September 26, 2007 — SOUTHAMPTON, PA — The Hose Track(TM) Identification and Lifecycle Analysis System from AdvantaPure(R) offers several improvements over the conventional pen-and-paper log book method of recording usage data for process equipment. Hose Track’s updated brochure now includes an easy-to-read chart that contrasts the differences. A patented system, Hose Track offers an enhanced level of safety and security to processing functions performed in critical industries like pharmaceutical, biotech, food and beverage, medical device, chemical, and others involving high-purity applications.

The Hose Track system was developed for hose assemblies and is now used for other process components — bio-bags, pumps, filters, diaphragm valves, UV lamps, tanks, and vessels — as well. Using RFID technology and software, Hose Track identifies individual parts to monitor continual, wear-related events such as cleaning cycles and the number of batches processed. The system also tracks where a critical component has been throughout its useful life and provides a reliable, 21CFR Part 11 compliant, electronic pedigree for all tagged critical components.

Traditionally, log books are used to record information relating to individual pieces of process equipment. The books have a number of inherent problems including security, illegible handwriting, transposed numbers, and misfiled documents. Log books also present a challenge when FDA audits occur, as data must be manually gathered from various books, which may be stored in different locations, incurring time and labor expenses. Hose Track consolidates documentation and links to a database that contains the complete biographical history of process components. It allows information access from any networked computer running the Hose Track program.

These differences and others are featured in the updated literature available both in print and on the company’s web site at http://www.advantapure.com/hosetrack_01.htm. Included as part of the printed data sheet on Hose Track, the brochure also contains information on how the system reduces operating costs and minimizes risks, highlights its new gamma-radiation-resistant RFID tag option called GammaTag(TM), and shows a comparison of the Hose Track method to bar code usage.

For more information on the advantages of the Hose Track RFID system vs. a log book approach to record keeping, contact the team at AdvantaPure, 145 James Way, Southampton, PA 18966; phone (888) 755-4370 or (215) 526-2151; fax (888) 258-4293 or (215) 526-2167; e-mail: [email protected]; web page: www.advantapure.com.

About AdvantaPure and NewAge(R) Industries
AdvantaPure, a division of NewAge Industries, specializes in ultra-clean products for the pharmaceutical, biomedical, food, beverage, chemical, and cosmetic industries. All products are manufactured, stored, and shipped using the cleanest methods possible to ensure unsurpassed product purity.

In business since 1954, NewAge Industries manufactures and fabricates thermoplastic and thermoset tubing and hose. The company offers one of the broadest product lines of tubing, hose, and fittings in the U.S., and its custom extrusion and fabrication services are unrivaled. NewAge Industries maintains a large inventory and prides itself on same-day shipment of 98% of orders for its core product lines. In 2006, NewAge initiated an ESOP (Employee Stock Ownership Plan) for the benefit of both its employees and customers.

September 27, 2007 — /PRNewswire/ — MOORESVILLE, NC — Anpath Group Inc. reported today that its wholly owned subsidiary, EnviroSystems, Inc. (ESI), announced completion of the initial production run by its manufacturing partner, Minntech Corporation.

The company previously announced that ESI had entered into a manufacturing agreement whereby Minntech will be the exclusive manufacturer of ESI disinfectant products. To support the arrangement, Minntech expanded its manufacturing facility and established a dedicated production area for EnviroSystems products. The company stated that initial production quantities of its new disinfectants EnviroTru(TM) and EnviroTru(TM) 1453 would be shipped immediately to fill its order backlog for these two products.

“The ESI and Minntech team has worked hard to reach this milestone and it is a critical step in the continuing development of our company,” states J. Lloyd Breedlove, ESI president and CEO. Breedlove continues, “The transition of our manufacturing to Minntech insures our customers of the highest possible product quality, guarantees our distribution network that we have the capacity to meet future growth and expansion, and frees important and valuable company resources to focus on other aspects of our long-term strategic plan. However, when all the advantages are considered, the ongoing quality of our products is paramount. While our arrangement with Minntech provides EnviroSystems with a world-class partner and may offer other future synergistic business opportunities, the most appealing aspect of this relationship is Minntech’s unwavering commitment to quality.”

Minntech Corporation, a subsidiary of Cantel Medical Corp. located outside of Minneapolis, MN, is an EPA and FDA registered facility. Minntech produces and sells a wide range of infection prevention and control products in the healthcare market, including specialized medical device reprocessing systems for renal dialysis and endoscopy, as well as disinfectants and sterilants.

