Compiled by Carrie Meadows

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High shear mixer
Millipore Corporation has announced the availability of the new high shear HS T10 mixer. The small size of the HS T10 makes it ideal for use in small production-scale processes and pilot plants in up to 75 L mixing volumes. The newest addition to Millipore’s line of high shear mixers, the HS T10 continues to offer the same advantages that characterize the NovAseptic® mixers. The magnetically coupled design means that there is no shaft led through the tank wall. This reduces the risk of leaks that could challenge the sterility of the vessel. Total integrity of the tank is maintained and there is no risk of contamination. The mixers are bottom mounted, which allows for low-level mixing and easy maintenance. Millipore’s NovAseptic mixers are completely and easily cleanable- and sterilizable-in-place (CIP/SIP).

Millipore Corporation
Billerica, MA
www.millipore.com/bioprocess

Food-grade white grease

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CRC Industries has added food-grade white grease to its complete line of NSF registered products suitable for use in the food processing industry. It is a high-purity, high-quality synthetic grease that provides superior lubrication and durability in many food and pharmaceutical processing applications. Designed for high load applications requiring a long grease life, it protects equipment against rust, oxidation, and wear. Food-grade white grease is NSF H1 registered for incidental food contact; is resistant to water, salt spray, and detergent; and has a wide operating temperature range of 0° to 450°F. This NLGL grade #2 grease resists throw-off and shear breakdown because of its excellent adhesion properties. Food-grade white grease is available in a 16 oz. aerosol can (part no. 03038.)

CRC Industries
>Warminster, PA
www.crcindustries.com/ei

Mini CRDS gas analyzer

Tiger Optics LLC, a manufacturer of laser-based trace gas analyzers, has announced the availability of the Halo™, reportedly the world’s first mini cavity ring-down spectroscopy (CRDS) device. The compact, affordable gas analyzer addresses the need for fast, accurate, calibration-free measurements in the parts-per-billion to parts-per-million range. Based on patented continuous wave (CW) CRDS technology, the analyzer can measure analytes including moisture, methane, acetylene, hydrogen cyanide, formaldehyde, and ammonia. The Halo can also analyze in many challenging matrices, including ammonia, arsine, phosphine, hydrogen bromide, and carbon dioxide. Unlike traditional gas analysis methods, which require consumables and fossil-fuel based standards to verify performance, the Halo enables analysis in real time of even minimal (e.g., ppb) variations while ensuring cleaner, consumable-free operations.

Tiger Optics, LLC
Warrington, PA
www.tigeroptics.com

PVDF exhaust piping system

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Designed specifically to provide a non-corroding, safe system for the conveyance of aggressive exhaust gases and fumes, GF Piping has introduced the SYGEF® PVDF Exhaust Piping System. The new system conforms to FM 4910 (Cleanroom Materials Flammability Test Protocol) standards and is suitable for the latest, state-of-the-art 300 mm semiconductor manufacturing plants as well as applications in the chemical and microelectronics markets. The non-metallic PVDF (polyvinylidene fluoride) material provides a highly inert, high-strength thermoplastic that will not corrode or rust. Available in a complete product range, the new system includes pipe sizes from 2-1/2 to 16 inches (75 to 400 mm) and a variety of fittings, reducers, fixed flanges, gaskets, seals, and throttle valves. Outstanding performance characteristics include UV resistance, a wide operating temperature range from -4° to +284°F (-20° to +140°C), and a vacuum rating of 0.015 bar (0.218 psi).

GF Piping Systems
Tustin, CA
www.gfpiping.com

In-line flow sensors

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SCHMIDT Technology presents a new family of in-line flow sensors. This is a significant improvement of the SCHMIDT program of flow sensors, which previously consisted of immersion-type flow sensors. These sensors come with their own measuring pipe, thus giving direct display of the volume flow. Contrary to immersion sensors, the inline sensors simplify the mounting, reduce the influence of mounting tolerances, and the measuring pipe is part of the adjustment process. This new product family consists of four sensor models in pipe sizes of 1/2, 1, 1-1/2, and 2 inches. Actual volume flow, totalized volume flow, and media temperature can be viewed from the LED display. Two keys allow configuration of the sensor functions. Output 1 may be configured as switching or analog output; output 2 may be used as pulse output or second switching output. The sensors are appropriate for compressed-air consumption measurements, volume flow measurements in test benches, flow measurements in nitrogen or other passivation gases, and flow measurements in process gases.

SCHMIDT Technology GmbH
St. Georgen, Germany
www.schmidttechnology.de

Mass spectrometer for leak detection, gas analysis

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Pfeiffer Vacuum, a leading producer of vacuum products and services, offers PrismaPlus, a new mass spectrometer for qualitative and quantitative gas analysis and leak detection. With the ability to select mass ranges, detectors, ion sources, and interface options, this mass spectrometer can be employed in many areas, such as industrial and analytical environments, R&D, leak detection and semiconductor production, and coating technology. The PrismaPlus delivers precise and stable results in three different mass ranges (1 to 100, 1 to 200, and 1 to 300 amu) down to a detection limit of 1×10^-14 mbar. With available Faraday and electron multiplier detectors, even low-level contamination in the vacuum system can be quickly identified.

Pfeiffer Vacuum, Inc.
Nashua, NH
www.pfeiffer-vacuum.com

Electronically commutated fans

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Rosenberg has introduced a family of compact, radial fans with free-running impellers and variable speeds that combine electronically commutated (EC) external rotor motors with newly developed integrated power electronics. Models GKHR and GKHM feature long-life, low-temperature “brushless” DC motors controlled by maintenance-free electronic circuitry. GKHR fans are motorized impellers, mounted and balanced, that may be provided with or without an inlet cone. GKHM fans are complete fan modules. The fans’ external rotor design and high power density make them ideal for use in ventilation and air conditioning applications. Unlike conventional DC motors, the new Rosenberg EC motors deliver highly efficient, low noise performance without using collectors and carbon brushes that wear out and shorten motor life.

Rosenberg USA
Charlotte, NC
www.rosenbergusa.com

Handheld pressure calibrator

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The compact JOFRA™ DPC-500 is the latest handheld pressure calibrator from AMETEK Calibration Instruments. The DPC-500 offers user-friendly, high-precision calibration of pressure gauges, transmitters, and switches as well as digital manometers and overpressure protection valves. The DPC-500 has a separate reference pressure sensor that can be fixed to the instrument or used “off instrument” via a cable. Up to five interchangeable reference sensors of different pressure ranges may be used with any one instrument. The calibrator offers excellent pressure, current, and voltage accuracies along with an extended pressure range of 250 mbar to 1,000 bar FS. Absolute pressure measurement also is offered. Since many calibration errors are caused by conversion of pressure units, the DPC-500 features 15 predefined units (bar, mbar, hPa, psi, inHg, cmHg, MPa, kPa, Pa, mH2O, cmH2O, mmH2O, Kg/cm2, InH2O, mmHg) together in one user-definable unit.

AMETEK Calibration Instruments
Albany, NY
www.jofra.com

On-line sodium analyzer

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Hach Company’s 9245 On-Line Sodium Analyzer is designed for boiler/steam generation and cooling water applications. Measurement of sodium concentration, recognized as an important index for water quality control, enables plant chemists and utilities managers to monitor several critical areas of their process to optimize performance. Monitoring indicates possible stress corrosion of the super heater, gives early warnings of excursions on condensates, detects hydroxides and chlorides that contribute to the stress corrosion of austenitic steel, helps manage ion exchange resin, and ensures the quality of de-mineralized water delivered to the makeup plant. The 9245 provides a detection limit of 0.01 ppb and measures in the range of 0 to 10,000 ppb. Calibration solution reagents and electrolyte only need to be replaced every 100 days for minimal maintenance.

