Project report on I.V.Fluid - Technology Book - Feasibility Report - Market Survey - Industrial Report

I.V. FLUID MANUFACTURING UNIT

EIRI Team — Thu, 26 Aug 2021 05:08:32 +0000

INTRODUCTION
STANDARD IV & ELECTROLITES
THE AIMS OF IV FLUID ADMINISTRATION SHOULD BE TO
BASIC IV SETUP
LET’S TAKE A LOOK AT THE MOST BASIC POSSIBLE SETUP FOR AN IV:
LOCATION- TENGNOUPAL DISTRICT
PLANT PROPOSED PLANT LOCATION:-
MAP
CLIMATE
TRANSPORTATION
BY AIR:
BY TRAIN:
BY ROAD:
DETAILS OF REGISTRATION
TYPES OF IV FLUIDS
IV SOLUTIONS CAN ALSO BE CLASSIFIED BASED ON THEIR PURPOSE:
CRYSTALLOIDS
GENERAL CHARACTERISTICS OF CRYSTALLOID
ISOTONIC IV FLUIDS
0.9% NACL (NORMAL SALINE SOLUTION, NSS)
DEXTROSE 5% IN WATER (D5W)
LACTATED RINGER’S 5% DEXTROSE IN WATER (D5LRS)
RINGER’S SOLUTION
HYPOTONIC IV FLUIDS
0.45% SODIUM CHLORIDE (0.45% NACL)
0.33% SODIUM CHLORIDE (0.33% NACL)
0.225% SODIUM CHLORIDE (0.225% NACL)
2.5% DEXTROSE IN WATER (D2.5W)
HYPERTONIC IV FLUIDS
HYPERTONIC DEXTROSE SOLUTIONS
DEXTROSE 10% IN WATER (D10W)
DEXTROSE 20% IN WATER (D20W)
DEXTROSE 50% IN WATER (D50W)
NURSING CONSIDERATIONS FOR HYPERTONIC SOLUTIONS
DARROW’S SOLUTION
COLLOIDS
HUMAN ALBUMIN
DEXTRANS
LOW-MOLECULAR-WEIGHT DEXTRANS (LMWD)
HIGH-MOLECULAR-WEIGHT DEXTRANS (HMWD)
IV FLUID/ELECTROLYTE THERAPY
NORMAL SALINE
VOLUME EFFECTS OF NS
RINGER’S FLUIDS
ADVANTAGE:
DEXTROSE SOLUTIONS
EFFECT OF DEXTROSE IN FLUID:
VOLUME EFFECTS
?5%D
? DNS
5% DEXTROSE COMPOSITION:
DEXTROSE SALINE (DNS)
PHARMACOLOGICAL BASIS
DEXTROSE WITH HALF STRENGTH SALINE
10% DEXTROSE & 25% DEXTROSE
ISOLYTE G,M,P,E
PARACETAMOL 10 MG/ML SOLUTION COMPOSITION
QUALITATIVE AND QUANTITATIVE COMPOSITION
METRONIDAZOLE IV SOLUTION
ECONOMIC PROFILE
MARKET POSITION
APPLICATION INSIGHTS
VOLUME INSIGHTS
INDIA LARGE VOLUME PARENTERAL (LVP) MARKET SHARE INSIGHTS
BUSINESS JUSTIFICATION
PRODUCTS
WHY IV FLUID?
GLOBAL INTRAVENOUS SOLUTION MARKET: KEY TRENDS
GLOBAL INTRAVENOUS SOLUTION MARKET: SEGMENTATION
GLOBAL INTRAVENOUS SOLUTION MARKET: REGIONAL ANALYSIS
GLOBAL INTRAVENOUS SOLUTION MARKET: COMPETITIVE LANDSCAPE
MAJOR FIVE IV FLUID MONITORING DEVICES COMPANIES:
B. BRAUN MELSUNGEN AG
BAXTER INTERNATIONAL INC.
BECTON, DICKINSON AND CO.
FORTIVE CORP
ICU MEDICAL INC.
SOURCE OF MACHINES TECHNOLOGY
USES AND APPLICATION
SOME GENERAL INTRAVENOUS FLUIDS
SPECIFICATION OF INDIAN PHARMACOPEIA ON I.V FLUIDS
DEXTRAN 40 INJECTIONS
DEXTROSE INJECTION WHEN DETERMINED BY THE FOLLOWING METHOD:-