About Anpath Group, Inc.
Anpath Group, Inc., through its wholly owned subsidiary EnviroSystems, Inc., produces cleaning and disinfecting products that it believes will help prevent the spread of infectious microorganisms while minimizing the harmful effects to people, equipment or the environment.
www.anpathgroup.com

EnviroSystems, Inc. is focused on safe infection prevention technologies that the company believes will position the company in the forefront of the industry at a time when there is rapidly growing awareness of the critical need to prevent biological risks — both natural and man-made.

Source: Anpath Group, Inc.

September 27, 2007 — /PRNewswire/ — NEENAH, WI — Plexus Corp., a contract manufacturer of electronics products, today announced that one of its Penang, Malaysia facilities has received approval from the U.S. Food and Drug Administration (FDA), through its premarket approval (PMA) supplement evaluation process, to manufacture Class III finished devices on behalf of a large tier-one medical OEM. This approval comes following an extensive on-site audit in Penang by the FDA.

Dean Foate, CEO of Plexus, comments, “This approval is another significant milestone in our more than 20 year history of supporting the increasingly global outsourcing requirements of medical device OEMs. Plexus has three FDA registered manufacturing facilities in the US, Mexico and Malaysia, two of which are now approved to manufacture finished Class III medical devices. Additionally, four of our engineering facilities and six of our manufacturing facilities are also ISO 13485:2003 registered. With approximately a quarter of our annual revenues coming from product design, supply chain management and manufacturing services for medical device OEMs, Plexus is a leading contract manufacturer for the medical device industry.”

Andy Hyatt, vice president of Plexus’ medical sector, adds, “We believe Plexus is one of the first contract manufacturers to have an Asian facility with FDA approval to manufacture finished Class III medical devices. We understand how competitive the medical device market is, and are committed to developing scalable, global solutions that will create a competitive advantage for our customers in their end markets. We will continue to broaden our global service offering and expect to be registering additional facilities in Malaysia and the U.K. with the FDA over the coming year.”

About Plexus Corp. — The Product Realization Company
Plexus is an award-winning participant in the electronics manufacturing services (EMS) industry, providing product design, test, manufacturing, fulfillment, and aftermarket solutions to branded product companies in the wireline/networking, wireless infrastructure, medical, industrial/commercial, and defense/security/aerospace industries.

The company’s unique Focused Factory manufacturing model and global supply chain solutions are strategically enhanced by value-added product design and engineering services. Plexus specializes in customer programs that require flexibility, scalability, technology and quality. Plexus provides award-winning customer service to more than 100 branded product companies in North America, Europe, and Asia.
www.plexus.com

Source: Plexus Corp.

October 1, 2007 — /PRWEB/ — DETROIT, MI — Ash Stevens(TM) Incorporated (ASI) recently brought two new Rosenmund filter-dryers and a 100-liter pilot plant with cryogenic capabilities online in its Riverview, MI development and manufacturing site — a total investment of more than $2.5 million. The large filter-dryer, a 0.3 m² unit, is equipped with glove-box technology to facilitate handling of air-sensitive materials and to enable safe handling of Category 3 and 4 potent materials at plant scale. The smaller filter-dryer, a 0.03 m² unit, was designed to be used with the new cryogenic pilot plant system. That new pilot plant has the ability to maintain temperatures as low as -80 degrees Celsius and has the flexibility to operate seamlessly to +200 degrees Celsius.

The new systems are modeled in ASI’s process laboratories with pocket filters and vessels using the same geometries as those found in the plant. These new capabilities facilitate the rapid scale-up of processes to support product requirements throughout clinical development and post-launch.

“It’s our mission to translate client discoveries into new products to help seriously ill people,” says Stephen Munk, president and CEO, ASI. “By upgrading our facilities with scaleable systems and assuring rapid product supply, we are investing in our customers’ success in the form of faster drug approvals. I am grateful for the continued support of our board and am really proud of the dedication, competence, and hard work of my colleagues at ASI.”

The company was recently approved to manufacture the active ingredients in Velcade(R), Vidaza(R), and Clolar(R). With these recent approvals, ASI now has a total of 11 FDA approved drug substances in its portfolio. These recent FDA manufacturing approvals represent 3 of the last 85 manufacturing approvals for new chemical entities as drugs.

