX100OverviewMakerTypeLensSensor/mediumImage sensor typeBayer CMOS43.8 mm x 32.9 mm (medium format)Image sensor makerMaximum11648 x 8736 (102 megapixels)ISO 100-12800 (Ext.