DEXTRAN 110 INJECTIONS
SODIUM CHLORIDE AND DEXTROSE INJECTION
BASIC RAW MATERIALS
REQUIREMENTS OF RAW MATERIALS AND SPECIFICATIONS
WATER FOR INJECTION
HDPE PHARMA GRADE LAMINATE/ PLASTIC ROLL
LABELING
IDENTIFICATION
HEAVY METALS
COMPOSITION OF IV FLUID
COMPOSITION OF COMMON IV FLUID (MEQ/L)
COMPOSITION OF IV FLUIDS
COMPOSITION OF COMMERCIAL I.V. FLUID AVAILABLE
FORM FILL SEAL TECHNOLOGY
LIST OF MACHINERY IV BAG PRODUCTION FORM FILL AND SEAL MACHINE
THE PRODUCTION OF I.V. SOLUTION PRODUCTION LINE CONSISTS
OF 5 MAIN PHASES:
1. WATER PURIFYING
2. DISTILLATION
3. SOLUTION FILLING
4. STERILIZATION
5. PACKING
A TYPICAL FFS PROCESS WORKS AS FOLLOWS.
BASIC OF BFS TECHNOLOGY
BLOW FILL SEAL EQUIPMENT
BFS MOLDS AND TOOLING
BFS TRIALS
PROCESS
1. BLOW MOLDING
2. FILLING
3. SEALING
BLOW FILL SEAL MACHINES
BLOW FILL SEAL IS SUITABLE FOR YOUR APPLICATION:
ASEPTIC PACKAGING
BLOW FILL SEAL (BFS) AND FORM FILL SEAL (FFS) TECHNOLOGY
MANUFACTURING PROCESS OF I.V. FLUID
1. DISTILLED WATER PREPARATION:-
2. SOLUTION PREPARATION:-
3. INJECTION BLOW MOULDING
4. MOULDING PROCESS
5. FILLING PROCESS
6. SEALING PROCESS
7. MOULD OPENING PROCESS
FILTRATION AND FILLING:-
STERILIZATION:-
QUALITY CONTROL:-
THE WHOLE PROCESS CONSISTS OF THE FOLLOWING STEPS:-
PROCESS FLOW DIAGRAM
FLOW DIAGRAM OF MANUFACTURING OF I.V. FLUIDS
SUPPLIERS OF RAW MATERIALS
POTASSIUM PERMANGANATE
SODIUM CHLORIDE (I.P. GRADE)
DEXTROSE
SUPPLIERS OF PLANT AND MACHINERY
STERILIZING EQUIPMENTS
PM METER
LABELING MACHINES
TANKS
BOILER
FILTER PRESS
LABORATORY EQUIPMENTS
MIXER
PLANT LOCATION FACTORS
PRIMARY FACTORS
1. RAW-MATERIAL SUPPLY:
2. MARKETS:
3. POWER AND FUEL SUPPLY:
4. WATER SUPPLY:
5. CLIMATE:
6. TRANSPORTATION:
7. WASTE DISPOSAL:
8. LABOR:
9. REGULATORY LAWS:
10. TAXES:
11. SITE CHARACTERISTICS:
12. COMMUNITY FACTORS:
13. VULNERABILITY TO WARTIME ATTACK:
14. FLOOD AND FIRE CONTROL:
EXPLANATION OF TERMS USED IN THE PROJECT REPORT
1. DEPRECIATION:
2. FIXED ASSETS:
3. WORKING CAPITAL:
4. BREAK-EVEN POINT:
5. OTHER FIXED EXPENSES:
6. MARGIN MONEY:
7. TERM LOANS:
8. TOTAL LOAD:
9. LAND AREA/MAN POWER RATIO:
PROJECT IMPLEMENTATION SCHEDULES
INTRODUCTION
PROJECT HANDLING
PROJECT SCHEDULING
PROJECT CONSTRUCTION SCHEDULE
TIME SCHEDULE
MACHINERY PHOTOGRAPHS
MULTIPLE EFFECT WATER DISTILLATION PLANT
MIXER
STORAGE VESSEL
BLOW FILL SEAL MACHINE
AUTOMATIC BOTTLE LABELLING MACHINES
RAW MATERIAL SUPPLIER
SODIUM LACTATE
NACL
KCL CACL2
PRODUCT PHOTOGRAPHS