About Ash Stevens, Inc.
Headquartered in Detroit, ASI was founded in 1962 to service the chemical research needs of the Federal Government. The company has since become a full-service, contract cGMP manufacturer of low-volume, high potency active pharmaceutical ingredients for life science companies and has expertise in process development and navigating the regulatory affairs landscape. ASI has a total of 11 FDA approved drug substances in its portfolio. The company has more than 50 employees and holds patents in both medicinal and process chemistry. The company maintains a state-of-the art, cGMP-compliant manufacturing plant in Riverview, MI, including reaction vessels with capacities up to 500 gallons.
http://www.ashstevens.com

October 3, 2007 — ARLINGTON HEIGHTS, IL — The Institute of Environmental Sciences and Technology (IEST) Working Groups develop the standards and Recommended Practices that capture the best practices across industries and distill the experiences of leaders in these fields. Approximately 19 working group sessions will be held at the IEST Fall Conference, Nov. 11-14, 2007, at the Hilton Garden Inn in Hoffman Estates (Northwest Suburban Chicago), Illinois. All interested persons are invited and encouraged to attend these Working Group meetings, where the latest Recommended Practices will be discussed and developed.

The initial meeting of Working Group 205, Nanotechnology safety: Applying prevention through design principles to nanotechnology facilities, will highlight the IEST Fall Conference sessions.

Other IEST Working Group meeting topics include Testing cleanrooms; Garment system considerations; Nonvolatile residue in cleanrooms; Testing fan filter units; Liquid-borne particle counting; IEST-STD-CC1246D; Nanotechnologies overview: Planning, design, construction, and operational considerations for facilities engaged in research or production at the nanometer scale; and many more. A list of the working group meetings can be found here.

Learn about the latest research in the controlled environments and cleanroom industries from leading industry experts in your field. Registration is now open here.

More information about IEST and the Fall Conference educational opportunities can be found at www.iest.org, or by calling (847) 981-0100.

About IEST
Founded in 1953, IEST is an international not-for-profit technical society of engineers, scientists, and educators that serves its members and the industries they represent (simulating, testing, controlling, and teaching the environments of earth and space) through education and the development of recommended practices and standards. IEST is an ANSI-accredited standards-developing organization; secretariat of ISO/TC 209 Cleanrooms and associated controlled environments; administrator of the ANSI-accredited US TAG to ISO/TC 209; administrator of the ANSI-accredited US TAG to ISO/TC 142 Cleaning equipment for air and other gases; and a founding member of the ANSI-accredited US TAG to ISO/TC 229 Nanotechnologies.

Rationale for non-compliance with voluntary environmental control standards requires understanding ‘best practice’ recommendations by industry experts

By Gregg Mosley, Communications Vice President, IEST

In reviewing the current standards and recommended practices for cleanrooms and controlled environments it is difficult to imagine the simple beginnings for the concept. Although many professionals worked on test methods and controlling microbial bioburden and particulate contamination, the original idea of a modern cleanroom was quite different. In the late 1950s, engineer Willis Whitfield, on staff at Sandia National Laboratories in Livermore, CA, conceived a simple idea: “To keep a room very clean, let air be the janitor.” His first tested design-using cleansed, monotemperature, laminar airflow-produced room contamination levels 1,000 times cleaner that any previously obtained. Patents for the cleanroom idea were issued to Whitfield in 1962.

Timing for Whitfield’s concept appears perfect as immediate applications were made in three separate areas. Electronics manufacturers saw the application as a tremendous cost savings to reduce product failures. Health care facilities implemented the design to reduce infections in operating room theaters. And the U.S. government operations at NASA applied the cleanroom concept to control particulate and microbial bioburden contamination of extraterrestrial vehicles in the space program. The latter application was combined with sterilization of materials and components to minimize the prospect of accidental contamination of space and other extraterrestrial bodies in the solar system by projectiles from earth.