Hach Company
Loveland, CO
www.hach.com/power

Low-outgassing dielectric gels for electronics packaging

NuSil Technology, a manufacturer of silicone-based materials for healthcare, aerospace, electronics, and photonics, has added three low outgassing, dielectric gels to its electronic packaging materials line. NuSil’s EPM-2480, EPM-2481, and EPM-2482 were designed for the encapsulation of chip packages in devices where outgassing-related contamination poses a problem. EPM-2480 and EPM-2481 are based on dimethyl silicone systems; the EPM-2480 is a lower-viscosity, firmer gel than the EPM-2481. Both are two-part systems and are supplied in 50 g and 50 ml side-by-side kits. The EPM-2482 is based on a diphenyl dimethyl silicone system for added temperature stability and is also supplied in 50 g and 50 ml side-by-side kits.

NuSil Technology
Carpinteria, CA
www.nusil.com

Programmable process control device

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Avery Weigh-Tronix, LLC, has introduced the newest version of its Model 1310 Indicator/Controller, an advanced weighing and process control device that can be fully programmed to fulfill virtually any industrial application requirement. The device can be used in food processing (filling and recipes) and chemical plants (filling, blending, and batching), for example. The Evolution E1310 is also faster and more flexible than its predecessor. It can function as a stand-alone control system or can be fully integrated with all major networks and SCADA systems. In addition, the E1310 can be programmed to automatically report scale or indicator error to the Avery Weigh-Tronix technical service center via an optional modem connection or industrial network. Technicians can then communicate with the indicator to evaluate the status and determine remedial action without having to visit the site.

Avery Weigh-Tronix, LLC
Fairmont, MN
www.wtxweb.com

Temperature recorder with new vented case

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DeltaTRAK, Inc., a leading manufacturer and provider of portable environmental test instruments and cold chain management solutions, announces the new In-Transit Temperature Recorder specially engineered with a lighter but durable vented case for superior air circulation and faster temperature response. The new DeltaTRAK Single Use In-Transit Temperature Recorders, 16000 series models, are available in five-day to 90-day transit periods. The recorders can be used to document the environmental temperature conditions encountered during storage and transportation of food, pharmaceuticals, chemicals, and other temperature-sensitive commodities.

DeltaTRAK, Inc.
Pleasanton, CA
www.deltatrak.com

Popular reagent reservoir redesigned

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Excel Scientific has announced that product revisions are complete and the popular Texan™ Reagent Reservoir is available for immediate delivery. The basic design of the Texan’s large V-shaped basin is compatible with both eight-channel and 12-channel multi-well pipettors. Improvements include volume graduations that are extended to 150 mL, a more rigid base that avoids spills by not wobbling, an easy-open latch that can be manipulated with one hand, and increased clarity for reagent visibility. Texan reservoirs are available sterile or non-sterile, with or without the hinged protective cover.

Excel Scientific, Inc.
Wrightwood, CA
www.excelscientific.com

High-capacity chilling/ heating dry baths

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Torrey Pines Scientific, Inc. has announced its new EchoTherm™ high-capacity chilling/heating dry baths. The IC30 (-10° to +100°C) and IC30XT (-20° to +100°C) can freeze, chill, or heat samples in a variety of sample blocks. Blocks are available to hold 0.5 to 50 ml centrifuge tubes, test tubes, vials, assay plates, and even round-bottom flasks. The units can freeze, chill, or heat 64 1.5-ml centrifuge tubes, nine 50-ml centrifuge tubes, or even four 250-ml flasks. The units measure 8.5x10x4 inches (21.6×24.5×10.2 cm). They come complete with chiller/heater module, universal power supply, AC line cord for the country of use, and an instruction manual. They are UL, CSA, and CE compliant.

Torrey Pines Scientific, Inc.
San Marcos, CA
www.torreypinesscientific.com

Wiper packaging

The QuickPick Packaging from Contec addresses two expensive problems in one convenient package: wiper waste and proper wiping technique. The packaging uses a convenient, blue dispenser bag as the inner-most package for the Polynit Heatseal wipers, which are half-folded with the folded edge easily accessible through the dispensing hole. QuickPick Packaging promotes proper protocol for critical wiping operations, eliminates operator time in folding wipers, and reduces cross-contamination from gloves in the folding process.

Contec, Inc.
Spartanburg, SC
www.contecinc.com

Serviceable in-line filters

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A new line of in-line filters from Industrial Specialties Mfg. provides fast, easy serviceability. The filter cartridge is easily visible through the clear, polycarbonate housing; a quick twist of the bayonet-style fastener separates the housing components for cartridge cleaning or replacement. Cartridges are available in a range of filter microns in both porous and plastic cone design. The standard ends are 3/16-inch I.D. barbs, but optional threaded fittings are available. Ends can also be provided in male and female luers and elbows. The filters will operate in air, vacuum, and some fluid applications.

Industrial Specialties Mfg., Inc.
Englewood, CO
www.industrialspec.com

Downflow workstations

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The New DWS range of downflow workstations from Air Science offer operator safety and cost reductions. The units operate at low noise levels, and, because they recirculate, they do not exhaust expensive conditioned and/or heated air into the atmosphere. The DWS workstations have been designed to provide a small bench-mounted unit with unrestricted access for those operations that are difficult to perform in a conventional fume hood. To provide protection, the downflow action takes the contaminated air away from the operator; an alarm will sound when the airflow falls to an unacceptable level. The main filter can be chosen from 14 different types of carbon, which include specialty media for vapors of organics, solvents, acids, mercury, and formaldehyde. HEPA filters for particulate filtration are also available to suit the application.

Air Science USA
Fort Myers, FL
www.air-science.com

New Literature

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Flooring systems
Valspar Flooring, a division of Valspar Corporation, has published a multi-page guide highlighting the advantages of its floor and wall systems specially engineered for the food and beverage industry. The brochure details Flowfresh® and Descoglas® systems. Flowfresh heavy duty urethane concrete, a product of Flowcrete PLC, has been installed on millions of square feet of concrete flooring around the world. Featuring Polygiene®, a non-chemical silver ion-based antimicrobial, Flowfresh is available in light- to heavy-duty formulas in a variety of colors. Descoglas reinforced wall and ceiling systems offer smooth, seamless environments by wrapping or tying the wall and ceiling into the floor and base and by rounding inside corners, eliminating the cracks and crevices that harbor dirt and bacteria. For a free copy of the brochure, please call 1-800-637-7793 or visit the company’s web site.

Valspar Flooring
Wheeling, IL
www.valspar.com

Materials, equipment approval guide

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Product testing and certification organization FM Approvals, a nationally recognized testing laboratory, has published its comprehensive “2007 Approval Guide” on CD-ROM. The guide provides the most up-to-date, detailed engineering data and technical information on the application and use of more than 45,000 FM-approved fire protection products, building materials, and electrical equipment and services that best prevent property loss. The CD-ROM also contains more than 140 Approval Standards documents, indicating the rigorous testing criteria products must meet to become FM-approved. For more information, call 1-877-364-6726 (toll-free in the U.S. and Canada) or 1-781-255-6681 (other countries) or visit the web site.

FM Approvals
Norwood, MA
www.fmapprovals.com

Manufacturing technology supplier directory

Manufacturers investigating solutions for microsystems technology, nanostructured materials, or automation with microcomponents will quickly find the appropriate suppliers in their vicinity or other regions through the IVAM directory online. The directory is accessible at www.ivam.de. With the help of a new search function, prospective customers can filter the profiles of about 220 international high-tech suppliers and research institutes in the field of micro- and nanotechnology for technologies, markets, and countries. Special products and applications can be found through a keyword search. The new filtering function accelerates the navigation through the profiles of the member companies and institutes of IVAM on the association’s web site, the number of which constantly increases.