APPENDIX – A:

01. PLANT ECONOMICS
02. LAND & BUILDING
03. PLANT AND MACHINERY
04. OTHER FIXED ASSESTS
05. FIXED CAPITAL
06. RAW MATERIAL
07. SALARY AND WAGES
08. UTILITIES AND OVERHEADS
09. TOTAL WORKING CAPITAL
10. TOTAL CAPITAL INVESTMENT
11. COST OF PRODUCTION
12. TURN OVER/ANNUM
13. BREAK EVEN POINT
14. RESOURCES FOR FINANCE
15. INSTALMENT PAYABLE IN 5 YEARS
16. DEPRECIATION CHART FOR 5 YEARS
17. PROFIT ANALYSIS FOR 5 YEARS
18. PROJECTED BALANCE SHEET FOR (5 YEARS)

The post I.V. FLUID MANUFACTURING UNIT appeared first on EIRI - eBooks and Project Reports.

I.V. FLUID (BFS TECHNOLOGY)

EIRI Team — Sat, 21 Sep 2019 06:34:32 +0000

Intravenous fluids, in general are used as I.V drips for patients in nursing homes and hospitals suffering from acute dehydration or considerable debilitating conditions. These I.V fluids replanish the body fluids. Though a number of I.V fluids are there, generally three types of I.V fluids are used in hospitals as I.V drips. They are as follows:- 1. Dextrose injection fluid, 2. Dextrose and sodium chloride injection fluid, Types of IV Fluid:- Crystalloid: Balanced salt/electrolyte solution; for msa true solution and is capable of passing through semi permeable membranes. May be isotonic, hypertonic or hypotonic. Normal Saline (0.9% NaCl), Lactated Ringer’s, Hypertonic saline (3, 5, & 7.5%), Ringer’s solution. However, hypertonic solutions are considered plasma expanders as they act to increase the circulatory volume via movement of intracellular and interstitial water into the intravascular space. Colloid: High-molecular-weight solutions, draw fluid into intravascular compartment via on cotic pressure (pressure exerted by plasma proteins not capable of passing through membranes on capillary walls).Plasma expanders, as they are composed of macromolecules, and are retained in the intravascular space. Free H2O solutions: provide water that is not bound by macromolecules or organelles, free to passthrough.D5W (5% dextrose in water), D10W, D20W, D50W, and Dextrose/crystalloid mixes. Blood products: whole blood, packed RBCs, FFP, Cryoprecipitate, platelets, albumin. Essentially all colloids. IVF can supply 3 things: fluid, electrolytes, & calories. In the non stressed, fasting state, the 150g per day inD5W at 125ml/h can provide enough carbohydrate to limit proteolysis. The most common uses for IVF: Acutely expand intravascular volume in hypovolemic states correct electrolyte imbalances Maintain basal hydration. Normal Saline (0.9% NaCl): Isotonic salt water.154 mEq/L Na+; 154 mEq/L Cl-; 308mOsm/L.Cheapest and most commonly used resuscitative crystalloid. High [Cl-] above the normal serum 103mEq/L imposes on the kidneys an appreciable load of excess Cl- that cannot be rapidly excreted. When saline is injected intravenously, it compensate the deficiency of sodium ions when dextrose is injected it gives energy due to glucose content of it when dextro-saline is given in combination, it replanishes the dehydration as well as gives energy thereby recouping debility syndrome and also in general take care of malaise. Intravenous fluids are chemically prepared solutions that are administered to the patient. They are tailored to the body’s needs and used to replace lost fluid and/or aid in the delivery of IV medications. For patients that do not require immediate fluid or drug therapy, the continuous delivery of a small amount of IV fluid can be used to keep a vein patent (open) for future use. IV fluids come in different forms and have different impacts on the body. Therefore, it is important to have an understanding of the different types of IV fluids, along with their indications for use. There are several types of IV fluids that have different effects on the body. Some IV fluids are designed to stay in the intravascular space (intra, within; vascular, blood vessels) to increase the intravascular volume, or volume of circulating blood. Other IV fluids are specifically designed so the fluid leaves the intravascular space and enters the interstitial and intracellular spaces. Still others are created to distribute evenly between the intravascular, interstitial, and cellular spaces. The properties that an IV solution has within the body depends on how it is created and the specific materials it contains. It also determines the best type of IV solution to use in relation to the patient’s needs. The majority of an IV solution is sterile water. Chemically, water is referred to as a “solvent.” A solvent is a substance that dissolves other materials called “solutes.” Within IV solutions, the solutes can be molecules called electrolytes (charged particles such as sodium, potassium, and chloride) and/or other larger compounds such as proteins or molecules. Today, a growing number of pharmaceutical manufacturers are using advanced aseptic processing technologies to minimize operator intervention and contamination risk in the filling and packaging of liquid parenteral drugs. One of these technologies is form-fill-seal (FFS), in which a polymeric material is formed and sealed inline to a container of choice, while the container is being filled. FFS offers cost savings over conventional aseptic processing in glass. Traditional parenteral filling and packaging requires 23 steps and individual machines for filling, stoppering and capping. In contrast, FFS requires one piece of automated machinery, and takes place in six seconds or less. The entire FFS process is performed under a class-100 laminar flow, preventing external contamination. The fully automatic, computer-controlled technology allows for filling and packaging of up to 3,00,000 bottles of IV fluid per day. Nitrogen purging options are available for sensitive formulations such as amino acids.

