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Feedstuff Evaluation Methodology

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Know the nutrient composition of your feed ingredients! ... Your region may differ in the nutrient density of the feedstuffs it produces ... – PowerPoint PPT presentation

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Title: Feedstuff Evaluation Methodology

1
Feedstuff Evaluation Methodology
2
The First Step

Know the nutrient composition of your feed
ingredients!
Discuss the way we determine nutrient
concentration in feedstuffs

3
Key to Nutrient Analysis

The analysis is only as good as the sample you
take !!!
1 quart sample has to represent several tons of
feed/feedstuff
representative sample

4
Sampling Feedstuffs

ID label containers with your name, address,
date, and feed type, etc.
Sampling
Grain or mixed feeds
Sacks 2 handfuls from 5-7 bags
Bulk 12-15 samples from different areas
Random samples placed in bucket mixed
Obtain uniform subsample

5
Sampling Feedstuffs

Hay
Use a hay probe take 12-15 samples from all
locations/depths
Cut samples into 1-2 lengths mix in clean
bucket
Haylage or Silage
Collect samples during the entire loading process
for new
For old, take series of samples (not spoiled)

6
Sampling Feedstuffs

Grain send in at least 1 pt
Hay send in at least ½ lb
Silage (Wet Feedstuffs) 2 qts in an airtight
container, preferably freeze or refrigerate, or
deliver immediately
Samples must arrive at lab in same condition they
left your farm!

7
Why analyze rations or feedstuffs??
8
Nutrient Analysis

Book values are averages over many locations
Your region may differ in the nutrient density of
the feedstuffs it produces
Example Book value for SBM 48 CP
Your SBM from SD 46.5 CP
Overfeeding/underfeeding nutrients
Contaminants in feedstuffs
Toxins, chemical residues, or other harmful
compounds

9
Nutrient Analysis

How often should you analyze your
feedstuffs/rations?
Every time you change batches/loads of feedstuffs
When you change feedstuffs in your rations
Every time you mix a new batch of feed
Monthly samples of forages/silages
In a perfect world
Generally, take sample after harvest

10
Analysis Systems
11
Analysis Methods

1. Chemical
e.g. titration, chromatography (chemistry)
No estimate of utilization, lab errors
2. Biological
Animals Expensive tedious
Difficult to obtain individual nutrient effects
3. Microbiological
Microorganisms estimations
Accurate quantification difficult

12
Proximate Analysis

Traditional standard of the industry
Developed in Germany more than a century ago
Most generally used chemical scheme for
describing feedstuffs
Limitations for todays diet formulation systems
Information is of uncertain nutritional
significance
May result in misleading results

13
Proximate Analysis
14
Dry Matter

Weigh a sample
Heat to 100 105 C
Re-weigh the sample
Difference in 2 weights is water loss
DM 100 - water loss

15
Ash

Weigh a sample
Burn for 2 hrs at 600 C (1112 F)
Weight remaining is ash
Individual minerals not determined
Use atomic absorption, spectrophotometry to get
individual minerals

16
Ashing Oven
17
Crude Protein

Kjehdahl Method
Digest a dry sample in concentrated sulfuric acid
Converts N to ammonium
During distillation ammonium is converted to
ammonia
mL of acid used to bring ammonia solution to
neutral pH amount of N in sample
Total N x 6.25 CP

18
Digestion Process
19
Distillation Process
20
Kjehdahl Method

Important Point
Analysis does not distinguish between N sources
Protein
Synthetic amino acids
Non-protein N (urea, NH4, biuret)

21
Crude Protein

Combustion Method (LECO)
N is released at high temperature in presence of
pure O2
N determined by thermal conductivity within the
instrument
EXPENSIVE equipment!