Manufacturing sterilized medical products

The combination of controlled environmental and sterilization practices developed at NASA has had a primary impact on manufacturing of sterile medical products. The outcome of the NASA projects demonstrated that sterilization was a function of the pre-existing product bioburden. Therefore, control of the environments for manufacturing and packaging of medical products has a direct impact on one’s ability to produce these sterile products. Many of the scientists involved in the NASA systems moved on to careers in government or industry directly related to production of sterile medical products. Recent ISO sterilization standards 17665-1 (2006) for moist heat; 11137-1, -2, and -3 (2006) for radiation; and 11135-1 for ethylene oxide (2007) identify the importance of quantifying and characterizing product bioburden as part of sterilization validation. For aseptically manufactured sterile products, components must be sterilized first, then the product should be final packaged in a controlled environment to ensure aseptic conditions are maintained for processing of the lot. These sterilization standards are not required by the U.S. Food and Drug Administration (FDA), though they are often considered best practice. However, for products marketed in the European Union (EU), the standards are required in the Medical Device Directives (MDD).

Current recommended practices and ISO standards for cleanrooms are developed under the leadership of the Institute for Environmental Science and Technology (IEST). Status of these standards and recommended practices was reviewed in the July issue of CleanRooms. IEST is the secretariat for ISO Technical Committee 209 (ISO/TC 209), Cleanrooms and associated controlled environments, and represents the United States as administrator of the U.S. Technical Advisory Group (TAG) to ISO/TC 209.

Industry perspectives on critical environments

A corporate determination of whether to comply with the ISO 14644 and 14698 series of standards for cleanrooms often appears to depend on whether the effects imparted by the critical environment are direct and immediate or not. For instance, manufacturers of electronic components verify the performance of components immediately and generally at a 100 percent inspection level. These quality control inspections may be repeated when multiples of components are assembled as subsystems. An increase in the number of rejects is detected immediately and correlates directly to the financial bottom line. Numerous quality inspections, set up early in the production sequence, minimize the potential loss of materials and employee time compared to inspections that are less frequent and further downstream.

In health care facilities, applying best practice for operating rooms and other potential sources of nosocomial infections minimizes both the probability of patient lawsuits and successful prosecution. In addition, best control practices as well as lawsuit history affect insurance premiums at health care locations.

Similarly, manufacturers of pharma-ceutical products that are aseptically filled see direct correlation. When such products fail required tests for sterility, the finished products lots may be rejected. In these situations, product cannot be reworked and the financial impact is immediate. Rework is not possible because tests are destructive; hence, statistically based sampling plans rather than 100 percent inspections are used. However, for these manufacturers, loss of the product is only the beginning of the financial loss. Medical product manufacturers operate as a regulated industry under the auspices of the FDA, similar national regulatory agencies, and/or the ISO notified bodies. Therefore, quality system problems often require internal investigations where effort is expended by staff at higher administrative levels to investigate and review all related data, training, and system controls. This is necessary to determine whether a general degradation of control can be identified somewhere in the quality system as the root cause. An identified root cause must be resolved, a corrective action implemented, and the effects monitored over time to determine whether the correction was successful. Requirements for these activities are covered in 21 CFR Part 820, Subpart J or ISO 13485: 2003, 8.5.2.

For products that are terminally sterilized, the effects of the critical environment used for manufacturing are not as clear as the examples given. Environmental particulates and microbes may have no impact on the ultimate quality of manufactured medical products. If products are cleaned, decontaminated, passivated, or rinsed prior to final packaging, most contaminating microbes may be removed or inactivated. For some products, the contribution of microbes by the manufacturing environment may be relatively insignificant compared to the levels on incoming components.

Sterilization validation

Terminally sterilized products may use an approach to sterilization based on bioburden, which is the microbial load naturally occurring on the product. Another approach referred to as “overkill” uses substitute microbes (biological indicators) with a known very high resistance to the sterilization method. Finally, a combination approach using information from both microbial groups is referred to as the “bioburden/BI approach.” Validation methods using radiation sterilization are bioburden based, so the impact of bioburden numbers and resistance is critical. Manufacturers using radiation take more notice of product bioburden changes and the manufacturing environment that may be a contributor. However, moist heat and ethylene oxide sterilization most often employ the overkill method. In this approach, bioburden has a lesser significance so long as the numbers remain below some maximum defined level and the types of microbes have a known low resistance to the sterilization method. Some manufacturers using these sterilization methods appear less concerned with the manufacturing environment and potential impact on the product. Often their rationale is that the overkill approach to sterilization will compensate for excursions in product bioburden, possibly imparted by the controlled manufacturing environment.