The post I.V. FLUID (BFS TECHNOLOGY) appeared first on EIRI - eBooks and Project Reports.

I.V. FLUID (BFS TECHNOLOGY)

EIRI Team — Fri, 06 Sep 2019 06:40:36 +0000

An indication of average landed cost is provided to assist the local producer to gauge initial exporting costs to a particular country. These costs do not include any clearance charges, duties/taxes or local distributor mark-ups. It should also be noted here that many producers make a particular product in various quality grades and this is reflected in their final price for these products. While these producers may have a `base’, `medium’ and/or `high’ price and/or quality levels, these price ranges cannot be easily identified from the trade data as the `product mix’ varies from country to country and, therefore, all statistical costs are averaged out within the specific product HS Code. It should also be noted that the variations in costs are also affected by the cost of the raw materials used for producing the product. High quality and pure raw materials are obviously more costly than their cheaper lower quality or synthetic counterparts and, hence, this is also reflected in the final price of the goods. It must be stressed here that within the above product ranges there are considerable costs variations which can be exit due to the `quality grade level’ (high/medium/low) of the products, the raw materials used in the production, the type of packaging used, the transport, logistical, distribution costs, the `product mix’ being imported, and the market price acceptable in the target country ñ which would be based on GDP, available disposable income and demand. As an example, a third world country is unlikely to import large amounts of high quality products as the local GDP and income compels the local populace to purchase lower cost/quality products. The converse would be true in developed western countries. It is likely for these reasons that there could be considerable landed cost differential between the countries. This information should assist local KSA companies to ascertain, in a very general manner, whether their respective products are likely to be competitive in the above identified export markets or not. Landed costs, by sea shipments, are normally based on CIF value - purely as a general guide, it is estimated that the variation between FOB and CIF costs could be somewhere in the region of 10% to 15% of FOB. Although the U.S. market comprises almost 70% of the total world market for IV solutions, the market for third world and emerging nations is growing much faster and presents a tremendous opportunity for the IVPC Facility™. This growth is due to the building of better and higher quality health care institutions and other health care infrastructures in areas once deemed dormant. World market growth is driven by population increases and constant up-scaling and sophistication of health care delivery. As part of this up-scaling, IV infusion therapy is becoming increasingly important in overall health care treatment regimens as new developments in antibiotics and other medications used in areas such as chemotherapy, burn centers, and renal/peritoneal dialysis centers favor intravenous use and application. Many countries continue to rely on imported product, which is often too expensive for the general population to afford. Frequently, where product is made locally, the quality is poor and the costs are still high. In addition, the lack of inexpensive and readily available supplies of IV solutions in many developing nations has lead to a high incidence of death from non-mortal injuries and non-terminal diseases. The IVPC Facility™ provides an immediate and inexpensive remedy to this situation. The economic advantages of producing IV solutions locally in emerging and medically developing nations via EWMA IVPC Facility™ can result in an extremely short return on initial investment. Profitability can be established at only 50% production capacity. Direct production costs using U.S. cost figures are 45% to 65% lower than current market pricing for primary product lines. Under the U. S. calculation. direct and indirect labor costs comprise the largest single cost element. In emerging nations, where the cost of labor is much less and the cost of IV solutions often is much higher, the actual production cost figures can be 60% to 90% lower than market pricing. Secondary product lines with significantly higher profit margins can be introduced at any time to greatly enhance profitability. Long distance shipping costs are not incurred with the regional target market creating significant savings on distribution costs. Demand for IV solutions is so great that should production exceed local demand. opportunities for national and export sales are unlimited in the foreseeable future. Local labor is trained in the technology and employed by the facility. The efficiency of the technology allows for a small staff of personnel to maintain rated production capacity. Most raw materials are available locally.