IVAM-Microtechnology Network
Dortmund, Germany
www.ivam.de

HVAC duct inspection

The Sheet Metal and Air Conditioning Contractors’ National Association (SMACNA) has published the revised third edition of the “HVAC Duct Systems Inspection Guide.” The guide reviews materials and reinforcement of duct systems, as well as assembly and support of ducts. It also contains guidelines for the inspection of commercial HVAC duct systems for compliance with SMACNA/ANSI “HVAC Duct Construction Standards-Metal and Flexible,” third edition, and “Fibrous Glass Duct Construction Standards,” seventh edition. To order, call SMACNA’s Publications Department at 1-703-803-2989 or visit the web site.

SMACNA
Chantilly, VA
www.smacna.org/bookstore

A novel new air purification technology has been developed to help battle infection in hospitals and other healthcare settings. The patented technology integrates with existing building HVAC and mechanical filtration systems to effectively remove airborne bacteria, yeasts, molds, and viruses.

Currently operating with the temporary product name “PureAir,” under the auspices of Leap Enterprise and Investments Ltd. (Richon Le Zion, Israel), the system uses a unique absorption system composed of an aqueous solution of mineral salts (oxidant brine) passed through an electrolytic cell to increase its redox potential (300 to 450 mV). Air is passed through the solution where biological contaminants are absorbed and denatured. The system can treat indoor air volumes at the rate of 2,000 cubic meters per hour.

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The system is the brainchild of David Itzhak, PhD, associate professor in the Materials Engineering Department at Ben-Gurion University of the Negev in Beer-Sheva, Israel. As he explains, his original interest first arose as the result of first-hand experience with foul-smelling air while awaiting treatment in a hospital facility several years ago. Using his background and experience with water purification technology, he would later develop the prototype air purification system and arrange with a group of physicians at a major Israeli hospital to conduct a feasibility study.

The eight-month beta-site trial, conducted in the hospital’s pediatric ICU (approximately 700 m³), demonstrated an 80% reduction in CFUs. As noted by Itzhak, the efficiency percentage will vary according to the level of control maintained in the environment, such as the number of times doors are opened. On average, when running continuously, the typical result after three hours was 70% and continued to improve over time.

Separate in vitro testing was also conducted to determine the system’s specific effectiveness against viruses. The results showed major reduction (five orders of magnitude) of both polio and adenovirus. Says Itzhak, “Unlike mechanical filtration systems, the chemical absorption process is actually more effective as particles become smaller.”

The PureAir beta test system installed at a major Israeli hospital is attached to an AC conduit. Photo courtesy of Leap Enterprise and Investments Ltd.Click here to enlarge image

The company is now actively marketing the product and technology worldwide. In the next six months, three hospitals in the United States will be installing and evaluating the system. An independent testing laboratory will conduct testing over a three-to-five month period with the results expected to be published within a year. Additional hospitals are also being sought to participate in the program.

Meanwhile, in the next few weeks, the Israeli agriculture ministry will be conducting studies on the effectiveness of the system for controlling avian flu at poultry farms and as an alternative to chlorine dioxide treatment for food preservation.

compiled by Carrie Meadows

Asyst reels in multiple 200 mm orders
Asyst Technologies, Inc., a leading supplier of integrated automation systems for semiconductor and flat-panel display manufacturing, has announced that its 200 mm products have been selected by multiple semiconductor fabs including EM Microelectronic of Switzerland, Shanghai Huahong NEC Electronics Co., Ltd. (HHNEC) of China, and additional semiconductor fabs in China and Russia. The aggregate multi-million dollar orders include SMIF loadports, indexers, and wafer stockers. SMIF products have better than ISO Class 1 particle performance, low cost of ownership, and improved tool utilization.

Avecia OligoMedicines expands manufacturing capabilities

Avecia OligoMedicines will be expanding its Milford, MA, manufacturing facility, further extending its capabilities in siRNA and aptamer manufacturing. The company has installed new cleavage deprotection vessels and equipment to enable large-scale siRNA manufacture in batch sizes of 75 to 100 mmol. The facility upgrade also includes two new chromatography skids and associated equipment, enabling high pressure/high temperature purification, and new duplexation/annealing vessels to enable controlled siRNA duplexation in batch sizes up to 150 mmol. Additionally, large-scale conjugation/pegylation capacity has been installed covering the range up to 100 mmol. The new equipment and facilities are expected to be online by September 1.

DuPont introduces FDA-compliant PLA modifier for food packaging

DuPont Packaging has announced expansion of its DuPont™ Biomax® Strong family of polymer additives to include an FDA-compliant grade for food contact applications. New DuPont™ Biomax® Strong 120 is a polymer additive that toughens bio-based polylactic acid (PLA) packaging materials while maintaining compliance with food contact requirements in the United States and in Europe. A similar additive was introduced in August 2006 for non-food applications. Both grades of Biomax® Strong provide improved toughness performance with minimal reduction in package clarity.

Mass. Governor pledges $1B in biotech funding over next decade

At last month’s 2007 BIO International Convention in Boston, MA, Governor Deval Patrick proposed a “Life Science Strategy” that calls for $1 billion in funding over the next 10 years for biotech research, which includes a plan to establish a stem-cell bank. Patrick indicated that the program is intended to fill gaps left by reduced funding from the National Institutes of Health. According to a release from the Governor’s web site, approximately $500 million would go toward the purchase of new equipment for higher education and other institutions, which could be shared with firms in the life science industry. Another $250 million would be allocated for research grants, training, and other initiatives, and $250 million would go toward matching grants for fellowships and research. It is estimated that $250 million will come in the form of tax benefits.

Commissioner of Food and Drugs Dr. Andrew C. von Eschenbach has announced the creation of a new Food and Drug Administration (FDA) position-assistant commissioner for food protection-to provide advice and counsel to the commissioner on strategic and substantive food safety and food defense matters.

David Acheson, M.D., F.R.C.P., is the first to be assigned to this senior leadership role, reporting to Dr. Murray Lumpkin, deputy commissioner for international and special programs. Acheson serves as chief medical officer and director of the Office of Food Defense, Communication and Emergency Response at FDA’s Center for Food Safety and Applied Nutrition (CFSAN). In his new role, Acheson will work with individual FDA product centers, as well as the Office of Regulatory Affairs to coordinate FDA’s food safety and defense assignments and commitments.

The agency says Acheson will also serve as the commissioner’s direct liaison to the Department of Health and Human Services, of which FDA is a part, and to other U.S. departments and agencies on food safety and food defense related inter-agency initiatives.

“The protection of America’s food supply and therefore the safety of Americans eating food of domestic or international origin is of utmost importance to me as a physician, and to the mission of this agency,” von Eschenbach says. “We’ve seen a rapid transformation of the food safety system due to advances in production technology, rapid methods of distribution, and the globalization of food sources. Dr. Acheson’s wealth of experience, and knowledge of the science behind food protection, will help the agency keep pace with this transformation in order to ensure that the safety and nutritional value of our food supply is second to none.”

One of Acheson’s first assignments will be the development of an agency-wide strategy for food safety and defense that will identify and characterize changes in the global food safety and defense system, and identify current and future challenges and opportunities. It will also name potential barriers, gaps, and the most critical needs in a food safety and defense system.

As a CFSAN office director, Acheson currently has the lead for emergency response, as well as outreach and communications to industry, state, and consumers on issues pertaining to the center. He manages a staff of epidemiologists, biostatisticians, and others in providing risk assessments, aid in epidemiological investigations of foodborne illness outbreaks, and other important center-wide functions.