As it relates to reliance on an overkill sterilization method, bioburden must still be monitored and known so far as numbers and resistance to the process. Objective evidence must be available comparing bioburden levels for product and the manufacturing environment to show whether or not a correlation exists. Without historical data maintained in a baseline monitoring program, one cannot determine what levels of environmental contamination do or do not create a problem for the finished product. If the environment could have an impact on the product quality attributes, then a defensible monitoring program is a requirement. A scientifically based, pragmatic approach to controlled environmental monitoring should ensure consumer safety and reduce manufacturer cost and risk.

Regulatory perspectives

The regulatory requirements are not so forgiving, though. The same investigations and corrective actions apply for terminally sterilized products as for aseptic pharmaceuticals. In addition, FDA and ISO regulations cite the need for monitoring and control of the manufacturing environment. The FDA Quality System regulation addresses issues related to manufacturing environmental controls in sections 21 CFR §820.3, §820.70, and §820.75 discussing processes, process controls, and validations. Sections §820.181 and §820.184 cover documentation requirements for process and device records. ISO 13485: 2003 cites similar needs in clauses: 4.2.4 control of records, 6.3 infrastructure, 6.4 work environment, 7.5 production controls and validation, and 8.2.3 monitoring and measurement of processes.

In addition, changes in quality system regulations such as those specified in ISO 13485: 2003 require that risk assessment (including the impact of environmental controls) must be performed. The risk assessment task can be reduced by comparing devices typically manufactured in similarly controlled environments. When a company chooses not to follow voluntary ISO standards guidelines, the supporting rationale should be documented and re-evaluated when risk assessment changes.

The desire by manufacturers to comply with voluntary cleanroom standards often directly correlates to finances. However, it is important to understand how regulatory agencies perceive compliance to quality systems regulations and these voluntary cleanroom standards because they have been developed by a consensus of experts. Rationale for why they do not or need not comply is essential if they choose another testing series and compliance is often easier to accomplish.

Click here to enlarge image

Gregg A. Mosley is founder and president of Biotest Laboratories, Inc. (Minneapolis, MN). Mosley serves IEST as chair of the editorial board for the peer-reviewed Journal of the IEST and as the executive committee communications vice president. He has more than 30 years of experience as a microbiologist, chemist, and biochemist in various academic and industry positions. He is co-chair of both the AAMI Biological Indicators and the Industrial Moist Heat Sterilization Committees. Email: [email protected].

By Winn Hardin

Two recent announcements serve to illustrate the point that radio frequency identification (RFID) technology is beginning to prove a useful and valuable technology in cleanroom applications and sensor-embedded pharmaceutical manufacturing equipment.

One announcement by Billerica, MA-based Millipore Corporation describes that company’s plan to embed RFID tags in precision filters used to manufacture pharmaceuticals in controlled environments, while AdvantaPure (Southampton, PA) announces a new RFID patent on its “HoseTRACK” technology for monitoring tubing used in pharmaceutical cleanroom manufacturing.

“RFID’s strength is in what bar codes cannot do,” explains ABI Research’s (Oyster Bay, NY) research director, Michael Liard. “There’s no ability to attach sensors to bar codes for tracking environmental or performance changes. With RFID embedded sensors, you have the convenience of sending, receiving, and monitoring advanced features and functionality. If you look at the [return on investment] in RFID, it’s in high-value, high-risk items that help justify the additional cost.”

The RFID tags in Millipore’s filters store information about where the filter was manufactured, as well as providing real-time information about product performance, including what fluids are present during the manufacturing process. According to the company, this information will help customers to ensure regulatory compliance and make recording and conveying manufacturing data faster and more reliable.

Radio frequency identification (RFID) technology is making its way into clean processing equipment, such as Millipore’s Viresolve® filters (inset) and AdvantaPure’s HoseTRACK tubing monitoring system. Photos courtesy of Millipore Corporation and AdvantaPure.Click here to enlarge image

Similarly, AdvantaPure’s HoseTRACK hose identification and life-cycle analysis system also takes advantage of integrated sensors that add cleaning logs and operational histories to the memory block in the RFID tag fixed to the outside of the medical tubing. The company also embeds sensors and tags into other bio/pharmaceutical process equipment, including mixing vessels, plastic pouches, and filters. When paired with an RFID reader, the system can help generate the data needed to meet FDA’s 21CFR Part 11 reporting requirements; the company says that the data tracking system reduces time spent gathering information for audits, and helps maintain clear and secure documentation compared to conventional log books.

