I.V. FLUID MANUFACTURING UNIT

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Intravenous fluids, also known as intravenous solutions, are supplemental fluids used in intravenous therapy to restore or maintain normal fluid volume and electrolyte balance when the oral route is not possible.

IV fluids are also known as a saline solution. This sterile solution is made of sodium chloride and water. This liquid is the foundation of every IV solution, providing essential hydration, diluting medications, and facilitating the delivery of vitamins throughout the body.

IV fluids help maintain a patient’s hydration, electrolyte and blood sugar levels while undergoing surgical procedures. Clinicians are also able to administer warmed IV fluids directly into a patient’s bloodstream, as it is common for a patient’s body temperature to decrease slowly while he or she is sedated.

STANDARD IV & ELECTROLITES

– NaCl 0.18 – 2.7%

– Glucose 2.5 – 50%

– Sodium Lactate (Hartmanns’s) Solution

– Ringer Lactate

– Water For injection

– Sterile Water for Irrigation

– Sodium Chloride 0.9% for irrigation

– Sodium Chloride 0.18 – 0.45% and Glucose 4 – 10 %

– Potassium Chloride 0.15 – 0.3% in Sodium Chloride 0.9%

– Potassium Chloride 0.15 – 0.3% in Glucose 5%

The aims of IV fluid administration should be to

• Avoid dehydration

• Maintain an effective circulating volume

• Prevent inadequate tissue perfusion during a period when the patient is unable to achieve these goals through normal oral fluid intake

“Intravenous fluids have a range of physiologic effects and should be considered to be drugs with indications, dose ranges, cautions, and side effects.”

The intravenous route is the fastest way to deliver medications and fluid replacement throughout the body, because they are introduced directly into the circulation.

Intravenous therapy may be used for fluid volume replacement, to correct electrolyte imbalances, to deliver medications, and for blood transfusions.

Basic IV Setup

Let’s take a look at the most basic possible setup for an IV:

The drip chamber is located just below the IV bag; inside this chamber we can see the fluid drip down from the bag into the IV tubing. This is where we measure the speed of a manual IV setup; we look at this chamber and count the number of drops we see per minute. So, for example, if we count 25 drops over the period of 60 seconds, we would say that the IV is infusing at a rate of 25 drops per minute, or 25 gtt/min. (In reality, we may not count the number of drops in a full minute; we can, for example, count the number of drops we see over a period of 15 seconds, and then multiply that number by 4 to get the number of drops in a full minute.)

The drip chamber must always be half full. If the drip chamber is too full, we will not be able to see the drops to count them, and so we will be unable to determine the rate at which the IV is infusing. If the drip chamber is not full enough, then this will allow air to get into the IV tubing, which means that air would get into the patient’s circulatory system, which could be very dangerous, blocking a blood vessel or stopping the heart.

The roller clamp is what we use to control the rate at which the IV fluid infuses. If we roll it one way, it squeezes the IV tubing more tightly, making it narrower and therefore making the fluid flow through the tubing more slowly; if we roll it the other way, it loosens its pinching of the IV tubing, making the tubing less narrow, and allowing the IV fluid to flow through at a faster rate. So, if for example, we observe (by looking at the drip chamber and counting drops) that an IV is infusing at a rate of 50 gtt/min, but it was ordered to infuse at a rate of 30 gtt/min, we would tighten the roller clamp to slow the drip rate down until we could count only 30 drops going through the drip chamber each minute.

All roller clamps on a set of IV tubing should be closed before we attach a bag of IV fluid to the top of the tubing; this ensures that no air gets into the tubing.

Every IV medication will be ordered to infuse at a specific rate, and one of the major tasks of hosptial nurses is to set up the IV so that it infuses at this rate and to adjust the IV periodically if the rate has changed so that it remmains at the ordered rate. The rate at which an IV fluid infuses is referred to as the IV infusion rate or flow rate.

The slide clamp is used when we want to completely stop the IV from flowing, without having to adjust the roller clamp. This is handy if we want to stop the IV for a moment, but we don’t want to have to reset the flow rate by readjusting the roller clamp all over again once we start the IV up again. This works by pinching the tubing completely shut when we slide the tubing into the narrowest part of the clamp.

The injection port is a place where medicine or fluids other than those in the current IV bag can be injected so that they will infuse into the patient’s vein through the IV tubing. On the photo above we can see two ports: one on the IV bag itself and one below the drip chamber. There is also usually an injection port close to where the needle goes into the patient’s vein; we’ll see this below. The injection port on the actual IV bag is used if we want to mix some kind of medication with the fluid that is in the IV bag; if we inject the medication into this port and then roll the bag a little to mix the medication into the fluid in the bag, then the patient will recieve both the medication and the IV fluid at the same time. However, this can only be done when the IV fluid and the medication are allowed to be mixed. If we want to inject medication or a second kind of IV fluid directly so that it does not mix with the IV fluid that we’ve already attached, then we will use one of the ports that are located below the drip chamber.

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Description

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)

Additional information

Plant Capacity

40 MT/Day

Land & Building

(4000 sq.mt.)

Plant & Machinery

US$.955714

Rate of Return

37%

Break Even Point

52%