Air Liquide Electronics, a leader in industrial and medical gases and related services, and Aviza Technology, Inc., a supplier of advanced semiconductor capital equipment and process technologies for the global semiconductor industry and related markets, have extended their joint development agreement (JDA). The JDA, which now has been extended through 2010, centers on advanced films and process development for semiconductor fabrication. The original agreement between the two companies was announced on April 4, 2005.

“We joined forces with Aviza as a partner for innovative materials development and integration so that we could offer chipmakers manufacturing-worthy process solutions to meet their roadmap requirements,” says Christophe Fontaine, vice president of Air Liquide Electronics. “The JDA has proven to be a mutually beneficial partnership for both companies and we look forward to continuing our development efforts with Aviza.”

Continuous integrated circuit (IC) device scaling poses certain critical manufacturing challenges, with new materials playing an integral role in successful sub-90-nm IC production. Ongoing industry collaboration is important for early development of process and technology solutions to overcome these next-generation challenges. Aviza and Air Liquide’s collaborative partnership enables the companies to combine their knowledge in the areas of advanced films, process technology, and hardware to help address deposition challenges for increasingly smaller and more complex IC devices.

As part of the JDA, Air Liquide’s ALOHA™ organization will produce the chemicals, perform the associated analyses and characterizations, and evaluate them through its Precursor Screening Program when necessary. Aviza will use selected precursors in developing fully characterized films to support advanced applications for sub-90-nm manufacturing.

“To date, Aviza has experienced quite a successful collaborative partnership with Air Liquide,” says Helmuth Treichel, vice president of advanced applications at Aviza. “Both Aviza and Air Liquide have benefited from our ongoing JDA and we feel there is much more opportunity to expand and enhance our research and development efforts by working with industry experts like Air Liquide in the materials arena.”

The clamor over the requirements of USP <797> is abating, but many pharmacies and healthcare facilities still feel they are being caught short in terms of the scientific, financial, and physical resources needed to comply with the standard.

By Bruce Flickinger

Compounding pharmacies, particularly those compounding sterile products, are increasingly under the regulatory eye. Once governed by a hodgepodge of state regulations, the industry has seen USP Chapter <797>: Pharmaceutical Compounding-Sterile Preparations emerge from an amorphous effort to standardize practices to the de facto industry standard in just a few years. Now there is the specter, albeit distant, of the Safe Drug Compounding Act, a draft Senate bill that would place the federal government (namely FDA) firmly in both the compounding pharmacy and the physician’s office. At press time, the bill had not been introduced and written comments were being received from numerous industry and special interest groups.

Preferring the carrot over the regulatory stick, the compounding pharmacy industry, and the healthcare community as a whole, is moving aggressively to police itself. While USP <797> is somewhat in flux, many of those affected by it are already girding for its impact instead of watching it develop and waiting for a clear mandate to comply. One manifestation of industry initiative is the Pharmacy Compounding Accreditation Board (PCAB), a group formed in 2004 to provide a profession-wide system of standards by which individual compounding pharmacies can test their quality processes.

Formed by six national pharmacy organizations, along with the National Association of Boards of Pharmacy and United States Pharmacopeia (USP), the PCAB tests and accredits pharmacies against standards, and notifies the public about which pharmacies have achieved accreditation. Thirteen pharmacies have been accredited to date, and about another 100 are currently undergoing the process. “We’re seeing a lot of enthusiasm,” says Ken Baker, executive director of the PCAB, based in Washington, DC. “Pharmacies want a set of national standards that they can meet voluntarily.”

Clearly, the intentions behind such efforts are good, but realistically, 13 accredited pharmacies nationwide is not a substantive number. And while many more quality-focused compounding pharmacies abound, the call has gone out from all invested parties for a tangible, nationally recognized mechanism that details the way sterile and high-risk pharmaceutical products should be compounded to optimally protect the safety and health of both patients and workers. USP <797> is the critical cog in this mechanism.

It’s easy to say that there’s much grumbling about the standard, but Baker is not seeing much consternation about USP <797> among the pharmacies pursuing accreditation. “Most of them already considered it to be a nationally recognized standard and were in the process of meeting the requirements,” he says. “There was some confusion when the standard first came out, but it’s been a long time since I’ve heard any complaints about USP <797>.” He is not alone in this observation.

“National standards like USP <797> will always be moving targets,” Baker adds. “There will always be revisions and changes, and pharmacies will have to meet them.”

Doing so is not a simple matter. As for PCAB accreditation, which requires compliance to USP <797> for pharmacies doing sterile compounding, Baker minces no words in saying it is “not an easy process. There are 10 standards to be accredited to and the pharmacy has to meet all 10 of them.” Following accreditation, there is a yearly application renewal and an on-site visit every three years. The revisit can take place before the three-year period if the application renewal reveals significant change in a pharmacy’s operations.

The pharmacy visit, called a survey, looks at two elements: what the pharmacy says it is doing and whether it is actually doing what it says it is. “We’ll follow back a filled prescription to see the process it went through to get there,” Baker says. “What a pharmacy is doing on a given day is just that: a snapshot of their operations. We need to see the policies and procedures that say they’ll be doing the same thing six months from now, or when new technicians are hired and trained.”

Figure 1. A technician at McGuff Compounding Pharmacy Services prepares an injectable drug solution. McGuff is located in California, where pharmacies that compound injections are required to have a license and are inspected by specially trained pharmacy inspectors. Photo courtesy of McGuff Compounding Pharmacy Services.Click here to enlarge image

Baker acknowledges that, for many, it is expensive to meet the equipment and infrastructure upgrades called for in USP <797>. But if it’s too expensive to do so, he says, “then you ought not to be compounding. Come back when you can meet the standards.” He adds, “We’re already seeing pharmacies getting out of the business of sterile compounding because they don’t want to make the necessary investments to comply.

“Part of our mission statement is to bring everyone up to meet quality standards,” Baker says. “Free enterprise will decide who remains in business and who doesn’t. The public should be able to decide the best place to take their prescriptions.”

Up to par

One place that patients can feel confident about their compounded prescriptions is McGuff Compounding Pharmacy Services, in Santa Ana, CA. One of the first pharmacies in California to earn PCAB’s Seal of Accreditation, McGuff is a state-of-the-art, ISO-accredited pharmacy with seven pharmacists on staff. It produces a variety of medications, including sterile injections, troches, capsules, creams, suppositories, gels, solutions, and suspensions. Compliance to USP <797> has long been part of the company’s quality assurance program.

“For our business, USP <797> simply represents what we have been doing from the beginning: good compounding practices,” says director of pharmacy services William Blair, Pharm.D. He advises pharmacies that might be holding off on facing up to USP <797>, “The best strategy is to work with knowledgeable people and get it done. The key to success will be fully understanding the regulatory, engineering, and quality concepts for CSP [compounded sterile preparation] compounding.”

Blair shares the opinion that the fuss about the financial outlay involved in USP <797> compliance is largely misplaced. He feels the standard offers options for pharmacies to overcome budgetary, space, and structural constraints to meet the requirements. “If pharmacies and physician offices cannot comply with the stated standards, they should not be in the business of compounding sterile drugs,” Blair says.

He cites as one example the fact that the standard does not mandate the use of barrier isolator systems, as some people erroneously believe, but rather indicates that unidirectional, laminar airflow workbenches (LAFWs) are equally suitable for CSP work. “So, USP strikes a balance between current accepted practice [LAFW in an ISO 7 buffer zone] and emerging technology [compounding aseptic isolator systems],” Blair says. “In either case, USP provides guidance on the proper use, precautions, and personnel interactions with the indicated engineering controls.”