Ultraviolet-C (UVC) technology for air purification has recently been endorsed or specified by numerous federal, state, and local government agencies such as the Government Services Administration (GSA), CDC, EPA, and FEMA, as well as industry organizations including the American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) and the Illumination Engineering Society of North America.

Other endorsements and specifications of UVC as an acceptable means for air purification have been documented by agencies such as the New York State and New York City Departments of Health, the Kansas Department of Health and Environment, and the National Institute for Occupational Safety and Health (NIOSH).

ASHRAE also recently created a formal technical committee to promote and assist in the use of UVC in HVAC systems (TC 2.9 UV for Air & Surfaces). In addition, two Standards Projects Committees (SPC 185.1 and SPC 185.2) have been formed and are in the process of establishing standards for the application of UV in HVAC systems.

Driving these trends is an increased level of attention from end users regarding indoor air quality (IAQ) and its impacts on home and building occupants. There is also an increasing recognition of UVC as viable technology for energy savings, cost avoidance, and improving IAQ. Based on energy efficiency and maintenance savings alone, many UVC installations have return on investment of less than 1 year, according to Ultra Violet Devices, Inc., a manufacturer of UV and molecular filtration products.

The Institute of Environmental Science and Technology (IEST) has begun assessing the need for a Recommended Practice (RP) on liquid particle counting (LPC). Working Group CC042, formed last November, has been assigned to work on RP-CC042.1, “Sizing and counting of submicrometer liquid-borne particles using optical discrete-particle counters,” with a focus on applications in the semiconductor, flat-panel display, and data storage industries. The Working Group intends to complete a votable version of the RP by the end of next year.

The RP will cover the following topics:

• An overview of light scattering technology
• Applications of LPC instruments-batch and inline types
• Cumulative vs. differential counts
• Coincidence level
• Lower particle size detection limit
• Bubble issues
• Refractive index effects
• Calibration verification
• Particle extraction methods
• Statistics
• Instrument noise
• Flow rate
• Sensor preventive maintenance
• Counter correlation

The Working Group has broad participation from LPC manufacturers, end users, and consultants in the microelectronics industry. The members would like to gather more feedback from end users to make the document as effective as possible. If you are interested in contributing to this RP, please contact Huaping Wang, chair of WG CC042, at [email protected], or (952) 556-4532.

The Working Group’s next meeting will take place at IEST’s Fall Meeting on November 14 in Chicago.

Silecs recently unveiled its new world-class materials manufacturing and R&D facility in Espoo, Finland. Designed from the ground up, the new ISO 9001-compliant facility comprises a total of 27,000 square feet and uses the most sophisticated and environmentally responsible production and quality control techniques available, according to the company. Within the facility the company’s polymer materials are manufactured in a Class 1000 (ISO 6) cleanroom that mirrors the advanced production techniques of microelectronics manufacturers. Polymer filtration is conducted in pristine Class 100 (ISO 5) cleanroom conditions. Even the packaging activities are conducted in an 11,000-square foot Class 10000 (ISO 7) environment. This “copy exact” manufacturing strategy-from R&D to pilot lines to volume production-is at the heart of Silecs’ “risk mitigation” commitment to its customers.

According to CEO Jack Kokko, the same copy exact philosophy extends beyond Silecs’ manufacturing activities and into the company’s world-class process applications lab. “Here, Silecs’ materials are put to the test on a pilot semiconductor production line, going through the same process steps that our customers use in their facilities. This makes it possible for us to take our newest materials from concept to application testing, and ultimately to manufacturing, rapidly and with a nearly seamless transition.”

Kokko continues, “In the applications lab, we can quickly process customer wafers or develop new processes for their materials on site, ensuring that our customers can easily-and confidently-integrate Silecs’ products on their high-volume production lines.”

Silecs’ new material manufacturing and R&D facility follows a ”copy exact” strategy that mirrors the advanced production techniques of its microelectronics manufacturer customers in cleanroom conditions. Photo courtesy of Silecs.Click here to enlarge image

The facility is equipped with state-of-the-art customized equipment and software. Full traceability is maintained on incoming raw materials and the use of statistical process control (SPC) monitors the lot-to-lot consistency. Once quality assurance personnel have approved those materials, they are loaded into processing reactors, which are computer-controlled for precise, repeatable control of heating and other critical parameters. Again, SPC is used to monitor the outgoing quality and consistency of every lot of material the company processes, ensuring consistently pure, highly uniform product, ready for production of the most advanced device designs.