22
LECO analyzer
23
Ether Extract

Fat determination
Boil sample in ether alcohol to extract lipid
fraction of sample

24
Crude Fiber

Industry method for fiber determination
BUT--80 of hemicelluloses, 60 of lignin, and as
much as 50 of celluloses can be lost
CF value lower than actual amount of fiber in
feedstuff
Lignin can attach to N
Overestimated lignin

25
Van Soest Method of Forage Determination
Replaces CF Analysis
26
Van Soest Fiber Determination

Used to determine the insoluble cell wall matrix
the major subcomponents
1. Hemicellulose
2. Cellulose
3. Lignin
Able to determine heat-damaged protein
Maillard Products
N content of ADF fraction (ADINindigestible N)
Tells you the amount of N in a sample that is
actually AVAILABLE to the animal for use

27
Detergent System
Ground forage sample
Digest with neutral detergent (ND)
ND insoluble fiber (NDF) (cell wall components)
ND solubles (cell contents)
Digest in acid detergent (AD)
AD insoluble fiber (ADF) (cellulose, lignin)
AD solubles (hemicellulose, cell wall N)
Digest with 72 H2SO4
Acid insoluble lignin
Solubles (cellulose)
Lignin by loss of ignition
28
Detergent Digestion System
29
Summary

NDF hemicellulose cellulose lignin
ADF cellulose lignin
ADL lignin

30
Near Infrared Reflectance Spectroscopy (NIRS)

Based on Each major chemical component has a
near infrared absorption property that
distinguishes each component
Absorption is affected by Atom vibration
velocity
Works for most common feeds
Questionable
Feeds from abnormal conditions (drought)
Mixed feeds

31
Near Infrared Reflectance Spectroscopy (NIRS)

Advantages
1. Speed (lt 30 sec - 3 min)
2. Simplicity of sample preparation
3. Analyze multiple components in one
operation
4. Does not consume the sample
5. Cheap

32
Near Infrared Reflectance Spectroscopy (NIRS)

Disadvantages
1. Expensive, high-precision instrumentation
2. Dependence on calibration procedures
3. Inability to measure minor constituents
i.e. minerals
Still a developing technology
Gaining popularity

33
Others

Vitamins
Individual assays for each vitamin
Chemical/biological assays using chromatography
Minerals
Assays to obtain concentration of individual
minerals
Using Atomic Absorption Spectrophotometry

34
Energy Determination

Total digestible nutrients (TDN) vs. Bomb
Calorimetry
Explained in Energy Systems

35
Feedstuff Evaluation

RememberChemical analysis is the starting point
for determining the nutritive value of feeds
The actual value of ingested feedstuffs is
dependant upon the ability of the body to make
use of the nutrients in the feedstuff

36
Feedstuff Evaluation

Two general classifications of methods
In vitro methodology Simulate digestion in a
test tube to estimate nutrient digestibility
In vivo methodology Feed animal and measure
response criteria
Growth
Retention/Excretion
Digestibility

37
In vitro methodology

Method to estimate digestibility of feedstuffs
Uses enzymes and (or) microorganisms in a test
tube to simulate GIT environment
Method is cheap, with results in about 24 - 48
hours
Rough estimate of digestibility

38
In vitro methodology
39
In vitro methodology

Use enzymes to simulate digestion in upper GIT
Mouth
Stomach
Small Intestine
Use fecal inoculant to simulate fermentation in
lower GIT
Large Intestine

40
In vivo methodology

Feeding trials
Simply give an indication of
Palatability of feedstuff in a ration (will the
animals eat it?)
Growth response compared to another
feedstuff/ration
Tells NOTHING of why different results were
obtained

41
Feeding Trials
42
Feeding Trials
43
In vivo methodology

Metabolism Trial
Determines nutrient retention/excretion
Complete analysis on ration
Feed known amount to animals
Collect urine/feces
Compete analysis on urine/feces

44
Metabolism Trial
45
In vivo methodology

Metabolism Trial
Calculation (In Out)/In 100

Nutrient retention Nutrient intake Nutrient
excretion (Urine Feces) x 100 Nutrient
intake
46
In vivo methodology

Digestibility studies
Use of cannulated animals
Can determine small intestinal digestibility
(hydrolytic digestion) as well as total tract
digestibility (hydrolytic fermentative
digestion) of nutrients