Clyde Buchanan, an Atlanta-based pharmacy consultant and expert on compounding sterile preparations, points out further means to mitigate the costs involved with compliance: the “judicious use” of compounding aseptic isolators (CAIs); centralizing sterile drug compounding in pharmacy; taking advantage of USP’s “immediate use” exemption and proprietary vial and bag systems; and outsourcing selected types of sterile drug compounding.

Equipment and environmental controls alone cannot ensure a safe, sterile product. Quality systems and properly trained technicians are key ingredients as well and are addressed in USP <797>. Numerous quality procedures and safeguards are in effect at McGuff. For a sterile compounding operation, vials are first washed in a multi-step, validated wash process and receive a final rinse with water for injection. The wash process is accomplished and controlled using qualified equipment and SOPs. Washed vials are then depyrogenated in a validated depyrogenation process. During aseptic filling, the compounded medications are passed through a bacterial retentive filter into the vial in an ISO 5 environment. As appropriate, a layer of sterilized nitrogen gas is placed on top of the liquid. A sterile stopper septum is then inserted and an aluminum seal is crimped to secure the stopper to the vial.

Samples of the finished medication are then sent to the chemistry and microbiology labs to be tested for foreign matter, potency, endotoxins, and sterility. If all results come back within acceptable limits, the finished medication is dispensed according to the indicated prescription.

“Our quality systems department ensures that all policies and procedures are current and effective, and are being used,” Blair says. “This department performs the finished medication testing and will release the finished medications if test results are within acceptable limits.” The quality department also performs environmental testing and ensures that all operators maintain their skills. Audits are conducted of the compounding processes. All employees receive extensive training in quality systems, current good manufacturing practices for pharmaceuticals, good compounding practices, and individual SOPs for which they are responsible.

“Training is extremely important and is a continual process at McGuff,” Blair says.

Protecting patients and pharmacists

Personnel training and protocol, and equipment and environment are both critical to the safe compounding of pharmaceuticals.

“Technique is the most important piece of sterile compounding, be it a chemo/HD [hazardous drug] or any sterile product,” says Luci Power, senior pharmacist and manager of Parenteral Support Services (PSS) at the University of California Medical Center-San Francisco (UCSF). “All individuals involved in any aspect of sterile or chemo/HD compounding must understand the issues and the systems in place to protect the compounder and the ancillary personnel in the areas.”

Power oversees a robust training and continuous monitoring program. One component: Technicians set up their batch or dose, but nothing is injected into the final container until a pharmacist checks the drug, diluent, final container, label, all calculations, etc. Once this check has been done, the technician can complete the compounding process. “This immediate supervision and direct observation is crucial to ensure that proper handling precautions are constantly in place. It’s a safety measure for the patient as well as the personnel,” she says.

Figure 2. Sterile fill operation at McGuff Compounding Pharmacy Services. Photo courtesy of McGuff Compounding Pharmacy Services.Click here to enlarge image

While Kenneth Mead, research mechanical engineer with the National Institute of Occupational Safety and Health (NIOSH), concurs protocol and operator technique are of primary importance, he also believes part of that protocol and technique should include the use of properly selected engineering controls. “The best engineering control designs will provide an environment that reduces the probability of an adverse outcome when proper technique is not perfectly followed, and will do so without sacrificing the ability to reasonably conduct the work task,” he says. That being said, however, “improper technique can work counter to the protective benefits provided by engineering controls, and if the work practice is sufficiently poor, even the best engineering control design won’t help.”

Mead was involved with developing the NIOSH Safety Alert, “Preventing Occupational Exposure to Antineoplastic and Other Hazardous Drugs in Health Care Settings,” published in September 2004. Although the document does not carry regulatory weight, it incorporates the principles of USP <797>. Among its recommendations: “Prepare hazardous drugs in an area that is devoted to that purpose alone and is restricted to authorized personnel,” and “limit access to areas where drugs are prepared to protect persons not involved in drug preparation.”

These recommendations are based on evidence that potential acute and chronic health effects associated with occupational exposure to hazardous drugs, notably chemotherapy and antineoplastic agents, can be very serious, Mead says. Even with the protection of properly selected primary engineering controls, “the potential for exposure still exists due to accidents, surface contamination on products and packaging, equipment malfunctions, or lapses in proper work practice,” he says.

Not only are there concerns for the exposed worker who is handling the hazardous drug, but in a multi-occupant, multi-task environment, there is potential for secondary exposure of individuals who may not be aware of the risk. “Intervening steps that reduce or eliminate that opportunity for exposure should be considered,” Mead says. “By designating this work to occur in a specified, well-marked, access-controlled area, you reduce the number of persons potentially exposed and increase the hazard awareness of the individuals involved in hazardous drug compounding.”

This awareness extends beyond pharmacy personnel. Power, who is a member of the NIOSH Hazardous Drug Working Group that helped develop the NIOSH Alert, says there is ample evidence of hospital staff, including janitors and housekeepers, having a drug in their urine that they obviously did not mix or administer. “We think that this is touch contamination spread through contact with personnel, but a number of these drugs vaporize into the air and these could be moved through positive-pressure air handling systems,” she says. In addition, “contaminated aerosols or particles, such as in packaging or from a spill, pose a threat in a positive-pressure, recirculating environment,” even where isolators are in use.

Figure 3. The HWI cleanroom compounding facility at the University of Pittsburgh Medical Center’s Braddock campus. From top: the anteroom; open-architecture compounding zone; and detail of the return-air wall behind the work area. Photos courtesy of HWI, LLC.Click here to enlarge image

Power is adamant that, aside from protecting patients, stringent containment controls are necessary to reduce worker exposure to hazardous drugs. With regard to product safety, the overarching recommendation for sterile compounding, she says, has been “a positive-pressure, recirculating environment that blows out of the compounding suite into the surrounding areas, and that the LAFWs are effectively sucking all the room air through their HEPAs.” However, hazardous drugs are another matter entirely, and this type of environment would allow for contamination of all equipment, supplies, and personnel if there is any contamination coming out of the primary control. “There are numerous published studies that document this surface contamination in chemo/HD compounding areas. A few of them tracked chemo/HD on floors and out into adjacent areas, onto carts, phones, computer terminals, and the like,” Power says.

Equipment options

The two infrastructure requirements in USP <797> generating the most comments and questions are 1) that rooms or areas for compounding chemotherapy and other hazardous drugs be segregated from the main cleanroom area; and 2) that barrier isolators-referred to as compounding aseptic isolators in USP nomenclature-do not, in themselves, provide adequate assurance of sterility and must be placed in an ISO 7 environment.

Buchanan is straightforward in addressing these areas of concern. He says that proposed changes to USP <797> require that hazardous drugs be compounded in a negative-pressure buffer room, while non-hazardous drugs must be compounded in a positive-pressure buffer room. Further, if the manufacturer of a CAI can prove that the isolator provides complete separation from the surrounding environment during dynamic operations, the isolator does not have to be placed in an ISO 7 cleanroom. “If the isolator is dedicated to hazardous drug compounding, it cannot be in the same room with other primary engineering controls used for non-hazardous drugs,” he adds.

Figure 4. A pharmacy technician loads pharmaceutical stock into the RIVA automated station. Photo courtesy of RIVA Systems.Click here to enlarge image

One point of interest, particularly for equipment manufacturers, is that USP is focused on assessing and qualifying equipment performance in operation-not just out of the box or at the factory. “USP is interested in dynamic operating conditions,” Buchanan says. “This is the best way to validate that the compounding system as a whole works according to a user’s expectations. You want to know how the room performs while the work is actually being done.

“Manufacturers of compounding aseptic isolators embraced the first version of USP <797> because it tended to encourage the use of isolators as alternatives to building cleanrooms,” Buchanan says. “But I am not aware of any makers of compounding aseptic isolators that have advertised that their units provide complete separation from the surrounding environment during dynamic operations.”