The post I.V. FLUID (BFS TECHNOLOGY) appeared first on EIRI - eBooks and Project Reports.

I.V. FLUID (FFS TECHNOLOGY)

EIRI Team — Fri, 02 May 2014 13:17:42 +0000

Infusion therapy as a basic toll of modren medical care enables the physician to restore and stabilise hoeostasis states quickely and co,pletely.

In nursing homes and hospital were patients are suffering from a cute dehydration or considerable debilitating conditions, the intra venous fluids are used as IV drips. The basic fuction of IV fluids is to replenish the body fluids. Although there are a number of IV fluids are there but generally three types of IV fluidsd are used in hospitals as IV drips. They are as follows :

1. Dextrose injection fluid

2. Deretrose and sodium chloride injection fluid

3. Sodium chloride injection solution (Saline solution).

PROJECT REPORT COVERS:

Introduction
Uses and Applications
Properties
Market Survey with future aspects
Present Manufacturers
B.I.S. Specifications
Manufacturing Process with Formulae
Cost Economics with Profitability Analysis
Capacity
Land & Building Requirements with Rates
List & Details of Plant and Machinery with their Costs
Raw Materials
Details/List and Costs
Power & Water Requirements
Labour/Staff Requirements
Utilities and Overheads
Total Capital Investment
Turnover
Cost of Production
Break Even Point
Profitability
Land Man Ratio
Suppliers of Plant & Machineries and Raw Materials.

The post I.V. FLUID (FFS TECHNOLOGY) appeared first on EIRI - eBooks and Project Reports.

I.V. FLUID (FFS TECHNOLOGY)

EIRI Team — Tue, 08 Apr 2014 12:04:19 +0000

1. Dextrose injection fluid

2. Dextrose and sodium chloride injection fluid

Project Reports Cover:

Introduction
Uses and Applications
Properties
Market Survey with future aspects
Present Manufacturers
B.I.S. Specifications
Manufacturing Process with Formulae
Cost Economics with Profitability Analysis
Capacity
Land & Building Requirements with Rates
List & Details of Plant and Machinery with their Costs
Raw Materials
Details/List and Costs
Power & Water Requirements
Labour/Staff Requirements
Utilities and Overheads
Total Capital Investment
Turnover
Cost of Production
Break Even Point
Profitability
Land Man Ratio
Suppliers of Plant & Machineries and Raw Materials.

The post I.V. FLUID (FFS TECHNOLOGY) appeared first on EIRI - eBooks and Project Reports.

I.V. Fluid (FFS or BFS Technology)

EIRI Team — Mon, 30 Dec 2013 11:14:55 +0000

1. Dextrose injection fluid

2. Dextrose and sodium chloride injection fluid

Project Report Covers:

Introduction
Uses and Applications
Properties
Market Survey with future aspects
Present Manufacturers
B.I.S. Specifications
Manufacturing Process with Formulae
Cost Economics with Profitability Analysis
Capacity
Land & Building Requirements with Rates
List & Details of Plant and Machinery with their Costs
Raw Materials
Details/List and Costs
Power & Water Requirements
Labour/Staff Requirements
Utilities and Overheads
Total Capital Investment
Turnover
Cost of Production
Break Even Point
Profitability
Land Man Ratio
Suppliers of Plant & Machineries and Raw Materials.

The post I.V. Fluid (FFS or BFS Technology) appeared first on EIRI - eBooks and Project Reports.