Isolation or open architecture

In many respects, which primary engineering control to use-a LAFW or a CAI-is the key guide to budgetary and engineering decision making for most compounding operations. Uniform equipment testing standards have not yet been adopted industry wide, although testing guidelines have been advanced by several associations and industry groups, such as the Controlled Environment Testing Association.

“I believe most, but probably not all, of the available CACIs [compounding aseptic containment isolators] currently on the market would meet the performance recommendations in the NIOSH alert,” Mead says. “The response among equipment manufacturers has been terrific in quickly bringing effective CACIs to the marketplace. The main thing lacking at this point is a uniform performance or testing standard by which all CACIs would be evaluated.” Such a standard ideally would address both the containment issues of the NIOSH alert as well as the asepsis requirements of USP <797>.

Power opines, “There is no question that isolators require more technician training and constant monitoring of work practices, and are not as efficient as open workstations.” However, “barrier isolators can prevent some of the corner cutting that compounders can get away with in open workstations. They enforce organization and prevent jumping from one task to another.” A technician at a biological safety cabinet (BSC), for example, can stop to answer the phone and then go back to compounding without cleaning their gloves; this couldn’t happen with an isolator because the gloves are attached to the unit. On the other hand, “the gloves in an isolator must be changed regularly and this is an expense as well as a potential breach of the integrity of the equipment,” Power says.

“Barrier isolators are a good technology when they are truly necessary,” says Daniel Jacobs, executive director of Haddad-Wylie Industries, LLC (HWI), in Pittsburgh, PA. “Pharmacies are looking at the cost of renovating or upgrading, and saying, ‘Instead of spending $300 a square foot to build a cleanroom, we’ll just spend $8,000 on an isolator.’ But the isolator still needs to be in an ISO 7 room that is buffered by an ISO 8 anteroom,” according to proposed revisions to the standard.

“We recommend isolators only where people are compounding very low amounts of chemo or other toxic drugs,” Jacobs continues. “If you’re compounding more than 15 drugs each day, the isolator can be cumbersome for the technicians. Compounding is a long, arduous process, and the operator doesn’t want to have his hands in an isolator all day long.”

Jacobs’ company takes an “open-architecture” approach to sterile compounding rooms that eliminates the need for LAFWs. Instead, a bay of HEPA filters is built into the ceiling grid above the compounding work table, with a suspended air return running behind the wall. The cleanroom walls are coated with a product called Bioguard, an 80-mil thick PVC laminate commonly found in pharmaceutical facilities.

“The approach eliminates the need for bulky hoods that can harbor microbial growth,” Jacobs says. “We have been able to achieve ISO 4 and 3 certification on the workbench, where only ISO 5 is required.” HWI has installed cleanrooms at several pharmacy facilities, including the Duke University Medical Center and the University of Pittsburgh Medical Center.

Figure 5. A compounded dose is drawn into a syringe in the RIVA system. The full syringe is weighed; the amount of drug is confirmed by comparing the weight of the full syringe with the empty syringe and confirming that the difference is accurate for that drug’s specific gravity at the appropriate volume and dilution. The full syringe is then removed for de-needling, capping, and labeling. Photo courtesy of RIVA Systems.Click here to enlarge image

Chemotherapy and other hazardous drugs obviously call for additional precautions. Jacobs’ experience has been that many of the hospitals that are compounding chemotherapy drugs have incurred considerable costs complying with USP <797> and NIOSH requirements. Per NIOSH, BSCs are to be vented (100% HEPA filtered) to the outside with no windows located above the exhaust, which usually means the vent is exhausted through the roof. “Often times the BSCs are located in the basement of the hospital, which can lead to a very cost-prohibitive exhaust system,” he says. An alternative according to Jacobs is an oxidizing (scrubbing) system that is in accordance with NIOSH requirements and thus complies with USP <797>. “This can save the hospital a lot of money by eliminating the exhaust system, and at the same time actually scrubs the toxic chemicals and better protects the public from the otherwise exhausted chemo,” Jacobs says.

The HVAC system is the cornerstone to any clean environment, Jacobs and others say. “We ideally want to see a dedicated HVAC system for the cleanroom, and while there may be an initial expenditure for the hospital to achieve this, there are savings in the long run,” he says. “A facility can save $10,000 to $12,000 a year with a well-engineered HVAC system.”

Advanced engineering

Power can attest to the importance of an optimally functioning HVAC system. “We’re set up to do batch chemo but have had continuing problems with our exhaust system that have delayed implementing this service,” Power says. “We added two floors to our three-floor building; our motor-blower, HEPA bank, and ductwork that support our negative-pressure HD compounding room are on the roof, so this has been problematic. The motor and ducts had to be upgraded and the system has not yet been re-balanced to operate.”

The UCSF PSS facility, which is USP <797> compliant, employs two pharmacists and three technicians, who compound total parenteral nutrition (TPN) solutions, continuous renal replacement therapy (CRRT) solution bases, batch intermittent IV antibiotics, batch electrolyte replacements, and other batch preparations. Output is an average of 40 TPNs per day and 50 CRRT bags, with other compounding amounting to roughly 2,200 units per month.

The negative-pressure (chemo or HD) room is designed as an ISO 8 room housing 2×6-foot exhausted CACIs. Elsewhere in PSS, the positive-pressure cleanroom is ISO 7 and contains a 2×8-foot and a 2×6-foot horizontal laminar airflow hood, and one 6-foot positive-pressure, recirculating isolator. The two cleanrooms share a HEPA-filtered anteroom. “All air technically goes into the HD room, but as it is filtered and controlled by sliding glass doors, the room stays at ISO 8,” Power says.

PSS is certified by an independent agency every six months, including all the equipment and the cleanrooms. Technicians are tested yearly for aseptic technique using a tryptic soy broth (TSB) test system of multiple manipulations. All compounding technicians perform a QC test bag daily with the automatic compounding device, and that test bag is filtered and inoculated with TSB as part of ongoing quality assurance.

Future plans for UCSF’s pharmacy system include the use of two automated, robotic compounding stations from RIVA Systems, in Winnipeg, Canada. The RIVA is an enclosed, ISO 5 robotic system for preparing IV admixtures. It fully automates the preparation of syringe and bag doses in multiple combinations and sizes, producing up to 800 labeled, patient-specific or batch doses per eight-hour shift. “The system requires that syringes have needles attached and placed into a carrier in an ISO 5 environment before being placed into the carousel,” Power says. “From there it draws the compound and completes all the remaining steps.”

Summary

Such equipment could well figure into the future of many pharmacies that compound sterile and high-risk drugs. But equipment and engineering are only one aspect of USP <797>’s current iteration that has generated comment and is being addressed. Other areas include beyond-use dating and appropriate storage parameters for compounded drugs, and standardized definitions and terminology. People involved in the revision process almost unanimously agree that definitive statements are needed most urgently on these topics.

As USP <797> is a work in progress, preparedness for and perception of it varies among compounding pharmacies throughout the country. Observers say it is a good sign that those adopting a “wait and see” posture are becoming the minority. They will likely be caught wanting-both technologically and economically-as the standard undergoes further refinement and becomes further ingrained in best pharmacy practice.

“Some hospitals tend to get out in front of the requirements, while others take a reactive approach, watching the revisions and waiting until something becomes concrete and enforceable,” Jacobs says. To this latter group he cautions, “Each revision to the standard is only going to get cleaner. It’s not going away, and the requirements aren’t going to get any dirtier.”

Resources and contacts

Haddad-Wylie Industries, LLC (HWI)
4143 Brownsville Rd.
Suite #6
Pittsburgh, PA 15227
(412) 884-3028
http://www.hwicleanrooms.com

Pharmacy Compounding Accreditation Board

1100 15th St. NW
Washington, DC 20005
(515) 341-1250
http://www.pcab.info

RIVA Systems

12-75 Scurfield Blvd.
Winnipeg, Manitoba R3Y 1G4, Canada
(204) 925-5349
http://www.rivasystem.com

The current version of USP <797> marked up with proposed revisions is available on the USP web site, at http://www.usp.org/pdf/EN/USPNF/PF797redline.pdf.

The NIOSH Safety Alert, “Preventing Occupational Exposure to Antineoplastic and Other Hazardous Drugs in Health Care Settings,” is available on the NIOSH web site, at http://www.cdc.gov/niosh/docs/2004-165/.

Three CETA standards for pharmaceutical compounding (CAG-001-2005 “Use Of Compounding Isolators in Compounding Sterile Preparations in Healthcare Facilities,” CAG-002-2006 “Compounding Isolator Testing Guide,” and CAG-003-2006 “Certification Guide for Sterile Compounding Facilities”) are available on the Controlled Environment Testing Association web site, at http://www.cetainternational.org.

This month’s issue of CleanRooms magazine will receive special bonus distribution at the American Society of Health-System Pharmacists (ASHP) Summer Meeting and Exhibition in San Francisco, June 24-27. And CleanRooms will be there as well to keep a close eye on this very important industry for contamination control professionals and companies. As described in this month’s special report, the creation and adoption of USP <797> standards and practices is already having a dramatic impact on improving the safety of sterile products produced in hospital pharmacies and other compounding facilities. And, with the release of the revisions, currently under active review by the USP <797> committee, there will also be substantial improvements to the safety levels of pharmacists performing the work, as well as anyone potentially coming into, or near, compounding spaces-particularly when hazardous compounds are being handled.

There are still questions that remain to be answered, however-one of which is the question of enforcement, which has been raised on this page before. The FDA has already cited USP <797> as its guidance document for compounding pharmacies, and a number of state boards of pharmacy have also either adopted or referenced the document. Still, much still needs to be done to establish a uniform national policy of inspection and enforcement. Some good news in the right direction is that the FDA is now considering the possibility of providing standardized training in USP <797> certification to state inspectors, in lieu of having FDA personnel actually perform the inspections themselves. While perhaps not the best solution, it may be the only realistic one given FDA’s manpower limitations. Another positive indication may be found in the Senate’s recent passage of the “FDA Revitalization Act,” which although it may not provide direct support for compounding concerns, does provide the FDA with some attention and relief in regard to its existing role in overseeing the overall approval, manufacture, and control of pharmaceuticals-a critical factor in protecting the public from potentially dangerous drugs but also in ensuring the rapid development and delivery of revolutionary new treatments into the arsenals of the medical community.

As evidenced by the increasing number of contamination control companies exhibiting at and attending ASHP events, there is also a clear recognition on the part of our industry that there are a great many opportunities in and existing technological benefits available to compounding pharmacies. While the USP <797> document gives guidance on what levels of protection must be achieved and maintained, it leaves plenty of options open as to how this is accomplished, and certainly the wide variety of facility constraints, locations, sizes, and applications means there are also a great many viable solutions possible for meeting them. I’ll be looking forward to seeing and hearing about many of them at the ASHP show and also in the pages of this magazine going forward.

John Haystead,
Editor-in-Chief

Guidelines to help maintain an area free of human-generated particle contamination

By Ron Perry, RPA

People play a major role in generating particles inside a cleanroom. It is important that each member of the cleanroom team understands how personal hygiene and habits affect the cleanroom’s cleanliness. Following are guidelines to help maintain an environment free of human-generated particle contamination.

Personal hygiene

Maintaining personal hygiene is extremely important for conditioning behavior and preventing undesirable contamination and the bad habits of everyday life from entering the cleanroom. When your job entails working in or even just entering a cleanroom environment, you should get into the practice of wearing non-linting street clothes made of cotton or polyester blend fabrics. Avoid nylon and other synthetic fabrics, which have a natural tendency to create static and attract particles. Fuzzy sweaters, scarves, or socks are never a good idea.

When it comes to cosmetics deodorant is encouraged. The dry, unscented, non-powder brands, such as roll-on, gel, or stick types, are preferred. Lip moisteners are good, but certain lipsticks that easily transfer color or other residue, rouge, powder, eye shadow, eyebrow pencil, mascara, hairspray, perfume, or cologne are not recommended because all of these products particulate or outgas.

Daily bathing and shampooing are encouraged; this helps control flaky skin and dandruff. Fingernails should be trimmed relatively short, and if fingernail polish must be used, use only non-flaking, non-metallic, and non-glitter types. Long nails are discouraged since they can puncture gloves or finger cots.

Wash your hands before entering the cleanroom with a specially formulated cleanroom cleaner and moisturizer to remove dead cells and prevent skin from flaking. Use only the hand soaps and moisturizers provided by your employer for this purpose. Certain over-the-counter, store-bought lotions contain sodium and oils that are not cleanroom compatible. It is not recommended that you scratch or rub your skin when inside the cleanroom as this can cause exfoliation and product contamination.

Hair should be combed frequently before entering a cleanroom because combing removes dandruff and loose hair. Wear a bouffant cap; bangs must be completely covered under the bouffant-no exceptions. Never remove your bouffant inside the cleanroom or gowning room and never comb or brush your hair when inside the gowning room or cleanroom.

Chewing gum and sucking mints should never be allowed. But do drink water before entering the cleanroom to help keep your body hydrated. A water fountain can be installed just outside the cleanroom. Never bring food or drinks inside the cleanroom. Smoking should be avoided up to 15 minutes before entering the cleanroom; this will give your lungs a chance to clear.

Garments and personal items

When it comes to jewelry, wedding and engagement rings are acceptable, though rings with prongs or sharp edges should be avoided since they can puncture gloves or garments. If they must be worn, then they can be tape wrapped before donning gloves and other garments. Dangling earrings, necklaces, brooches, and other protruding or hanging jewelry are not recommended, even if normally worn under street clothes. These items may interfere with cleanroom or laboratory activities.

Figure 1. Hygiene and gowning protocol must be outlined and followed to maintain the appropriate level of cleanliness for each critical environment. Photo © Christian Delbert.Click here to enlarge image

Keep personal items such as cigarettes, purses, tissues, and paper products inside your desk or locker, not in the cleanroom. Pockets in cleanroom garments should always be empty, unless authorized by your supervisor. Eyeglasses or goggles are strongly recommended because our eyes spew out mucus every time we blink. Wipe glasses and goggles clean of any visible particle contamination before entering cleanroom.

Figure 2. Examples of typical cleanroom garments. Photos courtesy of Cintas Corporation.Click here to enlarge image

Dry skin flakes, exhalant, and saliva can cause product contamination. Wearing a face mask varies with each individual company, but operators with sideburns, mustaches, or beards should wear beard covers. Disposable booties are recommended and should be changed once or twice daily. Most gowning rooms have a clean and a dirty side; protocols should always be followed. Never walk outside the gowning room with booties on and return wearing the same booties.

Bouffant caps are always recommended. As mentioned previously, hair, including bangs, must be covered completely without exception. Remove the bouffant cap once outside the cleanroom or gowning room, never within the cleanroom. The same bouffant cap should not be used if worn outside the cleanroom/gowning room.

If launderable frocks or coveralls (“bunny suits”) are utilized, then it’s recommended that they be changed once or twice a week or whenever the garment becomes soiled. This procedure varies with each company’s policies.

Always follow gowning procedures. Garments must not touch the floor. Touching the floor contaminates the garment. If the garment does touch the floor, get a clean, fresh garment.

If gloves are required, use cleanroom powder-free latex or vinyl gloves. Vinyl gloves should be worn if redness appears on hands after wearing latex gloves since some operators are allergic to the proteins in latex. Change gloves whenever they discolor, or when small holes appear-but not in the cleanroom. Gloves should always be changed in the gowning room. Never pull briskly and snap off the gloves; they should always be removed slowly.

Housekeeping

Tacky mats are recommended for cleaning the soles of shoes before entering a clean environment. The size of the mat varies with door entry openings. They are typically placed outside gowning room doors, inside the gowning room, and at main cleanroom entry doors. They are not required at exits. Step on the mat at least twice with each foot. Changing layers frequently captures loose dirt and keeps it out of the cleanroom. Change layers at least two or three times daily (traffic dependent).

Specialized HEPA-filtered vacuums are recommended and best suited for periodic cleaning. They are available in wet/dry or dry styles and are great for cleaning up spills. Hazardous spills must be properly attended to by trained safety personnel. Walls and ceilings can be dry vacuumed.

Cleanroom wipers, wet or dry, that are certified for your cleanroom classification are recommended and should be properly disposed of whenever soiled, torn, or abraded. Floors should be mopped or vacuumed once or twice a day. (This may vary from company to company.) Use only HEPA vacuum cleaners or low-particulating cleanroom mops.

Aqueous solutions, without sodium, potassium, ammonia, iron, copper, or nickel, are recommended for periodic wet cleanups. Detergents and disinfectants may require additional rinsing with cleanroom-compatible water, such as distilled or deionized water. If lubricating oils are to be used, consult your cleanroom manager for acceptable lubricants. Typically low-outgassing oils are recommended-wipe all residual oils from surfaces after lubrication to prevent particle accumulation.

Doors, frames, and thresholds should be cleaned on a regular basis. Wipe the top of the door first, then the sides and edges. A pre-saturated wiper is well suited for this. Tables, carts, and other furnishings should also be cleaned regularly. Wipe furniture slowly using long overlapping strokes. When wiping tables or work stations start at the back and move forward. Never wipe with fast or brisk strokes as this causes air turbulence within the cleanroom. And don’t forget to wipe underneath carts and tables.

Set up an in-house cleaning routine, or use trained outside professionals for periodic cleaning. Frequency may vary from once a day to once a week. Start at the dirty end of the cleanroom, wiping down the ceiling first, and work your way down the walls toward the floor. Work in small sections at a time and change solutions and water frequently. Additional rinsing may be required, particularly when using detergents. It is not recommended that you use brisk or side-to-side strokes. Try to use a slow and deliberate, vertical and overlapping method.

Flexible vinyl walls or curtains can be wiped down with pre-saturated wipes. Start at the top of the curtain and move toward the floor. Follow up with a dry wiper to remove any moisture remaining on the vinyl. Always use a cleanroom wiper with sealed edges. Outside walls of the cleanroom can be wiped with Simple Green and a non-abrasive, non-linting cloth.

Lights should also be cleaned. Make sure wipers and solutions will not scratch or etch the lens. Before cleaning, test the wiper on a small section of lens that is typically not visible. A pre-saturated cleanroom wiper may be best suited for the job. Clean the inside of the light starting at one end and move to the other side, using long, overlapping strokes. Then clean the outside in the same manner.

When cleaning glass, acrylic, or polycarbonate windows the selection of wiper and cleaning agent is vital. Plexiglas (polycarbonate or acrylic) windows can scratch or craze. Check with the window manufacturer for compatible chemicals. Squeegees make cleaning easy. Handles should be stainless steel or plastic coated. Use blades that are low in particulate shedding. Start at the top of the window and move toward the floor in slow, overlapping strokes. Check blades frequently since old blades may have exposed metal that can scratch the windows.

Ladders and step stools are often vital tools inside the cleanroom; cleanroom-compatible units are available in the market. Never bring a wooden or rusty ladder or stool into an active cleanroom. To maintain safe practices, never stand on a table, chair, or cart.

When it comes to cleaning buckets and wringers, units with casters of stainless steel or plastic construction are preferred. Keep buckets, mops, and other cleaning tools inside a designated area within the cleanroom or gowning room. It’s best to designate a specific cleaning cabinet within the area. It is not recommended that you remove cleaning tools from the cleanroom area after each cleaning. This may cause cross-contamination. Note that some utensils may contain galvanized parts that are subject to corrosion. Remove them from cleanroom use immediately if corrosion appears.

If hand tools or other materials are required, then keep a cleanroom-dedicated set of tools inside the area to perform routine maintenance. Wipe down all tools with a cleanroom-compatible pre-saturated wiper before entering the gowning room. Wipe again inside the gowning room, prior to entering the main cleanroom. All cleaning tools must be cleaned, rinsed, and dried before placing them into the storage cabinet to prevent mold and mildew.

Paper and containers

Use only cleanroom-compatible notebooks, paper, binders, and clipboards within the cleanroom. Consult the manufacturers for cleanroom ratings. Before putting cleanroom paper into a copy machine or printer, check with the manufacturer for office equipment and thermal compatibility. Some paper types may have a tendency to melt, leaving a residue on the rollers of the machines, creating contamination and possibly destroying your equipment.

One-piece ballpoint “stick” pens are best for cleanroom use. Click-type pens typically generate metal and plastic particles when they retract. Never use a graphite (lead) pencil in a clean environment.

Waste receptacles (trash cans) should be stainless steel or one-piece molded plastic, and flexible plastic liners should be utilized. Remove trash liners by folding all four corners into the center of the waste receptacle. Close the liner, taking care not to let air escape into the cleanroom. Take the receptacle into the gowning room to wipe down; wipe the receptacle inside and out daily.

Figure 3. Cleanroom-compatible notebook, clipboard, paper, and stick pen. Photo courtesy of RPA.Click here to enlarge image

Standard and ESD plastic totes, boxes, and containers are commercially available in all sizes. Never take cardboard or wooden containers into the gowning room or cleanroom. These fibrous containers are large particle generators. If adhesive tape is to be used, use only conductive or standard cleanroom-compatible tape.

Conclusion

Reviewing and following these guidelines will ensure that they become second nature. Although particle generation will still need to be monitored and analyzed, these management protocols will go a long way toward minimizing the human element in controlling the particulate levels in your critical environment.

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Ron Perry is president of RPA, a company that offers state-of-the-art cleanroom designs, construction, monitors, and furnishings. Perry has more than 25 years of experience selling products to the Southern California semiconductor, aerospace, microelectronics, biomedical, and pharmaceutical industries.

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Procedure for putting on coveralls (bunny suits)

1. Hold cuffs of sleeves in palms of hands.
2. Roll up coverall pant legs and put one leg inside coverall at a time.
3. Stand up straight and remain holding sleeves.
4. Let go of one sleeve and put one arm inside the sleeve, then let go of the other sleeve and put the second arm in the sleeve.
5. Zip up garment and you’re ready to go to work.

This procedure requires practice and balance. You may need to sit down to put on your garment.

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Procedure for removal of film layers

1. Look for color tab on end of mat.
2. Lift up tab and slowly peel layer away from mat.
3. Continue peeling film upward, separating it from the mat until all four corners are separated.
4. Bring all four corners together in the center of the mat, forming a tent- like appearance.
5. Slowly separate film from the center of the mat.
6. Fold film inward until it is small enough to discard. This procedure ensures that dust particles will be captured inside the film. Soiled sheets should be discarded outside the gowning room area.

It is not recommended that you pull the tab briskly and rip the film from the mat. This method allows particles to become airborne and enter the cleanroom. Go slowly and deliberately.